This case study showcases the use of green roofs in Kansas City to manage stormwater, reduce the urban heat island effect, and improve energy efficiency. By documenting the city’s efforts, including partnerships, costs, and measurable benefits, the report highlights how green infrastructure can serve as a sustainable urban planning tool. The study demonstrates reductions in rooftop temperatures, improved air quality, and long-term cost savings for buildings equipped with vegetated roofs. It serves as a practical resource for cities looking to invest in nature-based solutions for climate resilience and public health.

The ClimateVerse initiative by the Lakshmi Mittal and Family South Asia Institute at Harvard University is a cross-disciplinary platform addressing the intersection of climate change, health, and policy across South Asia. By fostering collaboration among researchers, policymakers, and local communities, ClimateVerse aims to build actionable solutions for climate resilience. The platform supports data-driven research, climate education, and policy engagement to address urgent climate-health challenges in the region. It highlights innovative regional responses, strengthens capacity building, and facilitates South-South knowledge exchange to inform sustainable development and equitable adaptation strategies across South Asian nations.

Rahat aims to provide solace (in Hindi: राहत (Rahat)) from extreme heat in the slums of Jodhpur in western India by implementing women-led housing design strategies like reflective roofs through community engagement. Through a randomised control trial experiment, this intervention seeks to relieve economically disadvantaged communities by assessing the solution’s effectiveness, community acceptance, and livelihood generation potential. The goal is to make extreme heat stress visible to the women in low-income communities, who often maladapt to heat and suffer from heat-health inequalities. 

ARTPARK’s Climate and Health initiative focuses on developing innovative, AI-powered technology solutions to address the growing health risks caused by climate change in India. The program aims to use predictive models, data integration, and real-time monitoring to support public health systems in managing climate-sensitive diseases, extreme heat exposure, and environmental stressors. With a mission to build scalable, inclusive technologies, ARTPARK bridges scientific research and digital innovation, empowering healthcare providers and communities to adapt to climate change. This initiative is part of a broader effort to create a resilient and equitable health ecosystem that can withstand future climate challenges.

The COPE (Cascading Climate Risks: Towards Adaptive and Resilient European Societies) project explores how climate risks interact across sectors and borders, aiming to improve adaptation strategies. By assessing cascading climate impacts, COPE provides insights for policymakers, businesses, and communities to enhance resilience and mitigate vulnerabilities in a changing climate.

The Heat Smart City Plan for Greater Sydney, developed collaboratively across multiple sectors, addresses heat risks, highlights the need for coordinated management, and outlines actions for change by 2030. It sets key directions agreed upon with stakeholders, with the next step being the creation of an Implementation Plan to specify funding, timelines, and reporting.

The technical report is intended to support efforts by the prefectural government of Hyogo (Japan) towards a comprehensive system for public health prevention of heat disorders. It is the result of an evidence-building process involving relevant stakeholders at the local and national level in Japan. The state of the science regarding public health action on heat waves is reflected only as required by practical purposes, and is based on published scientific literature, as well as the gathering of critical inputs from experts within and outside the World Health Organization (WHO).

The purpose of this industry guidance note (IGN) serves as a guidance and reference on matters pertaining to the management of heat stress in a workplace. Brunei’s climate is becoming warmer with a mean temperature increase of 0.25⁰C per decade (Brunei Darussalam National Council on Climate Change) and working in Brunei’s hot and humid weather can put employees at an increased risk of heat stress especially for outdoor workers.

The State Hazard Plan – Heatwave outlines Western Australia’s comprehensive approach to managing heatwave emergencies. It details strategies for prevention, preparedness, response, and initial recovery, emphasizing coordination among government agencies, communities, and stakeholders to mitigate health risks and infrastructure impacts during extreme heat events. The plan assigns the Department of Health as the Hazard Management Agency, responsible for overseeing emergency management related to heatwaves, while individual agencies handle prevention, preparedness, and recovery efforts.

The Heatwave Ready Tasmania guide by the Tasmanian Department of Health offers comprehensive strategies to mitigate heat-related illnesses during extreme temperatures. It emphasizes the importance of staying hydrated, wearing appropriate clothing, and recognizing symptoms of heat stress. The guide also highlights the increased vulnerability of certain groups, such as the elderly, young children, and individuals with chronic illnesses, providing tailored advice to ensure their safety during heatwaves. By following these guidelines, Tasmanians can effectively prepare for and respond to hot weather conditions, safeguarding their health and well-being.

The objective of this research is to highlight the climate-related hazards and their impacts on different sectors such as water, agriculture, coastal areas, livelihoods, and food security, and their impacts on vulnerable groups such as women, girls, children, people with disabilities, and elder people. It also sheds light on the climate-related conflicts, and mitigation and adaptation solutions that can be implemented to alleviate the impacts of climate change on the country. The methodology utilized in this research involved a combination of primary and secondary data sources. To ensure accuracy and reliability, the research team met with specialized experts and referred to authentic sources throughout the data collection process.

The Technical Guidelines for Management of Heat Stress at Work, issued by Dubai Municipality’s Health and Safety Department, provide comprehensive measures to protect workers from heat-related illnesses. The guidelines emphasize the importance of acclimatization, proper hydration, and regular rest breaks. They also outline employer responsibilities, including implementing engineering controls like ventilation and providing personal protective equipment to mitigate heat exposure. By adhering to these guidelines, workplaces can enhance safety and productivity during high-temperature conditions.

This Heatwave Emergency Preparedness & Response Plan aims to establish an effective, efficient, coordinated public health preparedness and response plan to prevent mortality, morbidity & disability because of heat. It relates to the preparation, readiness and responsiveness of the health care system in Northwest Syria, specifically of emergency departments and emergency medicine systems, to environmental heatwaves and extreme heat events.

The most important actions to take during a heat-wave are: to avoid or reduce exposure, to communicate risks effectively, to take particular care of vulnerable population groups and to manage mild and severe heat illness.

The National Adaptation Plan (NAP) of Kuwait (2019–2030) outlines the country’s strategic approach to addressing climate change impacts. It identifies key vulnerabilities in sectors such as water resources, agriculture, and public health, and proposes targeted adaptation measures to enhance resilience. The plan emphasizes integrating climate considerations into national development policies and promotes stakeholder engagement to ensure effective implementation.

The Action Plan elaborated by the Community of Madrid focuses on safeguarding residents in social and healthcare centers during extreme heat events. It emphasizes the importance of proper building ventilation, staff training, and the implementation of preventive measures to protect vulnerable groups, such as the elderly and individuals with chronic illnesses. The plan also highlights the necessity of interdepartmental coordination to ensure effective responses to high-temperature episodes.

The Action Plan for the Climate Emergency 2030 is an updated strategy by the Barcelona City Council, building upon the previous Climate Plan in response to the declared climate emergency. This plan adopts an eco-social approach, integrating environmental sustainability with social equity to address the multifaceted challenges posed by climate change.

The Action Plan to Prevent the Effects of Heatwaves on Health (POCS) is a comprehensive strategy developed by the Public Health Agency of Catalonia. It aims to mitigate health risks associated with heatwaves by implementing early warning systems, public education campaigns, and coordinated responses among healthcare providers. The plan focuses on protecting vulnerable populations, including the elderly, children, and individuals with chronic illnesses, by promoting preventive measures and ensuring timely medical assistance during extreme heat events.

Rising temperatures and weather extremes like floods and storms could be detrimental to the quality of life in Serbian towns – these are all challenges we have to face. Our towns must be prepared to cope with the effects of climate change as structures and the urban living environment are especially vulnerable.

At the same time well-functioning towns and cities are among the most important prerequisites for sustainable economic development. Lack of systematic planning in response to climate change impact will lead to increased costs for adaptation measures. Anticipatory strategies and plans including climate change projections must be continuously developed to ensure the adaptation of urban structures to mitigate the impact of a changing climate on the urban living environment.

In full awareness of these facts, the City of Belgrade developed this Climate Change Adaptation Action Plan and Vulnerability Assessment within the regional project “Climate Change Adaptation in the Western Balkans” implemented by the German International Cooperation Agency (Deutsche Gesellschaft für Internationale Zusammenarbeit – GIZ).

he Heat Wave Action Plan of Gorakhpur focuses on creating a dynamic early warning dissemination network to alert communities based on forecasts from the India Meteorological Department (IMD). It assigns clear responsibilities to stakeholders, such as establishing heatwave relief shelters, providing drinking water, and ensuring health facilities are operational. The plan emphasizes preparedness by training school and community responders like Aapda Mitra to assist vulnerable populations, including children, pregnant women, the elderly, and differently-abled individuals. It promotes cost-effective climate adaptation measures and strengthens public outreach through media channels, messaging platforms, and coordinated communication by the DDMA and Municipal Corporation.

The Heat Mitigation Plan for Ferozepur (2024), prepared by the District Disaster Management Authority (DDMA) outlines strategies to combat the adverse effects of extreme heat. The plan includes early warning systems, public awareness campaigns, and roles for government and community stakeholders. It emphasizes preparedness in health systems, urban planning, and infrastructure to mitigate the impacts of heatwaves on vulnerable populations, including children, the elderly, and outdoor workers. Long-term goals include sustainable urban design and enhanced public health responses.

This Heat Action Plan aims to provide a framework for the implementation, coordination, and evaluation of extreme heat response activities in Patiala that reduce the negative health impacts of extreme heat. The Plan’s primary objective is to alert those populations most at risk of heatrelated illness that extreme heat conditions either exist or are imminent, and to take appropriate precautions.

The Bhubaneswar Heat Action Plan is a strategic framework designed to address extreme heat impacts in Bhubaneswar, Odisha. It includes measures like early warning systems, public awareness campaigns, and inter-agency coordination to mitigate heat-related illnesses and fatalities. The plan emphasizes community preparedness and offers guidelines for various stakeholders to enhance resilience and protect public health during heat events.

The Heat Wave Action Plan has been prepared as there is continuous increase of heat in the month of March to June over the past several years. The District Heat Wave Action Plan, which shall consist of mapping of Heat Wave Preparedness in the district, measures to mitigate it and define the administrative framework for coordination and dissemination of such information to the general public. Kathua district has embarked on the path of preparing and publishing a comprehensive Heat Wave Action Plan that shall address all the concerns of Heat Wave. In this context, a dedicated effort has been made by the DDMA, Kathua district to prepare a comprehensive Heat Wave Action Plan for the year 2024-2025 under the stewardship of District Administration & UTDMA (Jammu and Kashmir Union Territory Disaster Management Authority).

The West Bengal Heat Action Plan is a comprehensive strategy developed by the West Bengal Disaster Management & Civil Defence Department to mitigate the adverse effects of extreme heat events in the state. This plan outlines measures such as early warning systems, public awareness campaigns, and inter-agency coordination to reduce heat-related illnesses and fatalities. It emphasizes the importance of community preparedness and provides guidelines for various stakeholders to effectively respond to extreme heat conditions.

The Kerala Heat Action Plan is a comprehensive strategy developed by the Kerala State Disaster Management Authority (KSDMA) to mitigate the adverse effects of extreme heat events in the state. This plan outlines measures such as early warning systems, public awareness campaigns, and inter-agency coordination to reduce heat-related illnesses and fatalities. It emphasizes the importance of community preparedness and provides guidelines for various stakeholders to effectively respond to extreme heat conditions.

This heat action plan is a comprehensive strategy designed to mitigate the adverse effects of extreme heat events. It outlines measures such as early warning systems, public awareness campaigns, and inter-agency coordination to reduce heat-related illnesses and fatalities. The plan emphasizes the importance of community preparedness and provides guidelines for various stakeholders to effectively respond to extreme heat conditions.

The Andhra Pradesh Heat Action Plan is a comprehensive strategy developed by the state’s Revenue (Disaster Management) Department to mitigate the adverse effects of heat waves. This plan outlines measures such as early warning systems, public awareness campaigns, and inter-agency coordination to reduce heat-related illnesses and fatalities. It emphasizes the importance of community preparedness and provides guidelines for various stakeholders to effectively respond to extreme heat events.

The Chatham County Heat Action Plan is a comprehensive strategy designed to protect residents from extreme heat events. Developed collaboratively by local agencies and community partners, the plan focuses on public education, preparedness, and response measures to mitigate heat-related health risks. Key components include establishing cooling centers, issuing heat health alerts, and providing resources for vulnerable populations. This proactive approach underscores Chatham County’s commitment to safeguarding public health amid rising temperatures.

The Heat Action Plan Toolkit offers comprehensive guidance for North Carolina communities to prepare for and mitigate the health impacts of extreme heat. This resource includes a customizable heat action plan template, strategies to identify vulnerable populations, activation recommendations, and communication materials. Developed in collaboration with the State Climate Office of North Carolina and other partners, the toolkit aims to enhance community resilience against rising temperatures.

The Extreme Heat Action Plan for New York State provides a comprehensive roadmap for 2024–2030 to address the increasing impacts of extreme heat. The plan focuses on building community resilience, protecting vulnerable populations, enhancing infrastructure, and promoting nature-based solutions. It emphasizes equity and includes actions like improving cooling access, supporting workers’ safety, advancing ecosystem-based adaptation, and strengthening local planning and emergency response capabilities. The plan aligns with the State’s broader climate adaptation and resilience goals.

The “National Adaptation Plan for the Republic of Trinidad and Tobago” outlines the nation’s strategic approach to addressing climate change impacts. Recognizing its vulnerability as a Small Island Developing State, the plan emphasizes adaptation in key sectors: coastal resources, agriculture, water, health, biodiversity, infrastructure, financial services, and Tobago-specific concerns. It integrates with existing policies, including the National Climate Change Policy and Vision 2030, aiming to build long-term resilience through a comprehensive, multi-year program developed with diverse stakeholder input. The plan also serves as Trinidad and Tobago’s first Adaptation Communication to the UNFCCC, reaffirming its commitment to global climate action.

This Response Plan outlines strategies to mitigate the health and environmental impacts of heatwaves. It emphasizes public education, early warning systems, and coordinated responses among government agencies and communities. The plan also identifies vulnerable populations and provides guidelines for healthcare facilities to manage heat-related illnesses effectively.

The “Community Climate Adaptation Plan” for Waterloo Region outlines strategies to enhance resilience against climate change impacts like extreme weather, flooding, and rising temperatures. Developed collaboratively with community stakeholders, the plan focuses on four key areas: health and community, built environment, natural environment and water, and energy and economy. It includes 15 objectives and 36 actions addressing climate adaptation needs through local solutions, emphasizing equity, sustainability, and collaboration. The plan adopts ICLEI’s BARC framework, which guides climate adaptation through assessment, planning, implementation, and monitoring.

This 2024-25 Strategy update is structured around the five main climate-related hazards facing Vancouver (extreme heat, poor air quality, drought, extreme rainfall, and sea level rise) and takes a risk-based approach to adaptation planning. The Strategy introduces updated climate projections, new objectives, and an action plan structured around the hazards plus enabling actions to support mainstreaming of climate adaptation across the City. It also has an increased focus on equity, prioritizing adaptation measures that support populations disproportionately impacted by climate change. An indicator and financial framework are included to support implementation. It is important to note that the funding needed to advance climate adaptation at the pace and scale required is beyond the City’s capacity and will require long term, sustainable funding from senior levels of government. This is particularly the case for coastal adaptation, for which we know the infrastructure costs will be high and there is a history of senior funding to support.

Zambia’s National Adaptation Plan (NAP) 2023 outlines medium- to long-term strategies to enhance resilience against climate change impacts across sectors like agriculture, health, water, and infrastructure. It identifies key vulnerabilities such as droughts, floods, and extreme temperatures, while proposing targeted adaptation actions, resource mobilization, and institutional coordination. The NAP integrates gender-sensitive approaches and aligns with global frameworks like the Paris Agreement, aiming for sustainable development and resilience by 2030.

The Ministry of Health (MoH) has collaboratively developed the Health-National Adaptation Plan (H-NAP) based on the findings of the Vulnerability and Adaption Assessment (VAA) to guide climate change adaption by the health sector. This H-NAP should be used to mobilize the required technical and financial resources. This effort should be replicated at the sub-national level to ensure we build a climate-resilient health system.

As centers of commerce, communication, culture and innovation, cities are the biggest contributors to climate change and consequently, must play a leading role in climate change mitigation and adaptation. Addis Ababa, the capital city of Ethiopia, is taking bold actions in meeting the objectives of the Paris Agreement and the country’s climate change objectives. Addis Ababa has developed its first Paris Agreement Compatible Climate Action Plan(CAP) that depicts the city’s commitment to tackle climate change and build resilience to its now-inevitable impacts. The CAP identifies key emission sources by sector within the city under the BASIC level of reporting of the Global Protocol for Community-scale Greenhouse Gas Emission Inventories Standard, in order to a set of recommendations and pathways towards an equitable, inclusive, climate resilient and carbon neutral Addis by 2050.

Garoua’s Sustainable Energy Access and Climate Action Plan (SEACAP) is the culmination of a two-years process led by the City Council and the three subdivisional councils (Garoua I, II and III) with the support of GIZ, ICLEI Africa and Help Community. The document highlights the key results, targets and actions for decision makers, citizens and those interested in partnering with the city and benefiting from its climate commitment.

Le Plan National d’Adaptation (PNA) vise à renforcer la résilience du Bénin face aux changements climatiques en réduisant la vulnérabilité, en intégrant l’adaptation au climat dans les politiques et en promouvant un développement durable. Les principales priorités stratégiques incluent la promotion de modes de consommation et de production durables, la gestion durable des ressources naturelles et des écosystèmes, ainsi que la mise en place de systèmes multirisques d’alerte précoce pour les catastrophes telles que les inondations et la montée du niveau de la mer. Le plan définit des objectifs pour garantir une gouvernance résiliente, une gestion des ressources naturelles efficace et des mécanismes socio-économiques inclusifs pour faire face aux risques climatiques, tout en soutenant les politiques sectorielles nationales.

Extreme temperatures already claim more lives around the world than any other natural hazard and under climate change this risk is increasing. Nevertheless, whilst the scale of the problem is increasingly recognised, understanding the lived experience of excess heat is a major research challenge.

A key issue facing such efforts is that heat stress is socially as well as geographically determined. The thermal experience of climate change is thus determined both by one’s position in space, and one’s position in society. The jobs we do, the roles we play in society, the conditions we work in, and our freedom within those roles, all shape our exposure to the changing climate. Recognising that the complexity and uniqueness of the climate crisis means we cannot continue to plan for it using the tools of the past, Oppressive Heat brings together a brand new suite of conceptual and methodological tools with which to analyse, interpret and address the dynamic global geography of thermal exposure under climate change.

Focusing on Cambodia, one of the world’s hottest and most humid countries, Oppressive Heat will show how climate impacts are shaped by positionality within the dynamic and interconnected global workplace. Aiming to initiate and develop a crucial new social-environmental scientific nexus on the working body under climate change, we work actively with governments, unions and scholars to reshape global understanding of heat stress in our warming world.

Pregnant women from socioeconomically disadvantaged populations living in tropical climates are most vulnerable to the effects of climate change. Extreme heat has been linked to preterm birth, fetal growth restriction, stillbirth and preeclampsia. We aim to describe how extreme heat leads to these outcomes by studying in detail heat exposure and physiological responses in women across India. Our study involves three linked activities. We will use the Garbh-Ini retrospective cohort (10 000 mother-baby pairs) to identify biomarkers and clinical factors associated with heat exposure and adverse outcomes. We will also describe how the fetal heart rate changes with heat exposure by studying a large database of 110 000 antenatal fetal heart traces recorded across India. These findings will inform a prospective, matched cohort study of 600 women vulnerable to heat stress across three different climate zones. Using state-of-the-art climate, imaging and laboratory diagnostics, we will study how heat exposures affect maternal, placental, fetal and lactational function. We will capture women?s lived experiences with heat, identifying opportunities for local heat adaptation. As findings emerge, we will bring together policymakers, researchers, clinicians and people living with heat to develop practical policies and actions that will protect women and their babies.

In an era marked by the escalating challenges of climate change, the increasing incidence of heat waves presents a significant threat to public safety and environmental well-being. This Heat Wave Action Plan is a testament to our commitment to safeguarding our community against the perils of extreme temperatures. Developed with a focus on resilience and preparedness, it outlines a comprehensive strategy designed to protect the district and its residents from the adverse effects of heat waves. Recognizing the unique vulnerabilities within our community, the plan emphasizes the importance of early warning systems and effective communication to ensure timely and widespread dissemination of heatwave alerts. It advocates for preventive measures against heat-related illnesses and underscores the necessity of a coordinated response that encompasses human, livestock, and agricultural concerns. Central to the success of this plan is the delineation of clear roles and responsibilities for governmental agencies, local authorities, and the community at large. It calls for a unified approach, leveraging the collective strength and resources of all stakeholders to foster an environment of resilience. As we navigate the challenges posed by a warming climate, this Heat Wave Action Plan serves as both a guide and a call to action. It underscores our resolve to proactively address the threats posed by heat waves, ensuring that our district is prepared to respond effectively and protect the well-being of all its inhabitants.

The Heat Wave Management Plan aims to establish a comprehensive framework for managing heat waves in Kishtwar District, focusing on preparedness, response, and recovery. This plan seeks to empower Kishtwar to effectively mitigate the impacts of heat waves and enhance the community’s resilience.

To achieve this, a coordinated multi-agency approach is essential for effective district-level management of heat waves. Currently, heat wave issues are addressed primarily at an operational level; however, a strategic approach is necessary. Clear roles and responsibilities must be defined, along with robust strategic monitoring processes.

Additionally, there is a need for greater clarity regarding the triggers for activation and the sharing of data across various systems. Comprehensive mapping and analysis of the extreme heat impacts on the community will further enhance our understanding and response capabilities.

As the sun beats down relentlessly, we find ourselves grappling with a pressing challenge: the heatwave. In recent years, the frequency and intensity of extreme heat events have risen, posing significant risks to the health, well-being, and livelihoods of our community. In response to this growing threat, we present the Heatwave Action Plan—a comprehensive strategy crafted to enhance resilience, mitigate risks, and foster adaptation in the face of extreme heat. This action plan is the culmination of extensive research, collaboration, and stakeholder engagement. We have drawn upon scientific expertise, local knowledge, and global best practices to develop a framework that addresses the multifaceted dimensions of the heatwave phenomenon. From the identification of heat-vulnerable populations to the implementation of early warning systems, each component of this plan is meticulously designed to protect the most vulnerable among us and build a more resilient community. Central to our approach is a commitment to inclusivity and equity. We recognize that the impacts of the heatwave are not evenly distributed, with marginalized communities often bearing the brunt of its effects. As such, this action plan prioritizes targeted interventions and support for those most in need, ensuring that no one is left behind in our pursuit of resilience.

The Heat Wave Action Plan for Rajkot City is a comprehensive strategy aimed at mitigating the adverse effects of heat waves and enhancing the city’s resilience to extreme heat events. Designed to protect vulnerable populations and reduce heat-related health risks, the plan outlines preventive and responsive measures across multiple sectors, including health, infrastructure, and public awareness. The Rajkot Heat Wave Action Plan emphasizes coordination between local government agencies, healthcare providers, and community organizations, aiming to minimize the impact of heat waves and improve long-term climate resilience in the city.

The National Health and Climate Strategy (the Strategy) is a whole-of-government plan to address the health and wellbeing impacts of climate change and the contribution the health system make to climate change through the generation of greenhouse gas emissions in care delivery. The 49 actions the Australian Government has committed to under the Strategy will require a range of approaches to deliver successfully. Key to the Strategy’s implementation will be a systematic approach to managing a complex program of work, coordination and leveraging of related policy across all levels of government, a diverse range of portfolios, and the mobilisation of numerous external stakeholders including communication with consumers to increase awareness and promote behaviour change.

This case study profiles the unique and pioneering approach of the International Federation of Red Cross and Red Crescent Societies (IFRC) in preparing for and mitigating the health threats of climate change through anticipatory action. The IFRC links locally led humanitarian action with regional- and global-scale responses and surge support through forecast-based financing from the Disaster Response Emergency Fund (DREF).

This case study profiles the efforts of the United States National Oceanic and Atmospheric Administration (NOAA) and other partners to enhance the region’s preparedness and response capabilities, mitigating the health threats of climate change through heat-health early warning (HHEW) systems in the Sahel. An initial pilot, launched in Senegal in 2023, was led by the National Agency of Civil Aviation and Meteorology (ANACIM) and the Directorate General of Public Health (DGSP) at the Ministry of Health and Social Action (MSAS).

The Heat Action Plan aims to provide a framework for implementation, coordination and evaluation of response activities in cities/ town to reduce the negative impacts of extreme heat. The primary objective is to spread awareness at places where extreme heat conditions exist or are imminent and alert people at risk of heat related illnesses to take appropriate precautions. The Plan also calls for preparedness measures to protect livestock/ animals as extreme heat causes signifi cant stress to them as well. The Heat Action Plan intends to mobilize diff erent stakeholders like government authorities and communities to help protect their neighbors, friends, relatives, livestock and themselves against preventable health problems during spells of scorching temperatures. The Plan also aims to support early warning agencies as well as the media for timely information dissemination. The administrative and preventive actions that need to be taken by multiple agencies, ministries and departments are enumerated in Table 5. All States/ districts/cities/towns can learn from their/ others’ experiences and develop a plan to tackle Heat Wave situations eff ectively (NDMA Guideline 2019).

Jodhpur’s HAP, slated for launch this heat season, will prioritize an enhanced focus on the needs of particularly vulnerable groups, identified through a risk assessment (RA) that characterizes spatial patterns in heat-sensitive populations, environmental risks, and community assets. Scientific evidence in understanding how the population is affected in different regions is crucial in developing HAPs. The risk score of each ward in the city accounts for local heat exposures, household inhabitants’ physical sensitivity to heat, and adaptive capacity to minimize exposures through resources like urban cooling centres, parks, and water distribution nodes. The power of the RA approach is its flexibility to incorporate a range of relevant data sources—spanning from individual biophysical characteristics to population-level demographic, health, economic, and environmental data. The Jodhpur RA will form the basis for the city’s Heat Action Plan, as the index provides new spatial information for municipal leaders to identify heat exposure risks and prioritize ‘at-risk’ areas for targeted local interventions

This plan aims to provide strategies to manage and reduce the impacts of extreme heat, including early warnings, capacity building, public awareness,  emergency response, and coordination among stakeholders to protect at-risk populations.

This plan aims to facilitate the stakeholders by providing insight into various aspects related to heat risk reduction and mobilization of stakeholders and coordination among various departments, individuals and community based organization for mitigating the impacts of heat wave. The aim is to protect lives of citizens and take preventive measures so that impact of heat wave can be mitigated.

Goa State Action Plan: Prevention and Mitigation of Impacts of Heat Wave 2024 aims to provide a framework for the implementation, coordination and evaluation of extreme heat response activities in Goa State that reduce the negative health impacts of extreme heat. The plan’s primary objective is to alert those populations most at risk of heat-related illness that extreme heat conditions either exist or are imminent, and to take appropriate precautions. This plan will also lay down the role and responsibility of variuos departments in various alert signs. The Standard Operating Procedures have also been laid down by the Goa SDMA for Heat Waves.

This plan is a package of mitigative measures and aims to protect lives of citizens without affecting individual livelihoods or macro-economic growth and stability. It provides insights into various aspects related to heat risk prevention, reduction and mitigation. It is also aimed at facilitating convergence and coordination among all the stakeholders including departments, individuals and community-based organizations for mitigating the impacts of heat wave.

The Heatwave Action Plan aims to provide a framework for implementation, coordination and evaluation of extreme heat response activities in cities/town in India that reduces the negative impact of extreme heat. The Plan’s primary objective is to alert those populations at risk of heat-related illness in places where extreme heat conditions either exist or are imminent, and to take appropriate precautions, which are at high risk. Preventive heat management and the administrative action need to be taken by the concerned ministries/departments are enumerated in Table 5. All cities can learn from their experience and develop a plan to deal with Heatwave in their specific cities/town and thus reduce the negative health impacts of extreme heat. In addition the State Governments should also prepare a comprehensive plan to combat heat wave.

The Heat Measures Toolbox is aimed at professionals and authorities who wish to contribute to protecting the population from heat. The Heat Measures Toolbox outlines action options for preventing heat-related health problems, contains many concrete tips, and highlights what other stakeholders (primarily in the healthcare sector) have already implemented. The short-, medium-, and long-term measures can be implemented individually, but their combined effect is greater.

This plan is made up of 136 actions, organized thematically into twenty focus areas and further organized to align with the priorities outlined in the foundational policy framework of New Jersey’s Climate Change Resilience Strategy. Action commitments address the activities completed, ongoing, or recommended in individual agencies, as well as efforts that cut across several or all state agencies who make up the Interagency Council on Climate Resilience (Figure 1). Actions included in this plan are designed to address community health, equity and justice, research needs, coordination of government, and funding, financing, and investment needed to implement the action, in accordance with the Resilience Strategy.

The Plan establishes a Surveillance and Information System that considers temperatures posing health risks in the geographical area of the Community of Madrid. Based on existing scientific literature, a maximum threshold of 36.5°C was set, beyond which there is a significant increase in mortality, prompting the activation of health protection measures. From June 1 to September 15, daily (excluding weekends and holidays) risk/alert levels for heat are communicated to the general population, healthcare and social professionals, and institutions responsible for socio-sanitary care of vulnerable groups. This ensures readiness well in advance of potential heatwaves and strengthens intervention mechanisms. A crucial aspect of the Plan involves monitoring morbidity and mortality throughout the campaign to compare observed data with expected trends, thereby detecting any unusual increases early on.

El objetivo principal del plan es mitigar el impacto negativo de las temperaturas extremas en la salud pública. Para lograrlo, se busca reducir los efectos adversos del aumento de la temperatura durante el verano y posibles olas de calor. Esto implica la colaboración activa entre la Administración Central, la Junta de Andalucía y la Administración Local para implementar medidas efectivas. Además, se pretende establecer un sistema de coordinación y compartir información entre las instituciones involucradas. Los esfuerzos preventivos se concentran en las poblaciones más vulnerables a enfermedades y muertes relacionadas con el calor elevado, identificándolas y proporcionando seguimiento personalizado utilizando los recursos disponibles.

The main objective of the plan is to mitigate the negative impact of extreme temperatures on public health. To achieve this, efforts aim to reduce the adverse effects of increased summer temperatures and potential heatwaves. This involves active collaboration among the Central Administration, the Junta de Andalucía, and Local Administration to implement effective measures. Additionally, the plan seeks to establish a coordination system and share information among the involved institutions. Preventive efforts focus on populations most vulnerable to illnesses and deaths related to high heat, identifying them and providing personalized monitoring using available resources.

El presente Plan establece las medidas necesarias para reducir los efectos asociados a las olas de calor y las instituciones implicadas en el establecimiento de dichas medidas, tanto de la Administración Autonómica como de la Central y Local y de instituciones privadas. El Plan intenta recoger la magnitud real del problema, el conocimiento científico existente y las estimaciones de futuro; a continuación especifica las acciones previstas para la prevención de los efectos sobre la salud, y para la detección y control de las alertas, estructuradas en varios niveles de actuación según el nivel alcanzado por las temperaturas por zonas geográficas provinciales y comarcales, en función de los umbrales de temperatura obtenidos de las series temporales de las mismas. Por último, se establecen los criterios de un sistema de información que permita la vigilancia activa de los riesgos asociados a la exposición a temperaturas extremas, con recogida de información predictiva sobre temperatura ambiental, información asistencial y epidemiológica.

The present Plan establishes the necessary measures to reduce the effects associated with heatwaves and the institutions involved in implementing these measures, including the Regional, Central, and Local Administration, as well as private institutions. The Plan aims to assess the real magnitude of the problem, existing scientific knowledge, and future projections. It specifies planned actions for health effects prevention, detection, and control of alerts, structured across various levels based on temperature thresholds obtained from temporal series by provincial and regional geographic zones. Finally, it outlines criteria for an information system enabling active surveillance of risks associated with extreme temperatures, collecting predictive data on ambient temperature, healthcare, and epidemiological information.

El presente documento es la actualización del contenido del Plan anterior y su adaptación al Plan Nacional de Actuaciones Preventivas de los Efectos del Exceso de Temperaturas sobre la Salud, aprobado por la Comisión Interministerial en su reunión del 26 de abril de 2022. Su aplicación, está cumpliendo su principal objetivo: la prevención de daños a la salud provocados por el exceso de calor.

El Plan establece las medidas necesarias para reducir los efectos asociados a las temperaturas excesivas y coordinar las instituciones de nuestra Comunidad implicadas. Describe la magnitud del problema, el conocimiento científico de los efectos de las temperaturas excesivas sobre la salud y los factores de riesgo asociados. También se especifican las acciones previstas para la prevención y control, estructuradas en varios niveles de actuación según el nivel alcanzado por las temperaturas. Se establecen los criterios de un sistema de información que permita la vigilancia activa de los riesgos asociados a la exposición a temperaturas excesivas. Así mismo, plantea la recogida de información predictiva sobre temperatura ambiental, información sobre las variaciones de la demanda asistencial e información diaria sobre los cambios cuantitativos de la mortalidad.

Un aspecto esencial de este Plan es la implicación de los Servicios Sociales, ya que las personas mayores son las más desprotegidas y vulnerables. La participación de la administración (central, autonómica y local), de las organizaciones sociales, y sobre todo la concienciación y el apoyo a los colectivos más sensibles, resultan necesarios para evitar posibles daños en la población.

The present document is an update of the previous Plan and its adaptation to the National Plan for Preventive Actions Against the Effects of Excessive Temperatures on Health, approved by the Interministerial Commission in its meeting on April 26, 2022. Its implementation aims to prevent health damage caused by excessive heat.

The Plan establishes necessary measures to reduce effects associated with excessive temperatures and coordinate involved institutions in our Community. It describes the problem’s magnitude, scientific knowledge on the health effects of excessive temperatures, and associated risk factors. Planned actions for prevention and control are detailed across different intervention levels based on temperature levels. Criteria for an information system allowing active monitoring of risks associated with excessive heat exposure are set. Additionally, it proposes collecting predictive information on ambient temperature, data on variations in healthcare demand, and daily information on quantitative changes in mortality.

An essential aspect of this Plan involves the involvement of Social Services, given that older adults are the most unprotected and vulnerable. Engagement of central, regional, and local administrations, social organizations, and particularly raising awareness and supporting sensitive groups, are necessary to prevent potential harm to the population.

In 2004, Spain launched the National Plan for Preventive Actions Against the Effects of Excessive Heat on Health, aiming to reduce potential impacts of high temperatures during summer. Since its inception, the National Plan has continuously improved over the years, positively impacting the prevention of health problems and illnesses related to excessive heat exposure.

2023 marks the nineteenth year that the Ministry of Health has planned and managed the National Plan, highlighting its crucial role in preventing health impacts from high temperatures. Experts predict that heatwaves will become more frequent and prolonged due to climate change.

Every summer, the Ministry of Health provides health authorities and citizens with information on the health effects of high temperatures, along with daily risk levels for excessive heat, aiming to prevent health impacts from high temperatures.

In Vienna, the increase in urban heat is the most strongly perceived consequence of progressive climate change. But not only average temperatures over the whole year are on the rise: Particular stress is caused by more and more frequent and longer heatwaves characterised by high temperatures over several consecutive days with only minimal cooling-off during the night hours. Moreover, heat is not evenly distributed across the city: The heat island effect is felt especially in densely built-up inner-city districts – here, temperatures are in part significantly higher than in the outskirts and environs of Vienna. For city dwellers, heat constitutes a source of growing stress that can lead to severe health impairments and even to death.

All over the world, heatwaves are already among those natural disasters with the highest number of fatalities. They especially affect vulnerable individuals and risk groups including elderly and socially isolated people, persons in need of care, individuals with chronic or mental diseases, pregnant women, young children or people living and working under particularly difficult conditions. For this reason, it is the goal of the present Heat Action Plan to proactively define measures that are necessary both for the prevention of overheating in the city and for coping with heat when it actually occurs. This is to prepare above all the health facilities, care and nursing institutions of Vienna for heat-related emergencies and protect the population against the negative health effects of heat.

The emphasis of the Heat Action Plan is on heat-related ad-hoc measures and on measures that must be taken at relatively short notice to be well prepared for hot spells during the summer months. For this purpose, the Heat Action Plan specifies 29 key measures, half of which target the entire urban population, while the second half focuses on the particular needs of specific vulnerable groups. Further measures are aimed at the long-term avoidance or reduction of heat in the city – however, these measures are mentioned in the Heat Action Plan only by way of example and described in greater detail in other documents of the City of Vienna, such as the Vienna Climate Guide.

Le plan d’action canicule énumère des recommandations à la population en cas de grande chaleur.

The Luxembourg heatwave action plan lists recommendations to the population in case of extreme heat events.

Ce plan n’a pas vocation à remplacer le plan géré par le ministère de la santé s’agissant des risques sanitaires, mais à le compléter. Un retour d’expérience interministériel a été mené à la suite des deux épisodes de canicule de 2019, ainsi qu’à l’épisode de sécheresse de 2022. Il en est ressorti que, si le système de santé n’a globalement pas été mis en tension pendant ces deux épisodes grâce à l’activation du plan national canicule, ces vagues de chaleur ont impacté l’ensemble de la population et ont eu des conséquences majeures dans de nombreux domaines : fermeture de classes et de crèches, report d’examens scolaires, annulation de manifestations sportives et culturelles, perturbations dans les transports en commun et grande pénibilité pour les usagers, mortalité animale, assèchement des cours d’eau et difficultés d’approvisionnement en eau potable, feux de récolte… Il a ainsi été décidé de prolonger le plan national de gestion des vagues de chaleur afin de prendre en compte tous les impacts de ces événements. Ce plan a pour objectifs de se préparer de façon systématique en amont de la période estivale puis d’anticiper l’arrivée prévue d’une vague de chaleur et de définir les actions à mettre en œuvre aux niveaux national et local pour en prévenir et en limiter les impacts. Il prend en compte les particularités des territoires d’outre-mer qui, de par leurs situations géographiques et climatiques, l’impact du changement climatique et l’augmentation des températures, le manque d’infrastructures et d’entretien de celles-ci, sont confrontés à d’importantes vagues de chaleur sur de longues périodes.

This plan is not intended to replace the plan managed by the Ministry of Health regarding health risks, but to complement it. An interministerial feedback was conducted following the two heatwaves of 2019, as well as the drought episode of 2022. It was found that although the healthcare system was generally not strained during these episodes due to the activation of the national heatwave plan, these heatwaves impacted the entire population and had major consequences in many areas: closure of schools and daycare centers, postponement of school exams, cancellation of sports and cultural events, disruptions in public transport causing significant inconvenience to users, animal mortality, drying up of watercourses, difficulties in water supply, crop fires, among others. It was thus decided to extend the national heatwave management plan to take into account all impacts of these events.

The objectives of this plan are to systematically prepare in advance of the summer period, anticipate the expected arrival of a heatwave, and define actions to be implemented at the national and local levels to prevent and limit its impacts. It considers the specificities of overseas territories which, due to their geographical and climatic situations, the impact of climate change, the rise in temperatures, and the lack of infrastructure and maintenance thereof, are confronted with significant heatwaves over long periods.

Hitzewellen sind auch in Tirol keine Ausnahmeerscheinung mehr. Länger andauernde Hitzeperioden können körperlich sehr anstrengend sein und zu ernsthaften Gesundheitsproblemen führen. Besonders gefährdet sind ältere Menschen, Kinder, Schwangere sowie Menschen mit chronischen Erkrankungen. Bereits einfache Maßnahmen können jedoch helfen, gesund durch die Hitzewelle zu kommen. Gemeinsam mit den tirol kliniken startet deshalb am Montag, den 3. Juli 2023, eine breitgefächerte Hitzeschutz-Kampagne des Landes, die mit fünf praktischen Tipps auf das richtige Verhalten während Hitzeperioden aufmerksam macht.

Heat waves are no longer an exception in Tyrol. Long periods of heat can be physically demanding and can lead to serious health problems. Older people, children, pregnant women and people with chronic illnesses are particularly at risk. However, even simple measures can help you get through the heat wave. Together with the Tyrol clinics, the state is launching a broad heat protection campaign, which will provide information on how to protect yourself during heatwaves.

This document provides strategic guidance, and is intended for use across SA Health, including the Department for Health and Wellbeing (DHW), Local Health Networks (LHNs), SA Ambulance Service (SAAS), Wellbeing SA and all other SA Health clinical support services. This document is not mandatory but serves to guide all areas within SA Health in developing and maintaining their localised planning and preparedness to respond to extreme heat and heatwaves, and establish their own procedures, arrangements or plans specific to their context.

This document also recognises and acknowledges the important role the wider health, aged care and disability sectors plays during extreme heat and heatwave events, including Aged Care, General Practice, Pharmacies, Community Health, and Disability services – some of whom are Commonwealth government or non-government organisations (NGOs), as well as private businesses. Guidance for these sector partners is included within this document, for their consideration, as part of their preparedness for extreme heat and heatwaves in South Australia.

This state Heatwave Sub Plan describes the strategic emergency management arrangements for heatwaves affecting New South Wales, including Lord Howe Island. This Plan is written and issued under the authority of the NSW State Emergency and Rescue Management Act 1989 (‘SERM Act’) and the NSW State Emergency Management Plan (EMPLAN). In addition to these instruments, the following Acts and Regulations apply to managing Heat Waves in New South Wales. This plan has been prepared on behalf of the State Emergency Operations Controller and was endorsed by the State Emergency Management Committee, in accordance with the State Emergency and Rescue Management Act 1989 (as amended), Section 15 (e), in April 2023. This plan acknowledges and aligns with the National Heatwave Warning Framework, which includes guidance on the use of the Australian Warning System for heatwaves Heatwave Service for Australia (bom.gov.au)

This State Emergency Management Plan (SEMP) Extreme Heat Sub-Plan contextualises the current arrangements, roles and responsibilities for planning, mitigation, preparedness, response (including relief) and recovery from all extreme heat events, regardless of their duration. For the purposes of this Sub-Plan, extreme heat events include low-intensity, severe and extreme heatwaves (three or more consecutive days of high temperatures), or one or two days of abnormal high temperatures which would impact the general population and include consequences for essential services, energy and water supply, health and wellbeing and the environment. The metric for defining heatwaves is the Excess Heat Factor (EHF), which correlates to one of three heatwave levels: low-intensity, severe or extreme heatwaves (see section 2). Operational activities of agencies or businesses are covered within their respective operational plans. Agency specific operational or business continuity plans may be enacted to manage the impacts or consequences of extreme heat events, without state level arrangements being triggered.

In January 2009, Victoria experienced an unprecedented statewide heatwave, with Melbourne experiencing three consecutive days of temperatures above 43°C and little overnight relief. The report by the Office of the Chief Health Officer concluded that there were 374 additional deaths during the heatwave in comparison to the previous five years. The Heatwave Planning Guide is designed to assist local councils in addressing the risks associated with heatwaves at a community level. Internationally, heatwave plans are commonly used to minimise the health impact of heatwaves

Die Erderwärmung lässt auch in gemäßigten Klimaregionen die Zahl der Hitzetage und Tropennächte steigen. Das erfordert intensive Vorkehrungen und Maßnahmen zur Klimaanpassung und zum Schutz der Gesundheit. Die Vorarlberger Landesregierung hat daher einen Hitzeschutzplan erarbeiten lassen, der sich an die ganze Bevölkerung sowie speziell an Gemeinden, Pflege- und Kinderbetreuungseinrichtungen richtet. „Damit haben wir jetzt erstmals eine umfassende Informationssammlung und Handlungsanleitung, die auch als Grundlage für künftige Entwicklungen dienen soll“, so Landeshauptmann Markus Wallner und Gemeindeverbands-Vizepräsidentin Andrea Kaufmann.

Global warming is causing the number of hot days and nights to rise even in temperate climate regions. This requires intensive precautions and measures to adapt to climate change and protect the health of people. The Vorarlberg state government has therefore had a heat protection plan drawn up that is aimed at the entire population and specifically at communities, nursing and childcare facilities. “This means that for the first time we now have a comprehensive collection of information and instructions for action that should also serve as a basis for future developments,” said Governor Markus Wallner and Vice President of the Association of Municipalities Andrea Kaufmann.

Hitzewellen kommen in regelmäßigen Abständen in unseren Breitengraden vor. Zusätzlich ist auch aufgrund der Klimaerwärmung mit einem gehäuften Auftreten von anhaltenden intensiven Hitzeperioden zu rechnen. Eine Hitzewelle liegt vor, wenn anhaltende Tag- und Nacht temperaturwerte erreicht werden, die eine massive Belastung der Gesundheit von Personen bzw.Risikogruppen mit sich bringen. Die WHO empfiehlt die Entwicklung von Strategien, Plänen und Maßnahmenpaketen zum Zwecke der bestmöglichen Einstellung der Bevölkerung auf Hitzebelastungstage und des effektiven Handlings von Aufgaben des Öffentlichen Gesundheitsdienstes (ÖGD), die durch das Auftreten von Hitzewellen entstehen.

Heat waves occur at regular intervals in our latitudes. In addition, due to global warming, a more frequent occurrence of sustained, intense heat periods is to be expected. When a heat wave occurs sustained day and night temperatures negatively affect the  health of people and groups at risk. The WHO recommends the development of strategies, plans and packages of measures to ensure that the population is as well prepared as possible for days of heat stress and to effectively handle public health tasks that arise from the occurrence of heat waves.

Der nationale Hitzeschutzplan beschreibt unterschiedliche Maßnahmen, die auf Bundesebene in Kooperation mit den Bundesländern und der GeoSphere Austria im Fall von Hitze insbesondere bei länger andauernden Hitzewellen unternommen werden. Dadurch wird ein Rahmen für zusätzliche Schritte auf Länderebene sowie auf regionaler und lokaler Ebene geschaffen, um die in Österreich lebende Bevölkerung bestmöglich vor den gesundheitlichen Auswirkungen von Hitze zu schützen.

Es handelt sich beim nationalen Hitzeschutzplan somit um eine Anleitung für das Vorgehen des für Gesundheit zuständigen Ministeriums sowie sonstiger Behörden und Organisationen. Dazu zählen insbesondere Gesundheitseinrichtungen und Sozialorganisationen auf Länder- bzw. Gemeindeebene, die im vorliegenden nationalen Hitzeschutzplan Verweise auf Werkzeuge und internationale gute Praxis für weiterführende Maßnahmen finden. Der vorliegende Hitzeschutzplan wird regelmäßig unter Berücksichtigung neuer wissenschaftlichen Erkenntnisse evaluiert und erforderlichenfalls adaptiert. Insofern ist er als lebendes Dokument anzusehen.

The national heat protection plan describes measures that are taken at a federal level in cooperation with the federal states and GeoSphere Austria during a extreme heat event, particularly during longer-lasting heat waves. This creates a framework for additional steps at state, regional and local levels in order to best protect the population living in Austria from the health effects of extream heat.

The national heat protection plan is therefore a guide for the actions of the ministry responsible for health and other authorities and organizations. These includes health facilities and social organizations at state or municipal level, which will find references to tools and international good practices for further measures. This heat protection plan is regularly evaluated taking into account new scientific findings and adapted if necessary. In this respect, it should be viewed as a living document.

The Maryland Extreme Heat Emergency Plan, developed by the Maryland Department of Health (MDH), guides the state’s actions during an Extreme Heat Event, as well as those of partner agencies and organizations, as defined below. This plan also provides guidance for the local health departments (LHDs) as they fulfill their roles; however, it does not mandate that LHDs perform the actions described. The Office of Preparedness & Response (OP&R) within MDH provides weekly heat reports on the OP&R webpage during each heat season.

The purpose of this plan is to provide information and to identify the Department of Health and Human Services’ (DHHS) role in response to excessive heat emergencies in the State in collaboration with the NH Public Health Regions (PHR) and with other State agencies, and in accordance with the National Incident Management System (NIMS). The plan includes the threshold for response activation, a description of heat indices and associated health risks, response activities by heat emergency phase, and criteria for cooling centers. It also includes templates for an extreme heat press release, hotline script, health alert message, and heat fact sheet.

Port Moody’s Climate Action Plan is a community-wide plan that outlines actions to help the City and its residents adapt to climate change and reduce greenhouse gas emissions (GHGs) that contribute to the warming of the Earth.

The Climate Action Plan considers both aspects of climate change planning: mitigation and adaptation. Mitigation – working to reduce or prevent the emission of GHGs – is an important part of responding to climate change. However, even if we significantly reduced GHG emissions overnight, the effects of climate change would continue to be felt by future generations for a long time to come. That’s why our Climate Action Plan also focuses on adaptation measures, which will help us adjust to our new normal in Port Moody and reduce our vulnerability to the harmful effects of climate change.

This low carbon resilience (LCR) approach demonstrates that adaptation and mitigation are two sides of the same coin; both are proactive responses that minimize the risks of climate change and build resilience into the future. Integrating the two at all levels of policy, planning and practice will align climate action goals and advance the transition toward a more energy efficient, resilient, and sustainable future.

HEATS (Heat Exposure, AcTivity, and Sleep) is a three-year, multi-institutional project focused on improving sleep outcomes for people exposed to heat. Funded by the Singapore National Research Foundation, the project will develop technological and behavioral solutions to minimize heat exposure for improved sleep.

The project is structured as three distinct and complementary components: 1) continuous monitoring of more than 100 working-age persons over several months to study the effect of heat exposure on sleep, 2) develop and evaluate a novel bedroom and worker dormitories cooling solution, and 3) deploy and test personalized smartphone nudging strategies to improve sleep environments.

The project team is comprised of researchers from University of California, Berkeley, the National University of Singapore, and The University of Sydney. The expertise of the 6-member team includes thermal physiology, sleep quality, indoor environmental quality, thermal comfort, and machine learning. The Principal Investigators are Stefano Schiavon (UC Berkeley) and Jason Kai Wei Lee (NUS). Co-Investigators include June Chi Yan Lo (NUS), Clayton Miller (NUS), Thomas Parkinson (The University of Sydney), and Hui Zhang (UC Berkeley).

While focused on describing the BC HARS, this document also contains general background information on heat events in B.C. and the reason for the establishment of the BC HEAT Committee. Section Two details the development of the BC HARS and describes the criteria for the two alert levels. Section Three contains tables with key messages and recommended actions for different partners and public health actors. In general, information in each table is divided into four parts: pre-season, during a Heat Warning, during an Extreme Heat Emergency, and post-season or deactivation. The final section contains links to relevant resources and appendices.

This document is intended to be used as a resource to support the province-wide implementation of the heat alert and response system in British Columbia. The recommendations in section three of this document are not prescriptive but are intended to be used as tools to initiate heat planning or to complement the creation of more robust heat response plans. Acknowledging the wide variation in local heat response planning needs, not all recommendations may be appropriate for all settings.

The audience for this BC HARS document is all levels of government and all levels of the health system involved in heat preparedness planning, emergency management partners that plan for and respond to heat events, Indigenous governing bodies and local authorities, as well as organizations that work with and interface with susceptible populations and those at greatest risk of mortality during heat events.

In 2023, Greater Sudbury experienced seven days under a heat warning. The Ontario Provincial Climate Change Impact Assessment Technical Report anticipates Northeast and Northwest Ontario will see temperatures from 3.8 and 4.1 days now rise to over 35 days per year, on average, with impacts felt in the far North, Northwest and Northeastern Ontario despite the absolute numbers being lower compared to Southern Ontario. The report goes on to predict that by the 2080s, major cities like Sudbury could see as many as 55 days a year with temperatures over 30 degrees, in comparison to the 10 days being experienced now. The Hot Weather Response Plan (HWRP) is intended to alert those most at risk of heat-related illness that hot weather conditions are either imminent or currently exist and to take appropriate precautions.

Urban areas are the hot spots of global warming. Extreme heat is a key risk to the health and well-being of British Columbians. The situation is growing more dangerous, driven by irreversible climate change. Canada is warming, on average, at twice the global rate. Urban centres face the greatest risk because of the urban-heat-island effect. Surface daytime temperatures can be 10 – 15°C hotter in urban heat islands, while nighttime temperatures can be up to 12°C hotter than in surrounding rural areas. During episodes of extreme heat, everyone is at risk of heat-related illnesses. The danger is greatest for those who are more vulnerable or less able to protect themselves. This includes people who are more sensitive to extreme heat (such as the elderly or chronically ill) and those with fewer resources to adapt (for instance, people on lower incomes who cannot afford actions to retrofit their homes).

The purpose of this plan is to outline the actions available to the City of Surrey to support provincial ministries in mitigating risks to life and safety caused from an extreme heat event. Once a heat event is imminent, Surrey will support the messaging and promote the recommendations made by the governing health authority to our citizens, to ensure consistent information is published.

The central purpose of this report is to increase understanding of the interactions between people, the environment, and the climate in Waitaha Canterbury – to provide planners and decision-makers and the wider community with information that can shape the development of effective responses to climate change.

The scope and extent of climate-related health and wellbeing impacts can be strongly influenced by location and it is important that regional-level adaptation strategies are matched to the specific geographic and demographic characteristics of the Waitaha Canterbury region. This report presents the interim findings of a scoping and profiling assessment that outlines the connections between climate change and health, relevant to the people of Waitaha Canterbury. This report does not specifically cover adaptation or mitigation/transition risks; however, this report does provide some commentary on adaptation and mitigation strategies that could help reduce the health and wellbeing impacts of climate1 . This report describes a range of climate change related determinants of health – incorporating broad perspectives of health and wellbeing.

This report encompasses the first steps of assessing the health and wellbeing impacts of climate change across Waitaha Canterbury and the potential effects on the health and wellbeing of the population and the distribution of those effects within the population

Heat Resilience Solutions for Boston presents a roadmap for navigating extreme heat. By building on the legacy of previous resilience plans, including 2016’s Climate Ready Boston report, we will be prepared to combat climate change. This study centers people and recognizes the challenges extreme heat poses to our quality of life. It focuses on environmental justice neighborhoods that disproportionately face extreme heat: Chinatown, Dorchester, East Boston, Mattapan, and Roxbury

Dit plan schetst de krijtlijnen over hoe en wanneer kwetsbare doelgroepen – en professionals die werken met die doelgroepen – geïnformeerd en gewaarschuwd moeten worden voor en tijdens warmteperiodes. Het actieplan biedt ook handvaten aan professionals om preventieve acties te ondernemen om zo, gezondheidseffecten als gevolg van warmte, te voorkomen. Het Vlaams Warmteactieplan bestaat uit een waakzaamheids- en waarschuwingsfase.

This plan outlines how and when vulnerable groups – and professionals who work with those groups – should be informed and warned before and during extreme heat periods. The action plan also provides tools for professionals to take preventive actions to prevent health effects due to heat. The Flemish Heat Action Plan consists of a vigilance and warning phase.

This Heat Preparedness and Adaptation Plan provides an actionable roadmap and recommendations on how the region can better prepare for and adapt to extreme heat and rising temperatures. This plan primarily addresses strategies and actions that reduce risk and increase preparedness through public health, planning, land use, and other municipal and regional actions. This comprehensive plan also provides strategies and actions to improve municipal and regional response to heat emergencies, although it is not intended to stand in for a robust municipal heat emergency response plan.

Desde 2004 el Plan Nacional de actuaciones Preventivas de los efectos de los excesos de temperaturas sobre la salud se activa cada verano, entre los meses de junio y septiembre.

El objetivo de este Plan es reducir el impacto sobre la salud de la población como consecuencia del exceso de temperatura. El Plan establece las medidas para reducir los efectos asociados a las temperaturas excesivas y para coordinar las instituciones de la Administración del Estado implicadas, así como también se proponen acciones que puedan ser realizadas por las Comunidades Autónomas y la Administración Local en función de los niveles de riesgo asignadas en base a las temperaturas.

Since 2004, the National Plan Heat Action Plan has been activated every summer, between the months of June and September.

The objective of this plan is to reduce the impact on the health of the population as a consequence of the exposure to extreme temperatures. The Plan establishes measures to reduce the effects associated with excessive temperatures and to coordinate the institutions involved, as well as propose actions that can be carried out by the Autonomous Communities and the Local Administration depending on the levels of risk assigned based on temperatures.

Extreme heat can cause illness and death, but effective planning and actions can reduce its effects on health. Because effects of heat are associated with relative rather than absolute temperatures, even in New Zealand’s temperate climate people can experience negative health effects with modest increases in seasonal temperature. The purpose of these guidelines is to assist health and community service providers, health sector organisations, local government and other community organisations prepare heat health response plans.

The main sections of these guidelines are:

• objectives and scope – objectives and scope for these guidelines and how they fit into existing statutory frameworks
• heatwave hazard – the potential of heatwaves as a health hazard and the relevance of heatwave health planning in New Zealand
• health effects of heatwaves – heatwave-related health effects and vulnerable populations
• heat health actions – risk management actions.

These guidelines are a companion document to Heat Health Plans: Key Information (Te Whatu Ora 2023).

Am20.11.2023 hat unter der Leitung von Minister Prof. Karl Lauterbach mit allen verantwortlichen Akteurinnen und Akteuren von Bund, Ländern, Kommunen, Selbstverwaltungspartnern, Verbänden und Zivilgesellschaft eine „Statuskonferenz Hitzeschutz Gesundheit“ stattgefunden. In diesem Rahmen wurde eine Bestandsaufnahme und Analyse bestehender Konzepte und Ressourcen für Hitzeschutzmaßnahmen durchgeführt und konkrete Ziele und Maßnahmen identifiziert, die zur Verstetigung und Weiterentwicklung des gesundheitlichen Hitzeschutzes auf Bundesebene und zur Vorbereitung von Hitzeschutzmaßnahmen im Sommer 2024 dienen sollen.

Eine “Roadmap für den Sommer 2024“ bündelt und konkretisiert diese Ziele und Maßnahmen, die auch auf den Empfehlungen und Vorschlägen der im „Hitzeschutzplan für Gesundheit des BMG“ eingebundenen Akteurinnen und Akteure basieren.

On November 20, 2023 , a “Status Conference on Heat Protection Health” was held under the leadership of Minister Prof. Karl Lauterbach with all responsible actors from the federal government, states, municipalities, self-government partners, associations and civil society. In this context, an inventory and analysis of existing concepts and resources for heat protection measures was carried out and concrete goals and measures were identified that should serve to consolidate and further develop heat protection for health at the federal level and to prepare heat protection measures in summer 2024.

A “Roadmap for Summer 2024” bundles and specifies these goals and measures, which are also based on the recommendations and suggestions of the actors involved in the “ BMG ’s Heat Protection Plan for Health”.

Der Schwerpunkt der Initiativen liege derzeit vor allem auf der Kommunikation und der Sensibilisierung, erklärte der Bundesgesundheitsministers. Das sei wichtig, um kurzfristig wirksam Hitzeschutz zu betreiben. Prof. Karl Lauterbach: „Langfristig wollen wir uns aber auch strukturell besser aufstellen. Dafür werden wir uns im Herbst zu einer Statuskonferenz zusammenfinden, um uns für den Sommer 2024 zu rüsten“.

The focus of this initiative is currently on communication and raising awareness, explained the Federal Minister of Health. This is important in order to provide effective heat protection in the short term. Prof. Karl Lauterbach: “In the long term, however, we also want to position ourselves better structurally. To this end, we will meet in the autumn for a status conference to prepare ourselves for the summer of 2024.”

Responding to heat will require a mix of mitigation (reducing temperatures and limiting heat exposure) and adaptation (coping when heat cannot be mitigated); physical, social, and policy interventions; and action by the City, professional partners, property owners, and community members. While some solutions can be quickly implemented, others will take months or years to put in place. Solutions exist at the household level and community-wide. As local leaders and residents plan for a hotter future, it will be essential to consider a range of heat mitigation and adaptation options, and select a complementary blend of solutions which meet immediate and long term needs. Ideally, heat mitigation solutions can integrate with existing priorities to address other environmental and health hazards (e.g., air pollution and stormwater runoff). This guidebook presents solutions which are supported by existing literature, and which are suitable for the steppe climate of Sedona. Of the multiple solutions to mitigate heat, literature overwhelmingly emphasizes tree planting and preservation because trees offer numerous co-benefits such as air quality improvement, stormwater retention, flood reduction, improved neighborhood aesthetics, and increased property values. However, trees are not appropriate in all situations, nor are they the only available option for heat mitigation. In Sedona, a city positioned near the southwest Arizona desert and coping with regional drought, trees are not the most obvious line of defense, though they are one option. In addition to a summary of the benefits and challenges associated with trees, content will emphasize lesser known options which can support, replace, complement, or amplify a vegetation-based strategy. The guidebook includes ideas for maximizing the effectiveness and sustainability of various heat mitigation and adaptation strategies. This is not a prescriptive implementation plan, but rather an offering of potential solutions to help stimulate and structure ongoing conversations about extreme heat.

Austin’s first Heat Resilience Playbook identifies neighborhood-based and citywide projects, programs, and policies that can be leveraged to combat extreme heat. This Playbook seeks to uplift existing City-led heat resilience efforts and outline a series of high-impact actions that the City of Austin can take, with additional funding and resources, to build heat resilience. The actions outlined in this Playbook are structured through a three-pillar approach that focuses on individuals, neighborhoods, and our built and living environment. Strategies and actions identified are informed by Austin’s most recent localized extreme heat data and the latest international best practices. The strategies and actions are also a result of workshops, departmental meetings, office hours, and individual review efforts in collaboration with and consultation from City departments and Austin community members. Each action has associated champions assigned based on interest, capacity, and alignment with existing jurisdiction and responsibilities.

The Heat Action Plan (HAP) of Thane City has been formulated using a combination of climate datasets and climate projections from sources such as the Indian Monsoon Data Assimilation and Analysis (IMDAA) and Regional Climate Models (RCMs) from the Ministry of Earth Sciences (MoES) for the period from 1982 to 2040. It combines these climatic datasets with onground socioeconomic data and satellite-derived indices to map Thane City’s heat risk.

Climatic projections for India indicate that heat extremes are likely to intensify, occur more frequently, last longer, and impact wider geographical areas not previously impacted. Other factors, such as humidity and urban heat islands, particularly in cities, will further exacerbate and compound the risks associated with these extremes. With such record-breaking heat waves already being witnessed nationwide, there is an urgent need to develop and implement heat risk mitigation and adaptation strategies to reduce the impacts of heat waves across various geographical scales.

Thane City’s administration attempted to address these challenges by developing a city-level heat action plan, offering insights into heat risks considering historical trends and projections of dry temperature extremes, humidity, warm nights, and socioeconomic factors at a detailed ward/ Prabhag Samitee level (Figure ES1). The primary objective was to mitigate the impact of heat stress on human health and establish effective pathways for preparedness and response mechanisms.

In response to rising temperatures the City of Tucson has developed this Heat Action Roadmap, a cornerstone of its broader climate resilience initiatives under the Tucson Resilient Together climate action plan. Developed collaboratively, with community members, stakeholders and experts, this roadmap incorporates benchmarked best practices, relevant regional research, and the lived experiences of community members. It focuses on preventive measures, public outreach, infrastructure enhancements, and cross-sectional partnerships to mitigate the health and economic impacts of extreme heat while promoting long-term sustainability and resilience.

The Heat Action Roadmap is structured around three main goals, ten intersectional strategies and 61 actionable items, aiming to mitigate and manage the adverse effects of extreme heat in coordination with cross-sectoral partners. The City of Tucson prioritizes community engagement, data driven strategies, and continuous adaptation to evolving needs. This approach addresses the immediate challenges posed by rising temperatures and fosters a more resilient and equitable city for all Tucsonans.

The mission of the Extreme Heat Action Plan is to reduce the health and economic impacts of increasing extreme heat and create a baseline for further research and new partnerships around this issue. The plan is organized around three main goals and 19 actions.

HPSDMP is the primary agency with responsibility for the hazard of heatwave. The purpose of the Heatwave Management Plan (this plan) is to outline the arrangements for the management of heatwaves in Himachal Pradesh across preparedness, response and recovery. The aim of this plan is to enable Himachal Pradesh to mitigate the effects of, prepare for, respond to, and recover from heatwaves.

The Heat Wave Action Plan 2024 meticulously crafted by the Uttar Pradesh State Disaster Management Authority aligns with global efforts aimed at the climate resilience and disaster risk reduction. This plan echoes the commitments mande during the COP 21 or the Paris  Climate Conference, where nations pledged to adhere to an international climate agreement, striving collectively to limit global warming to below 2 celsius degrees as recommended by the Intergovermental Panel on climate Change (IPCC). The framework stresses the enhancement of national disaster loss databaeses and risk analysis, underscoring the critical importance of data in mitigating disaster impacts.

Delhi Disaster Management Authority developed Heat Action Plan (HAP), as per NDMA Guideline. This aims to facilitate the stakeholders in preparing a Heat Management plan by providing insight into the heat related illness and the necessary mitigative and response actions to be undertaken. It would also help in mobilization and co- ordination of various departments, individuals and communities to focus on heat reduction aspects to help and protect their neighbours, friends, relatives and themselves against avoidable health problems during spell of very hot and dry weather.

To implement Heat Action plan in Delhi the following key strategies have been adopted:

•  Establish Early Warning System and Inter- Agency Coordination
•  Capacity building/ training programme
•  Public Awareness and community outreach
•  Collaboration with Non-Governmental and Civil Society

This document outlines a Harmonized Heat Warning and Information System (HWIS) for dealing with heat events. The aspects of this HWIS include:

• Governance: roles, responsibilities, and decision-making structures
• Triggers for the issuing of various heat warning to the public health units (PHUs) from a central source, and mechanisms for disseminating these warnings
• Definitions of warnings, along with suggested core activities
• Communications messaging to support the various warning levels
• Planning guidance to support PHUs and local partners in their heat response planning

This document is intended to support planning for boards of health and PHUs in Ontario. Other levels of government and potential partners may also choose to use the guidance contained in this document.

The Heat Action Plan (HAP) provides a framework for implementing, coordinating and evaluating extreme heat action across different timescales in Nepalgunj to minimize the negative impacts of extreme heat on the health and livelihood of the city’s residents. The HAP is organized into two sections: 1. seasonal heat risk reduction – focuses on action before, during and after the heat season; and 2. longer term urban planning including heat stress and heatstroke. According to the country’s Ministry of Home Affairs, 25 heatwaves occurred in 2002–2010, with the most significant occurring in 2009 and 2010, mainly in the Terai region of Nepal.

El Plan de Acción Climática de Bogotá D.C. 2020-2050 (PAC) es un instrumento ambicioso que establece las herramientas y los mecanismos necesarios para que Bogotá D.C. enfrente la crisis climática, se consolide como una ciudad carbono neutral y resiliente a los efectos del cambio climático y se mejore el bienestar social y las calidades de vida de su población, en el marco de la justicia climática.

The Climate Action Plan for Bogotá 2020-2050 is an ambitious instrument that establishes the tools and mechanisms necessary for Bogotá D.C. to affront the climate crisis, consolidate itself as a carbon-neutral and become resilient to the effects of climate change and improve the social well-being and quality of life of its population, within the framework of climate justice.

El documento a continuación sintetiza el esfuerzo de diferentes instituciones y dependencias de la Administración Municipal por materializar el compromiso de Medellín en la lucha global frente a la crisis del clima. La estructura del mismo presenta, en primer lugar, la definición de los referentes normativos y antecedentes instrumentales sobre los que se debe garantizar articulación; seguidamente, el plan presenta un resumen del contexto urbano y los principales retos ambientales y climáticos a los que se ve abocada la ciudad para finalizar con los mecanismos de gobernanza y los arreglos necesarios para garantizar su debida implementación.

This document summarizes the efforts of different institutions and agencies of the Municipal Administration of Medellin to materialize Medellín’s commitment to the global fight against the climate crisis. Its structure presents, first of all, the definition of the normative references and instrumental antecedents on which articulation must be guaranteed.  The plan presents a summary of the urban context and the main environmental and climatic challenges that the city is facing and the necessary governance mechanisms and arrangements to guarantee their proper implementation.

Heat Action plan for the province of British Columbia, Canada. This plan aims to provide information on how extreme heat events pose a threat to the health and well-being of communities and what meassures can be in place to avoid them.

This survey report from Sweltering Cities reveals the serious impact that this summer’s heat has had on Australians’ health. The 2024 Summer Survey received more than 2300 responses from people reporting their experience of heat over the summer.

National Disaster Management Authority encompasses the Heat Wave Action Plan in all States to mitigate any loss due to heat waves. This plan aims to provide a framework for the implementation, coordination and evaluation of extreme heat response activities in cities/towns in
India reduces the negative impact of extreme heat. The Plan’s primary objective is to alert the population at risk of heat-related illness in places where extreme heat either exists or is imminent
and to take appropriate precautions which are at high risk. Preventive heat management and the administrative action that needs to be taken by the concerned ministries/departments are enumerated. All
cities can learn from their experience and develop a plan to deal with Heat Wave. Similarly Vadodara Municipal Corporation has released do’s and don’ts related to heat wave alerts as well as the action plan for the city.

The IFRC Disaster Response Emergency Fund (DREF) has approved a total of CHF 499,930 for Heatwave Early Action Protocol (EAP) for Bangladesh Red Crescent Society. The approved amount consists of an immediate allocation of CHF 206,061 for readiness, CHF 44,599 for Pre-positioning stocks and CHF 249,271 automatically allocated to implement early actions once the defined triggers are met. Allocations are made from the Anticipatory Pillar of the DREF, under the DREF appeal code MDR00001. Unearmarked contributions to the DREF are encouraged to guarantee enough funding is available for the Early Action Protocols being developed.

This U.S. Congress Joint Economic Committee report outlines the mounting costs of extreme heat as a growing threat to public health, the economy, and infrastructure.

The report highlights the unequal impacts on disadvantaged communities, and summarizes local, state, and federal efforts to address the impacts of extreme heat.

Este capítulo destaca que el aumento sostenido de eventos de calor extremo, exacerbados por la crisis climática, representa un riesgo significativo para la salud, la economía y la seguridad de las personas en la Región Metropolitana de Santiago. La situación es más crítica en algunas zonas y para algunos grupos particularmente vulnerables, como personas de la tercera edad, enfermos crónicos, mujeres embarazadas, niños y quienes tienen problemas de salud mental. A pesar de lo anterior, se evidencia la ausencia de políticas públicas enfocadas a la gestión de emergencias o un plan de adaptación con medidas urbanas, económicas y sociales orientadas a la resiliencia. A partir de un análisis comprehensivo del riesgo asociado al calor extremo para el Gran Santiago y un estudio de políticas públicas comparadas en 17 ciudades con desafíos similares, se propone que la Región Metropolitana cuente con un plan para la prevención y gestión de la amenaza del calor extremo que incorpore un sistema de alerta temprana, planes de acción específicos para distintas instituciones, y una hoja de ruta a mediano y largo plazo para mejorar la resiliencia urbana y social de la ciudad. Con esto, se busca crear una gobernanza efectiva, asignando responsabilidades claras y proporcionando recursos adecuados para políticas públicas proactivas y adaptativas para enfrentar el calor extremo, mitigando sus efectos adversos en la población y el entorno.

This chapter highlights that the sustained increase in extreme heat events, exacerbated by the climate crisis, represents a significant risk to the health, economy and security of people in the Santiago Metropolitan Region. The situation is more critical in some areas and for some vulnerable groups, such as the elderly, the chronically ill, pregnant women, children and those with mental health problems. Despite the above, the absence of public policies focused on emergency management or an adaptation plan with urban, economic and social measures aimed at resilience is evident. Based on a comprehensive analysis of the risk associated with extreme heat for the Greater Santiago region and a study of public policies compared in 17 cities with similar challenges, it is proposed that the Metropolitan Region needs a plan for the prevention and management of the threat from extreme heat that incorporates an early warning system, specific action plans for different institutions, and a medium and long-term roadmap to improve the urban and social resilience of the city. This seeks to create effective governance, assigning clear responsibilities and providing adequate resources for proactive and adaptive public policies to confront extreme heat, mitigating its adverse effects on the population and the environment.

Heat relief and preparedness work is not new to Arizona, and this Plan builds on the foundation laid by local governments, universities, and organizations (See Spotlights for examples of innovative initiatives on heat preparedness and Appendix C for heat-preparedness milestones). OOR engaged extensively with subject-matter experts and organizations including Arizona State University’s Knowledge Exchange for Resilience (KER), the Human Services Campus, the Arizona Faith Network, cities and towns, and utilities. OOR also invited the public to weigh in on heat-related issues during the planning process. In collaboration with KER, OOR held two state agency workshops to identify knowledge gaps, areas that require additional research, and opportunities for future collaboration and coordination. Agencies used this time to better understand how they can mitigate extreme heat risks throughout their daily operations and how they can better respond to extreme heat events.

Since 2016, the Homefront (i.e., ministries/statutory boards) has relied on a Heatwave Contingency Plan that was based on temperatures reaching up to 35°C over a prolonged period.  However, learning from the severity of 2022’s heatwave episodes in Europe and China and more severe climate change projections, MSE has formed a workgroup comprising representatives from MOE, MOH, MOM, NEA, MCCY, PA, SportSG, to review and align contingency plans for the Homefront. SportSG has since updated the Heat Stress Management Plan for reference and use by the sports fraternity.

Due to climate change, Malaysia is projected to experience 200 heat wave days per year by 2050 and a significant increase in floods and storms. This will impact the health and well-being of the population from heat-stress related illness, injury from floods and storms, impact mental health due to loss of property and life, increase allergies due to weather changes, increase vector and water-borne diseases and cause potential malnutrition due to food insecurity. 

Climate change is causing an increase in the frequency and magnitude of extreme weather events such as heatwaves, floods, and droughts. Extreme weather events lead to loss of human life and have devastating consequences on socio-economic outcomes. In India, most vulnerable communities do not have access to either information about the occurrence of these events, or the understanding of risk from current warnings. This lack of useful information inhibits pre-emptive and potentially life saving action.

Many laborers are confronted with occupational heat stress from physically demanding work in high environmental temperatures with inadequate protections. Heat stress has multiple well-established adverse health outcomes, including increased accidents, heart attacks, heat illness, stroke, and organ damage including kidney diseases. All are potentially fatal and associated with decreased productivity. Heat stress and its health effects harm workers, communities, employers, and health systems. Active intervention in a warming world is required. Chronic Kidney Disease of undetermined causes (CKDnT) is a fatal progressive loss of kidney function that has killed more than 40,000 people in Mesoamerica and Sri Lanka alone in the last 10 years. Treatment is out of reach for most ensuring an early death for those affected.

This case studies outlines Mahila Housing Trust’s scalable model of woman-led education programme on climate change and health-related risks in urban settlements. Their model uses communication methods to introduce the concept of climate change and build climate resilience among vulnerable communities in India.

As climate change continues to intensify, so will the adverse effects of extreme heat for LMIC communities living in climate hotspots in Africa, Asia, Latin America and Oceania. Identifying effective climate change adaptation interventions that can be implemented in these diverse communities will support people, organisations, and governments to make climate change adaptation investment decisions. Therefore, this project aims to address extreme heat effects using cool roofs as an efficient solution for lowering indoor temperatures without the need for expensive air conditioning or other energy-intensive coolers. Its benefits encompass passive operation, low-cost, and durability. Cool roofs can work to mitigate adverse health, environmental, and economic impacts by:

• Reflecting sunlight​ to reduce indoor temperatures​
• Improving occupant comfort and health
• Increasing occupant productivity ​
• ​Lowering energy use ​

Climate change scenarios for Rotterdam show multiple future challenges. With rising temperatures, heat stress due to the urban heat island effect is increasing. With rising sea levels, the influx of saltwater into the river delta around Rotterdam is increasing. Peak weather events will lead to challenges for water storage both in the city of Rotterdam and its surrounding areas close to the Rhine and Meuse rivers. Urban transformation and other adaptation measures to overcome these challenges might affect mosquito, rodent, and bird populations.

CHALLENGE

The health impacts of extreme heat are predictable and largely avoidable, provided that city authorities have access to timely and location-specific information. With the right data and tools, city authorities can identify local hot spots, optimize the allocation and management of cooling centres, ensure sufficient drinking water spots and cooling spaces and communicate the health-related risks of excessive heat. Citizens and visitors can plan their daily lives in the city safely knowing the risks, and can adapt their routines accordingly. The challenge then is to improve access to information so that city authorities can reduce heat-related illness and deaths.

APPROACH

EXTREMA Global148 is a portfolio of digital services based on open Earth observation data as well as climate and atmosphere models and local data, targeting cities and citizens with city-specific customizations. It was originally designed to lessen the impacts of heatwaves on public health, and to make cities more heat resilient. The core services of EXTREMA Global include a free, multilingual mobile app that uses data and services to provide the current heat risk at the location of the user and recommendations for health protection, including directions to the nearest cooling places and drinking water spots and public announcements from city authorities. The app supports multiple profiles, allowing users to check on family members in multiple locations. The city authorities access tools and alerts through a dashboard to help them manage their resources to reduce heat exposure. City authorities also have access to satellite-derived maps showing the distribution of surface temperature in order to identify hot spots and areas that need intervention, through for example, the planning, design and management of urban infrastructure. The smartphone app also has optional modules that allow for the integration of air quality data from Copernicus Atmospheric Monitoring Service (CAMS) and provision of relevant health instructions. EXTREMA Global services are already being used in the municipalities of Athens, Milan, Paris, Rotterdam, Greater London (UK), and in Chicago, Tampa and Newark in the USA.

RESULT

Athens (Greece) was the first city in which the concept was adopted in 2016. City authorities worked to design the app to meet the city requirements, and have since included the app in the #CoolAthens campaign. They have also included the add-on to provide air quality data at the location of the user, and use high-resolution temperature distribution maps to guide planning. The combination of air quality and heat risk proved to be very useful in July 2021 when Athens experienced a severe heatwave that lasted 10 days and saw temperatures reach about 44 °C, with very poor air quality due to nearby wildfires sparked by the heat. The EXTREMA app suggests “cool routes” where users can walk safely around the city, for example, between tourist attractions, a feature much needed for tourists. In July 2023, during a heatwave that lasted 14 days, app requests by Athenians and visitors reached 10 000 hits. Furthermore, the app contributed drastically to strengthening communication between the departments of the municipality to exchange know-how and data. In Milan, hundreds of drinking water spots are mapped in the app, making use of the digital infrastructure to also decrease the use of plastic bottles. Publicity and dissemination by the city authorities play a critical role in the use and impact of the app, with peak usage dates coinciding with days in which the city promoted the app in the local press. In 2022, the app received 6 324 requests for service from Milan. Milan is now using digital services to calculate the safest and coolest routes for bicycles.

In Athens, the EXTREMA app supports six languages to help tourists find their nearest cooling space and the coolest route to their destination.

PARTNERS National Observatory of Athens, Group on Earth Observations (GEO), Global Urban Observation and Information (GUOI) initiative, ARTi Analytics B.V., Copernicus Atmospheric Monitoring Service (CAMS), Bloomberg Associates

CHALLENGE

Extreme temperatures have serious and direct effects on public health. In the summer of 2013–2014 Argentina experienced record heatwaves and preventable deaths. This motivated additional studies of the impact of extreme heat on health, with the aim of developing a health impact-based warning system.

Two studies established the statistical relationship between the occurrence of extreme temperatures and the increase in mortality. The studies were carried out jointly by the Ministry of Health, the National Meteorological Service, the National University of Entre Ríos, the National University of La Matanza and the University of Buenos Aires.

Mortality was analysed by sex, age and cause of death, and results indicated that mortality increased significantly in both extreme hot and cold temperatures. The mortality risk during heatwaves increased in 13 of the 18 provinces analysed. For extreme cold temperatures, risk of death significantly increased in the week following a cold day in 10 of the 21 cities analysed, while cold waves were associated with an increased risk of death in the following two weeks in 10 cities. Based on the evidence of extreme temperature episodes in Argentina driving increased negative health outcomes, an early warning system (EWS) for extreme temperatures was deemed necessary to reduce preventable deaths.

APPROACH

The objective of the EWS for extreme temperatures is to enable the population, the health system and civil protection organizations to take the appropriate prevention, mitigation and response measures at each alert level. Development of the EWS occurred in several phases.

Firstly, an EWS for Heatwaves and Health was developed and tested in two cities.132 Subsequently, in 2017 and based on the results of a study,133 the alert thresholds were adapted.

Finally, in 2021, the EWS began to cover the entire national territory (sub-divided into 168 fixed regions) and was renamed the EWS for Extreme Heat Temperatures. In the same way, the EWS for Extreme Cold Temperatures was created. The system issues alerts at different levels (yellow, orange and red). The alert thresholds were established based on the 90th percentile for heat (and the 10th percentile for extreme cold) of each city.

RESULT

During the warm period from October 2021 to March 2022, 987 daily alerts were issued for extreme heat (615 yellow, 205 orange and 167 red). Likewise, during the EWS for Extreme Cold Temperatures test period, from 9 June to 20 September 2021, 239 daily alerts were issued for extreme cold (197 yellow, 37 orange and 5 red).

The alerts were communicated to health and civil protection agencies at the national level, as well as to the general population through different media. An evaluation of the effectiveness of the system is planned. Under this system the weather alerts are issued by the Argentinian National Meteorological Service, and the Ministry of Health issues recommendations for health care.

LIMITATIONS AND LESSONS LEARNED

The Early Warning System for Extreme Temperatures (SAT-TE in Spanish) has climatic thresholds for which the significant increase in mortality was evaluated epidemiologically. Two studies established the statistical relationship between the occurrence of extreme temperatures and the increase in mortality.

However, future studies could evaluate the temperature at which mortality increases significantly, both for extreme cold and extreme heat. The main actions carried out are preventive, with little development of those aimed at mitigation and response. There is still a long way to go to complete the system, including improving the criteria for issuing alerts so that they contemplate different scenarios, such as power cuts or water shortages, among others.

During the warm period from October 2021 to March 2022, 987 daily alerts were issued for extreme heat.

PARTNERS: Ministry of Health of Argentina

Global warming is expected to exacerbate heat-related illness, especially in Africa. This not only has an impact on an individual’s health, but also their ability to work, and therefore reduces the economic productivity at a community level. Simple modifications to doors, windows and eaves in a home could help to alleviate these effects. Dr Abong’o will lead a team investigating the effectiveness of simple housing modifications, assessing their impact on cooling internal temperatures as well as their ability to lower the incidence of malaria by preventing indoor entry of mosquitoes.

In Southeast Asia, annual heat-related mortality is projected to increase by 295% by 2030 if there is no adaptation. To strengthen heat adaptation in Malaysia, Professor Tin Tin Su and her team will evaluate simple behavioural and structural interventions that have the potential to protect vulnerable communities from the health effects of extreme heat. They will introduce interventions that will improve heat health literacy and fluency for individuals and communities and test a passive cooling technology to decrease indoor exposure to extreme heat.

South Asia is one of the regions most affected by increasing global temperatures and extreme heat events, but more evidence is needed to determine the most appropriate strategies for heat adaptation and harm reduction. Through community participation and pilot testing, this study will assess a possible package of heat-health interventions in representative urban and rural settings in Pakistan. Professor Bhutta and the team will also review global evidence of community-based heat adaptation strategies and use this to evaluate and implement a locally appropriate heat adaptation and reduction plan.

Rural communities in low- and middle-income countries are particularly vulnerable to heat-related illnesses. Heat action plans that aide the public in understanding and evaluating their own risks and take the appropriate steps for prevention and preparedness have shown consistently positive results. Working in six rural communities in southern Mexico, Dr Riojas and the team will co-develop, test and evaluate a user-driven heat-health action plan, including an early warning and surveillance system, capacity building, prevention education and communication tools.

The negative impacts of heat exposure on maternal and child health outcomes are well documented, but there is little evidence to help us understand how best to reduce the risk of extreme heat on pregnant women. Professor Chersich will lead this study investigating a range of potential protective mechanisms, covering behavioural, built environment and environmental innovations. The team will work across six maternity facilities and the surrounding communities of urban areas in South Africa and semi-rural parts of Zimbabwe.

Despite a high vulnerability to heat-related health risks, interventions which investigate and implement heat adaptions are lacking in sub-Saharan Africa. Professors New and Dugas, and their collaborators, hope to address this evidence gap by evaluating physical and behavioural adaptations among manual labourers and low-income house dwellers in four study sites across Ghana and South Africa. The study will also develop and test heat warning systems to support these adaptations and gather high-quality data on physiological and mental health, as well as key climate, environmental and socio-economic variables.

Low- and middle-income countries are severely affected by climate change, but evidence for guiding uptake of suitable interventions is currently limited. Dr Tukuitonga and Dr Bunker will lead a global multi-centre trial in Burkina Faso, India, Niue and Mexico to assess the effects of affordable, sunlight-reflecting cool-roof coatings — an effective home cooling intervention — on health, environmental and economic outcomes for vulnerable populations. The findings will inform global adaptation and policy responses to increasing heat exposure from climate change.

Tree restoration plays an important role in climate change mitigation and adaptation. However, we don’t yet have evidence of the human health benefits of this restoration or the impact it has on reducing heat stress. Dr Chiwanga will lead this comprehensive study to evaluate how trees can be used to alter microclimates and protect Tanzania’s millions of outdoor agricultural workers from the long-term health risks of heat exposure. The research will build on land restoration work in central Tanzania which has championed local farmers to regenerate nine million native trees in three years.

Mitigating climate change is vital, but inevitable rising temperatures means that identifying sustainable cooling strategies is also important. Strategies at the individual scale that focus on cooling the person instead of the surrounding air can be effectively adopted, even in low-resource settings.

This report presents the evidence behind “Fan-First” cooling as a low-carbon approach to improving heat resilience.

The sub-plan aligns with the Bureau of Meteorology’s National Heatwave Warning Framework, ensuring a consistent approach to heat health and heatwave warnings across Australia. It highlights heatwave impacts on sectors like water, energy, infrastructure, and agriculture. The plan provides guidance to health and cross-sector stakeholders and applies to all areas of Queensland Health, including the Department and Hospital and Health Services (HHSs). Local agencies and disaster management groups may develop tailored heatwave management plans to address specific risks and needs.

Climate change has a negative impact on the health of every society, including the Peruvian population. The effects of climate change, such as increased temperature or extreme weather events, are the cause of diseases, for example, air pollution (from forest fires), or water pollution (from floods). Likewise, these effects can lead to direct injuries from extreme events or chronic malnutrition by reducing agricultural production. Which can even increase vector-borne infections, such as dengue fever. In addition, the loss of infrastructure in health services, political instability and poor climate governance amplify these risks and significantly threaten the health and well-being of the Peruvian population.

High school athletic associations (HSAAs) bear the responsibility of ensuring the health and safety of student-athletes. Exertional heat illness poses a significant risk, making this a task of increasing urgency in light of climate change and rising temperatures.

This policy brief, from Duke University’s Heat Policy Innovation Hub, builds on prior research to offer recommendations to HSAAs as part of an ongoing commitment to safeguard student-athletes from heat-related illnesses:

1. Implement environmental heat monitoring using a scientific device for onsite measurement of a heat stress index appropriate for the local climate, with staff training to ensure measurement precision.
2. Develop activity modification guidelines contingent on heat stress levels.
3. Incorporate specific heat action protocols into existing venue-specific emergency action plans.
4. Institute universal application of heat policies across all sports and activities.
5. Support full implementation by pursuing funding opportunities for measurement equipment and establishing incentives for compliance among member schools.

This policy brief discusses cost of extreme heat for outdoor workers/employers in low-and middle-income countries and provides cost-effective protection measures. It calls for workplace interventions and regulation to improve productivity and health.

This online application calculates daily mortality due to heat in Spain, using methodology is based on the March 2023 paper Heat-attributable Mortality in the Summer of 2022 in Spain The application uses the daily mortality data for Spain from the All-cause Daily Mortality Monitoring System (MoMo) and the average summer temperature (June, July and August) in Spain calculated from the reference stations defined by the Spanish State Meteorological Agency (AEMET).

Extreme heat events directly impact worker health and cause additional cascading and transitional workplace impacts. However, current investigations on these impacts often rely on specific datasets (e.g., compensation claims, hospitalizations). Thus, to continue to work towards preventing and mitigating the occupational risks posed by extreme heat events, this study aimed to explore the occupational impacts of the 2021 Heat Dome in Canada using a qualitative content analysis method on a news-based dataset. A systematized review of news articles published before, during, and after the 2021 Heat Dome was conducted on academic (n = 8) and news (n = 5) databases, along with targeted grey literature. Two researchers qualitatively coded the articles in NVivo for occupational impacts or references mentioned within the articles. Overall, 52 different occupations were identified as being impacted by the 2021 Heat Dome. Impacts were diverse and ranged from work cancellations or delays to work modifications and reports of heat-related illnesses. The 2021 Heat Dome impacted the health and safety of many occupational groups and provided new insights into the expanding impacts that extreme heat events can have on the Canadian workforce. With climate projections showing a growing trend of more hot days and intense heat waves in Canada, addressing these concerns should be a critical priority.

Extreme heat events directly impact worker health and cause additional cascading and transitional workplace impacts. However, current investigations on these impacts often rely on specific datasets (e.g., compensation claims, hospitalizations). Thus, to continue to work towards preventing and mitigating the occupational risks posed by extreme heat events, this study aimed to explore the occupational impacts of the 2021 Heat Dome in Canada using a qualitative content analysis method on a news-based dataset. A systematized review of news articles published before, during, and after the 2021 Heat Dome was conducted on academic (n = 8) and news (n = 5) databases, along with targeted grey literature. Two researchers qualitatively coded the articles in NVivo for occupational impacts or references mentioned within the articles. Overall, 52 different occupations were identified as being impacted by the 2021 Heat Dome. Impacts were diverse and ranged from work cancellations or delays to work modifications and reports of heat-related illnesses. The 2021 Heat Dome impacted the health and safety of many occupational groups and provided new insights into the expanding impacts that extreme heat events can have on the Canadian workforce. With climate projections showing a growing trend of more hot days and intense heat waves in Canada, addressing these concerns should be a critical priority.

The resources listed on this page are intended to help environmental public health professionals improve their understanding of infrastructural and behavioural risk factors that contribute to indoor overheating in Canada, and the strategies that can mitigate these risks.  Policy considerations to protect against indoor overheating are also outlined.

This web tool allows users to select their city or Zip code and an activity such as cycling, walking or distance running to determine the level of risk over the course of the day.

The combination of climate change and the urban heat island (UHI) effect is increasing the number of dangerously hot days and the need for all communities to plan for urban heat resilience equitably. Urban heat resilience requires an integrated planning approach that coordinates strategies across community plans and uses the best available heat risk information to prioritize heat mitigation strategies for the most vulnerable communities. The Plan Integration for Resilience Scorecard™ (PIRS™) for Heat is an approach that communities can use to analyze how heat mitigation policies are integrated into different plans and to identify opportunities to better target heat mitigation policies in high heat risk areas.

The PIRS™ for Heat was developed as an extension of the original Plan Integration for Resilience Scorecard™, a methodology, originally developed by Berke et al. (2015) and then further advanced and translated to planning practice by Malecha et al. (2019), for spatially evaluating networks of plans to reduce vulnerability to hazards. With support from the U.S. National Oceanic and Atmospheric Administration (NOAA) Climate Program Office’s Climate Adaptation Partnerships and Extreme Heat Risk Initiative and in partnership with the American Planning Association, PIRS™ for Heat was piloted in five geographically diverse U.S. communities, including Baltimore, MD, Boston, MA, Fort Lauderdale, FL, Seattle, WA, and Houston, TX.

This guidebook explains the rationale for the PIRS™ for Heat, provides a step-by-step guide for any practitioner or researcher interested in applying the methodology, includes a detailed and ready-to-go worksheet, and summarizes key plan integration findings from five communities across the U.S. There is also an accompanying individual case study report with the PIRS™ for Heat results for Kent, WA.

This guidebook is available free to all. This project was supported by financial assistance provided by the National Oceanic and Atmospheric Administration’s Climate Adaptation Partnerships and Extreme Heat Risk Initiative.

The ready-made garment industry is critical to the Bangladesh economy. There is an urgent need to improve current working conditions and build capacity for heat mitigation as conditions worsen due to climate change. We modelled a typical, mid-sized, non-air-conditioned factory in Bangladesh and simulated how the indoor thermal environment is altered by four rooftop retrofits (1. extensive green roof, 2. rooftop shading, 3. white cool roof, 4. insulated white cool roof) on present-day and future decades under different climate scenarios. Simulations showed that all strategies reduce indoor air temperatures by around 2 °C on average and reduce the number of present-day annual work-hours during which wet-bulb globe temperature exceeds the standardised limits for moderate work rates by up to 603 h – the equivalent of 75 (8 h) working days per year. By 2050 under a high-emissions scenario, indoor conditions with a rooftop intervention are comparable to present-day conditions. To reduce the growing need for carbon-intensive air-conditioning, sustainable heat mitigation strategies need to be incorporated into a wider range of solutions at the individual, building, and urban level. The results presented here have implications for factory planning and retrofit design, and may inform policies targeting worker health, well-being, and productivity.

Schools are hubs for their surrounding community, connecting parents, teachers, children, and families. Hence, the heat conditions at schools, as well as their preparedness and policies for managing extreme heat, impact multiple aspects of the community. However, minimal attention has been paid to formalizing school heat preparedness, ensuring their ability to mitigate the effects of high temperatures on the health and education of students. Since commencing in 2017, this project has sought to improve the safety and protection measures for children exposed to extreme heat during the school day by understanding the important factors for becoming a HeatReady School. We define HeatReady Schools as those that are increasingly able to identify, prepare for, mitigate, track, and respond to the negative impacts of schoolground heat (Shortridge et al., 2021). Through this research, we have improved our understanding of how people perceive and react to heat emergencies, as well as what actions are taken at the school level to mitigate their effects. Based on interviews with key stakeholders, we have gauged the effectiveness of existing heat preparedness actions at schools in the Phoenix area. Our thirty final recommendations based on five action areas (raining, prevention, school policy, community, and environment) are providing important “HeatReady” actions that can be applied or adapted for various school contexts and/or climate regions. To date, we have reached over 30 schools and community centers utilizing HeatReady Schools resources, a number that continues to grow. We have also created a HeatReady Schools growth tree and rubric, share numerous resources with our members, and have developed multiple training resources for schools to leverage (e.g., Bilingual K-12 Summer Emergency Preparedness course, HeatReady Teacher Training). These trainings also support work within HeatReady Neighborhoods, within which schools are a critical player for heat readiness.

Occupational heat stress is a crucial risk factor for a range of Heat-Related Illnesses (HRI). Outdoor workers in unorganized work sectors exposed to high ambient temperatures are at increased risk in developing countries. We aim to compare HRI, Productivity Loss (PL), and reduced renal health risk between workers from outdoor unorganized (N = 1053) and indoor organized (N = 1051) work sectors. Using descriptive methods and a large epidemiological cross-sectional study using mixed methods, we compared risk patterns between the two groups. We analyzed the risk of self-reported HRI symptoms, Heat Strain Indicators (HSIs), PL, and reduced kidney function using Multivariate Logistic Regression (MLR) models. Although Wet Bulb Globe Temperature (WBGT) exposures were high in both the outdoor and indoor sectors, significantly more Outdoor Unorganized Workers (OUWs) reported heat stress symptoms (45.2% vs 39.1%) among 2104 workers. OUWs had a significantly higher share of the heavy workload (86.7%) and long years of heat exposures (41.9%), the key drivers of HRIs, than the workers in indoor sectors. MLR models comparing the indoor vs outdoor workers showed significantly increased risk of HRI symptoms (Adjusted Odds Ratio) (AORoutdoor = 2.1; 95% C.I:1.60–2.77), HSI (AORoutdoor = 1.7; 95% C.I:1.00–2.93), PL (AORoutdoor = 11.4; 95% C.I:7.39–17.6), and reduced kidney function (Crude Odds Ratio) (CORoutdoor = 1.4; 95% C.I:1.10–1.84) for the OUWs. Among the heat-exposed workers, OUW had a higher risk of HRI, HSI, and PL even after adjusting for potential confounders. The risk of reduced kidney function was significantly higher among OUWs, particularly for those with heat exposures and heavy workload (AORoutdoor = 1.5; 95% C.I: 0.96–2.44, p = 0.073) compared to the indoor workers. Further, in-depth studies, protective policies, feasible interventions, adaptive strategies, and proactive mitigation efforts are urgently needed to avert health and productivity risks for a few million vulnerable workers in developing nations as climate change proceeds.

A project developing low-cost options for reducing heat stress in urban contexts.

This project brings together an expert, interdisciplinary team to investigate the impacts of flooding and extreme heat on urban infrastructure and the resultant consequences for the livelihoods of poor urban residents in Ghana.

Many cities in the global South are increasingly experiencing extreme weather events, which are having devastating impacts on infrastructure and human lives. The main aims of “Vulnerability to Extreme Weather Events in Cities: Implications for Infrastructure and Livelihoods” (VEWEC) are to:

• Refine methods for mapping ‘hotspots’ of vulnerability and predicting flooding and extreme heat in cities by drawing on existing climate data
• Examine the impact of flooding and extreme heat on water, electricity and health services
• Analyse the impact of reduced service levels during extreme weather events on the income-generating activities of the urban poor
• Co-produce adaptive strategies to extreme weather events with residents, service providers and policymakers

The cities of Accra and Tamale, with their differing climates, urban form and size, infrastructure and governance systems, provide contrasting cases within one national context. This project focuses on four areas within each city that have been selected as representative of neighbourhoods suffering from either flooding and/or extreme temperatures. For Accra these are Odawna, Bortianor, Agbogbloshie and Alajo. For Tamale they are Gumani, Sakasaka, Kukuo and Lamashegu.

Put simply, key questions being asked include:

• Where, when and how are climate hazards impacting Accra and Tamale?
• What actions are already being taken by communities and service providers to adapt to flooding and extreme temperatures?
• What further action could be taken?

The views and experiences of key stakeholders and residents of the study communities are being sought using qualitative methods, including in-depth interviews and focus group discussions. Household-level temperature data will be collected using tiny-tag sensors located within and outside houses and businesses.

This collaborative research is being conducted by climate scientists, human geographers, health specialists and infrastructure engineers based at Loughborough University, the University of Ghana, and the University for Development Studies (Tamale).

Background: Extreme heat may discourage physical activity of children while shade may provide thermal comfort. The authors determined the associations between ambient temperature, shade, and moderate to vigorous physical activity (MVPA) of children during school recess. Methods: Children aged 8–10 (n = 213) wore accelerometers and global positioning system monitors during recess at 3 school parks in Austin, Texas (September–November 2019). Weather data originated from 10 sensors per park. The authors calculated shade from imagery using a geographic information system (GIS) and time-matched physical activity, location, temperature, and shade data. The authors specified piecewise multilevel regression to assess relations between average temperature and percentage of recess time in MVPA and shade. Results: Temperature ranged 11 °C to 35 °C. Each 1 °C higher temperature was associated with a 0.7 percentage point lower time spent in MVPA, until 33 °C (91 °F) when the association changed to a 1.5 lower time (P < .01). Each 1 °C higher temperature was associated with a 0.3 percentage point higher time spent under shade, until 33 °C when the association changed to a 3.4 higher time (P < .001). At 33 °C or above, the direct association between shade and MVPA weakened (P < .05), with no interaction effect above 33 °C (P > .05). Children at the park with the most tree canopy spent 6.0 percentage points more time in MVPA (P < .01). Conclusions: Children engage in less MVPA and seek shade during extreme heat and engage in more MVPA in green schoolyards. With climate change, schools should consider interventions (eg, organizing shaded play, tree planting) to promote heat safe MVPA.

Temperature extremes vary across Africa. A continent-wide examination of the impacts of heat on health in Africa, and a synthesis of Africa-informed evidence is, however, lacking. A systematic review of articles published in peer-reviewed journals between January 1992 and April 2019 was conducted. To be eligible, articles had to be Africa-specific, in English, and focused on how heatwaves and high ambient temperatures affect morbidity and mortality. A secondary systematic analysis on policies and interventions comprising 17 studies was also conducted, and the findings synthesised together with those of the 20 primary studies. Eleven studies showed that high ambient temperatures and heat waves are linked with increased mortality rates in Africa. These linkages are characterised by complex, linear and non-linear (J or U) relationships. Eight of the nine primary studies of morbidity outcome reported that an increase in temperature was accompanied by raised disease incidence. Children and the elderly were the population groups most vulnerable to extreme heat exposure. Location-specific interventions and policy suggestions include developing early warning systems, creating heat-health plans, changing housing conditions and implementing heat-health awareness campaigns. In summary, this review demonstrates that, while heat-health relationships in Africa are complex, extreme temperatures are associated with high mortality and morbidity, especially amongst vulnerable populations. As temperatures increase across Africa, there is an urgent need to develop heat-health plans and implement interventions. Future studies must document intervention effectiveness and quantify the costs of action and inaction on extreme heatrelated mortality and morbidity.

 Significance:

• Empirical evidence shows that the relationship between heat and human health is complex in the African This complexity has implications for the development of interventions and policies for heathealth on the continent.
• This review is important for African policymakers, practitioners and others who support Africa’s adaptation to climate change. Through this review, a compendium of Africa-specific and relevant empirical information is aggregated and made readily available to various interested and affected parties.

Climate change is one of the biggest health threats facing humanity and can directly affect human health through heat waves. This study aims to evaluate excess deaths during heat waves between the summer months of 2004 and 2017 in Istanbul and to determine a definition of heat waves that can be used in the development of an early warning system, a part of prospective urban heat-health action plans. In this study, heat waves were determined using the Excess Heat Factor, an index based on a three-day-averaged daily mean temperature. The death rates during heat waves and non-heat wave days of the summer months were compared with a Z test of the difference of natural logarithms. Thirty heat waves were recorded in Istanbul during the summer months of 2004–2017. In 67% of the heat waves, the death rate was significantly higher than the reference period and 4281 excess deaths were recorded. The mortality risk was especially higher during heat waves of higher intensity. The study showed an excess risk of mortality during heat waves in Istanbul, and the findings suggest that the Excess Heat Factor could be an appropriate tool for an early warning system in Istanbul.

The growing frequency, intensity, and duration of extreme heat events necessitates interventions to reduce heat exposures. Local opportunities for heat adaptation may be optimally identified through collection of both quantitative exposure metrics and qualitative data on perceptions of heat. In this study, we used mixed methods to characterize heat exposure among urban residents in the area of Boston, Massachusetts, US, in summer 2020. Repeated interviews of N = 24 study participants ascertained heat vulnerability and adaptation strategies. Participants also used low-cost sensors to collect temperature, location, sleep, and physical activity data. We saw significant differences across temperature metrics: median personal temperature exposures were 3.9 °C higher than median ambient weather station temperatures. Existing air conditioning (AC) units did not adequately control indoor temperatures to desired thermostat levels: even with AC use, indoor maximum temperatures increased by 0.24 °C per °C of maximum outdoor temperature. Sleep duration was not associated with indoor or outdoor temperature. On warmer days, we observed a range of changes in time-at-home, expected given our small study size. Interview results further indicated opportunities for heat adaptation interventions including AC upgrades, hydration education campaigns, and amelioration of energy costs during high heat periods. Our mixed methods design informs heat adaptation interventions tailored to the challenges faced by residents in the study area. The strength of our community-academic partnership was a large part of the success of the mixed methods approach.

Summer heatwaves repeatedly affect extended regions in Europe, resulting in adverse economic, social, and ecological impacts. Recent events, e.g., the 2022 heatwave, also attract interest regarding the spatial shifts of their impact centers. Evaluations so far either investigated heatwave passage at pre-defined locations or employed algorithms to spatio-temporally track their core regions. Usually, the latter focus on single events, and thus often fail to generalize spatial heatwave tracks or ignore track characteristics. Here, we use a data-driven approach employing causal discovery to robustly characterize European heatwave tracks in single-model initial condition large ensemble (SMILE) climate simulations to overcome sampling uncertainties of observational records. This enables us to identify specific recurrent heatwave tracks, evaluate their preferential seasonal occurrence, and associate them with atmospheric pressure center shifts. Additionally, the evaluation of heatwave track representation in the SMILE extends standard model evaluation, which is mostly based on static statistics. We provide the first comprehensive analysis on heatwave tracks considering internal climate variability conducted within a SMILE, promoting the latter as a methodological testbed in climate extremes research.

Epidemiological studies have reported the association between extreme temperatures and adverse reproductive effects. However, the susceptible period of exposure during pregnancy remains unclear. This study aimed to assess the impact of extreme temperature on the stillbirth rate. We performed a time-series analysis to explore the associations between temperature and stillbirth with a distributed lag nonlinear model. A total of 22,769 stillbirths in Taiwan between 2009 and 2018 were enrolled. The mean stillbirth rate was 11.3 ± 1.4 per 1000 births. The relative risk of stillbirth due to exposure to extreme heat temperature (> 29 °C) was 1.18 (95% CI 1.11, 1.25). Pregnant women in the third trimester were most susceptible to the effects of extreme cold and heat temperatures. At lag of 0–3 months, the cumulative relative risk (CRR) of stillbirth for exposure to extreme heat temperature (29.8 °C, 97.5th percentile of temperature) relative to the optimal temperature (21 °C) was 2.49 (95% CI: 1.24, 5.03), and the CRR of stillbirth for exposure to extreme low temperature (16.5 °C, 1st percentile) was 1.29 (95% CI: 0.93, 1.80). The stillbirth rate in Taiwan is on the rise. Our findings inform public health interventions to manage the health impacts of climate change.

The urban heat island (UHI) effect exacerbates the adverse impact of heat on human health. However, while the UHI effect is further intensified during extreme heat events, prior studies have rarely mapped the UHI effect during extreme heat events to assess its direct temperature impact on mortality. This study examined the UHI effect during extreme heat and non-extreme heat scenarios and compared their temperature-mortality associations in Hong Kong from 2010 to 2019. Four urban heat island degree hour (UHIdh) scenarios were mapped onto Hong Kong’s tertiary planning units and classified into three levels (Low, Moderate, and High). We assessed the association between temperature and non-external mortality of populations living in each UHIdh level for the extreme heat/non-extreme heat scenarios during the 2010–2019 hot seasons. Our results showed substantial differences between the temperature-mortality associations in the three levels under the UHIdh extreme heat scenario (UHIdh_EH). While there was no evidence of increased mortality in Low UHIdh_EH areas, the mortality risk in Moderate and High UHIdh_EH areas were significantly increased during periods of hot temperature, with the High UHIdh_EH areas displaying almost double the risk (RR: 1.08, 95%CI: 1.03, 1.14 vs. RR: 1.05, 95 % CI: 1.01, 1.09). However, other non-extreme heat UHI scenarios did not demonstrate as prominent of a difference. When stratified by age, the heat effects were found in Moderate and High UHIdh_EH among the elderly aged 75 and above. Our study found a difference in the temperature-mortality associations based on UHI intensity and potential heat vulnerability of populations during extreme heat events. Preventive measures should be taken to mitigate heat especially in urban areas with high UHI intensity during extreme heat events, with particular attention and support for those prone to heat vulnerability, such as the elderly and poorer populations.

This NRDC factsheet summarizes key findings from a study on energy savings from cool roofs in India.

This report draws on knowledge developed for the European Climate and Health Observatory. It focuses on the impact high temperatures are having on the population, as well as another emerging threat: the spread of climate-sensitive infectious diseases.

The Laboratory of Urban and Environmental Systems (URBES) at EPFL is looking for a postdoctoral researcher in the area of urban climate, risk and health.
Deadline: until filled

The California Department of Public Health interim health guidance provides additional or supplemental information and guidance; if a school or local jurisdiction has an existing heat emergency plan, consult with the existing plan first.

South Korea’s population is declining and its composition changing, associated with lowest-low fertility rates and rapid aging (super aging). When estimating changes in future exposure to extreme heat events (EHE), events that are predicted to be intensified due to climate change, it is important to incorporate demographic dynamics. We analyze business-as-usual (BAU) population and climate scenarios—where BAU refers to no significant change in current processes and trends in either domain—from 2010 to 2060 for South Korea. Data for both BAU scenarios are spatially linked and used to measure and identify national and sub-national and age-group specific EHE exposure. The results reveal an increasing exposure to EHE over time at the national level, but this varies widely within the country, measured at the municipal level. The most intensive exposure levels will be in the decade ending in 2040 driven by high estimated severe EHE. Sub-nationally, Seoul will be the most vulnerable municipality associated with super aging, while severe EHE not demographic factors will be relevant in Daegu, the second-most vulnerable metropolitan area. By 2060, national estimates suggest the older population will be up to four times more exposed to EHE than today. While the population of South Korea will decline, the rapid aging of the population ensures that specific regions of the country will become exceedingly vulnerable to EHE.

More frequent and intense heatwaves in the last decade have challenged humanitarian, health and meteorological authorities to mitigate impact. Meteorological heatwave monitoring and prediction services vary between heatwave definitions which either include humidity or are based only on temperature. Incorporation of humidity into human health heatwave studies and warning services has been variable. Whilst higher humidity is a known stressor during heatwaves, humidity is known to confound interpretation of heatwave data and can be difficult to monitor and forecast.

This study examines the effect of humidity on diagnosed heatwave severity across Australia’s diverse climate zones. Dry bulb temperature is used as the only input into the Bureau of Meteorology’s current operational Excess Heat Factor (EHF) index. Alternative humidity-affected temperature indices (Apparent Temperature, Wet Bulb Globe Temperature and Heat Index) are examined for suitability as input to EHF to compare the incidence of dry and humidity-affected heatwave severity within Australia. This paper uses maximum and minimum dry and humidity affected temperature indices extracted from Australia’s Bureau of Meteorology Atmospheric high-resolution Regional Reanalysis for Australia (BARRA).

Our investigation demonstrates Australia’s operational temperature-only percentile-based heatwave severity service provides effective heatwave warning guidance for five of Australia’s six diverse climate zones. However, rare very dry or very humid heatwaves in the tropics require both dry bulb temperature-only and Heat Index versions of Excess Heat Factor (EHF) severity index to provide competent operational heatwave early warning guidance.

Anatomical, physiologic, and socio-cultural changes during pregnancy and childbirth increase vulnerability of women and newborns to high ambient temperatures. Extreme heat can overwhelm thermoregulatory mechanisms in pregnant women, especially during labor, cause dehydration and endocrine dysfunction, and compromise placental function. Clinical sequelae include hypertensive disorders, gestational diabetes, preterm birth, and stillbirth. High ambient temperatures increase rates of infections, and affect health worker performance and healthcare seeking. Rising temperatures with climate change and limited resources heighten concerns. We propose an adaptation framework containing four prongs. First, behavioral changes such as reducing workloads during pregnancy and using low-cost water sprays. Second, health system interventions encompassing Early Warning Systems centered around existing community-based outreach; heat-health indicator tracking; water supplementation and monitoring for heat-related conditions during labor. Building modifications, passive and active cooling systems, and nature-based solutions can reduce temperatures in facilities. Lastly, structural interventions and climate financing are critical. The overall package of interventions, ideally selected following cost-effectiveness and thermal modeling trade-offs, needs to be co-designed and co-delivered with affected communities, and take advantage of existing maternal and child health platforms. Robust-applied research will set the stage for programs across Africa that target pregnant women. Adequate research and climate financing are now urgent.

In response to the recognized high risks and potential impacts of extreme heat in South Asia, the 1st South Asia Climate Services Forum for Health focused on heat health and brought together over 25 experts in public health, climate and meteorology to discuss the needs and opportunities for multi-sectoral collaboration to better understand and address these health risks in the region.

This meeting contributes a regional perspective to a global discussion on the state of the science and practice in heat health action. Under the leadership of the US-NOAA and German Deutscher Wetterdienst (DWD), a global coalition of meteorological experts and health practitioners came together in Chicago in July 2015 to consider three issues. First, to identify knowledge gaps in our understanding of heat exposure and health outcomes across different timescales and geographies; along with the observations, monitoring, data, and forecast product needs. Secondly, to synthesize existing heat health forecasting systems being used around the world and to consider if their prediction parameters correspond to health sector requirements for preparedness. Thirdly, to identify specific partnerships, dialogues or processes needed to improve existing heat health early warning systems and develop heat related climate services for the public health sector to improve community resilience. The need for support and action in South Asia was highlighted at this meeting, and the CSFHealth dialogue and recommendations will feed back into the global effort to increase capacity and action in this region.

Myanmar’s climate is changing and climate variability already affects communities and socioeconomic sectors in the country. Some climate change impacts are already observable and there is broad scientific consensus that further change will occur. Even with significant global climate mitigation (activities and technologies that reduce greenhouse gas emissions), economic sectors, local communities and natural ecosystems in Myanmar will be strongly affected by climate change as a result of the emissions already in the atmosphere. Adaptation is therefore necessary for reducing Myanmar‟s vulnerability to climate variability and change.

National Adaptation Programmes of Action (NAPAs) serve as simplified, rapid and direct channels for Least Developed Countries to identify and communicate priority activities to address their urgent and immediate adaptation needs. NAPAs emerged from the multilateral discussions on adaptation measures within the UN Framework Convention on Climate Change (UNFCCC)1,2.

Myanmar;s NAPA therefore specifies 32 priority activities (referred to as Priority Adaptation Projects) for effective climate change adaptation for eight main sectors/themes (i.e. four Project Options per sector/theme), namely: i) Agriculture; ii) Early Warning Systems; iii) Forest; iv) Public Health; v) Water Resources; vi) Coastal Zone; vii) Energy, and Industry; and viii) Biodiversity(Table 1).

Mumbai city, home to over 12 million people and thriving on a diverse economy, is increasingly at risk of the impacts of climate change. Increasing temperatures, depleting natural green cover, routine bouts of extreme rainfall events resulting in severe flood conditions incur severe losses to the city’s economy and its people. Recent increase in tropical cyclones along the coast and future risks from sea level rise projected over the next 3 decades pose critical challenges to Mumbai’s future. In this context, the Brihanmumbai Municipal Corporation have led the process to drafting the first ever, Mumbai Climate Action Plan ( MCAP).

The MCAP envisions a city where its communities and citizens are safer, healthier, and thrive even in the context of a changing and uncertain climate. The MCAP is committed to a net zero and climate-resilient Mumbai by 2050. This means ensuring just transitions – towards net zero pathways; big investments – towards inclusive and transformative climate solutions; and coordinated and robust governance – to ensure a targets-based approach. BMC acknowledges that the climate crisis is already affecting us all, although in varying ways, and the time for action is now to secure a better future for all by 2050.

Heatwaves in Canada are becoming more intense and lasting for longer periods. Heat waves can pose a serious risk to the wellbeing of many Canadians. Developing robust localized heat health warning systems are important to prevent heat-related illnesses, provide heat-relief programs, guide policy and municipal planning, and may help to prevent deaths from extreme heat.

This study will use thermostats to collect indoor temperature to see if indoor temperatures are higher than outdoor temperatures. The study will take place from May 1, 2022 to September 30, 2022.

Extreme heat events affect different people in different ways, and some people are at higher risk of experiencing heat-related illness if they do not have air conditioning. One way to reduce the public health impacts of extreme heat events is to check in regularly with susceptible people to see how they are coping. However, not everyone knows who is at most risk, how to recognize heat-related illness, or what to do in risky situations. This tool from the NCCEH was designed to help support people doing heat checks by providing all they key information and guidance in a 5-page package. This tool has been co-developed with Dr. Glen Kenny and his heat stress research group at the University of Ottawa.

Available in 22 scheduled languages of India, the comic book narrates the story of three children returning home after school during a heatwave.

Climate change is likely to have wide-ranging impacts on maternal and neonatal health in Africa. Populations in low-resource settings already experience adverse impacts from weather extremes, a high burden of disease from environmental exposures, and limited access to high-quality clinical care. Climate change is already increasing local temperatures. Neonates are at high risk of heat stress and dehydration due to their unique metabolism, physiology, growth, and developmental characteristics. Infants in low-income settings may have little protection against extreme heat due to housing design and limited access to affordable space cooling. Climate change may increase risks to neonatal health from weather disasters, decreasing food security, and facilitating infectious disease transmission. Effective interventions to reduce risks from the heat include health education on heat risks for mothers, caregivers, and clinicians; nature-based solutions to reduce urban heat islands; space cooling in health facilities; and equitable improvements in housing quality and food systems. Reductions in greenhouse gas emissions are essential to reduce the long-term impacts of climate change that will further undermine global health strategies to reduce neonatal mortality.

Forty years (1980–2019) of reanalysis data were used to investigate climatology and trends of heat stress in the Caribbean region. Represented via the Universal Thermal Climate Index (UTCI), a multivariate thermophysiological-relevant parameter, the highest heat stress is found to be most frequent and geographically widespread during the rainy season (August, September, and October). UTCI trends indicate an increase of more than 0.2°C·decade⁻¹, with southern Florida and the Lesser Antilles witnessing the greatest upward rates (0.45°C·decade⁻¹). Correlations with climate variables known to induce heat stress reveal that the increase in heat stress is driven by increases in air temperature and radiation, and decreases in wind speed. Conditions of heat danger, as depicted by the heat index (HI), have intensified since 1980 (+1.2°C) and are found to occur simultaneously to conditions of heat stress suggesting a synergy between heat illnesses and physiological responses to heat. This work also includes the analysis of the record-breaking 2020 heat season during which the UTCI and HI achieved above average values, indicating that local populations most likely experienced heat stress and danger higher than the ones they are used to. These findings confirm the gradual intensification of heat stress in the Caribbean and aim to provide a guidance for heat-related policies in the region.

Extreme weather alerting systems are one of the central tools utilised in adapting to changing weather patterns resulting from climate change. This paper evaluates the effectiveness of the current alerting systems for hot and cold weather used in England to notify the health and social care sector of upcoming extreme weather events. We consider the views of stakeholders on the current system and explore their perspectives on the proposal to move towards an impact-based system. The paper concludes that while the current system is an effective tool, stakeholders feel they need to draw on additional material to assist with the development of an appropriate response. We also highlight that many stakeholders are concerned about the potential for creating alert fatigue due to a lack of clarity of the geographical area impact of some of the alerts. Consequently, there was a high level of support from stakeholders for the move towards an impact-focused system.

Durante los meses de verano del año 2003 se produjeron temperaturas muy elevadas en toda
Europa que provocaron un importante aumento de la morbilidad y, como posteriormente se ha
comprobado, de la mortalidad por causas en las que el factor de exceso de temperatura fue un
desencadenante. A fin de evitar episodios como los ocurridos durante ese verano, en el año 2004
el Ministerio de Sanidad puso en marcha el Plan Nacional de Actuaciones Preventivas de los
Efectos de los Excesos de Temperaturas Sobre la Salud. Desde entonces, el Plan se activa cada
verano durante los meses de junio a septiembre.
La aplicación del Plan está cumpliendo su principal objetivo: la prevención de daños a la salud
provocados por el exceso de temperatura. Desde un enfoque sanitario, la exposición a
temperaturas excesivas afecta especialmente a los menores, a las personas mayores y a las
personas con patologías crónicas de base. Desde un punto de vista social, la marginación, el
aislamiento, la dependencia, la discapacidad, las condiciones de habitabilidad de las personas
con menos recursos, añaden factores de riesgo que hacen aún más vulnerables a colectivos que,
precisamente por sus condiciones socio-económicas, deberían estar más apoyados.
El Plan establece las medidas para reducir los efectos asociados a las temperaturas excesivas y
para coordinar las instituciones de la Administración del Estado implicadas. Así mismo propone
acciones que puedan ser realizadas por las Comunidades Autónomas y la Administración Local.
El Plan establece las acciones previstas para la prevención y control, estructuradas en varios
niveles de actuación según el nivel de riesgo alcanzado como consecuencia del incremento de las
temperaturas.

La Estrategia y el Programa contemplan ocho ejes estratégicos y 23 líneas de acción: 1) Movilidad integrada y sustentable, 2) Ciudad solar, 3) Basura cero, 4) Manejo sustentable del agua y rescate de ríos y cuerpos de agua, 5) Revegetación del campo y la ciudad, 6) Capacidad adaptativa y resiliencia urbana, 7) Calidad del aire, y 8) Cultura climática.

Este documento fornece subsídios para a elaboração do Plano de Adaptação da CRJ, peloqual de vem ser estabelecidos caminhos para a adaptação que tenham, por objetivo, assegurar a proteção do patrimônio natural e construído e preservar as relações econômicas e socioculturais face às mudanças do clima, em prol da atual e futuras gerações.

Estratégia de Adaptação está fundamentada em seis Eixos Estratégicos:
A. Fortalecer a capacidade institucional e humana;
B. Garantir a conservação e integridade dos ecossistemas e o uso racional e sustentável dos recursos naturais;
C. Fomentar a promoção da saúde da população
frente às mudanças climáticas;
D. Conduzir a ocupação e uso do território de forma a promover a qualidade urbano-ambiental;
E. Garantir a mobilidade urbana eficiente e
sustentável; e
F. Garantir o funcionamento das Infraestruturas
Estratégicas sob condições climáticas adversas.

Actions in the plan are organized into four tracks –

(A) Build Public Awareness and Notification;

(B) Strengthen Community Services and Response;

(C) Increase Resilience of Our Built Environment; and

(D) Utilize Nature-Based Solutions.

These tracks include established and recommended state actions to address extreme heat. The Administration is committed to continued scoping and exploration of these actions. Areas of near-term focus include:

• Implement a statewide public health monitoring system to identify heat illness events early, monitor trends, and track illnesses to intervene and prevent further harm.
• Accelerate readiness and protection of communities most impacted by extreme heat, including through cooling schools and homes, supporting
  community resilience centers, and expanding nature-based solutions.
• Protect vulnerable populations through codes, standards, and regulations.
• Expand economic opportunity and build a climate smart workforce that can operate under and address extreme heat.
• Increase public awareness to reduce risks posed by extreme heat.
• Protect natural and working lands, ecosystems, and biodiversity from the impacts of extreme heat.

This report aims to support the Rajshahi Metropolitan City and other emergency service providers in Rajshahi, such as the Disaster Management Department, the Rajshahi branch of Bangladesh Red Crescent Society (BDRCS), the unit responsible for determining the heat thresholds and hotspots indicating when and where to act before or during heatwave days. Moreover, the report intends to encourage city stakeholders to take fruitful actions in upcoming heat seasons to reduce the city’s heat risks and build stakeholder’s capacity on city heat actions.

Guide to extreme heat planning in South Africa for the human health sector: A package of practical, feasible, and low-cost interventions at the individual and community level can assist people to adapt to high temperatures. The health sector is the lead agency on the Heat Health Action Plan, responsible for coordinating across other departments and stakeholders, including those outside of government. The Heat Health Information Plan needs to deliver useful, timely, accessible, consistent and trustworthy information to their target audience, with a focus on vulnerable populations.

COSMA is a multidisciplinary study that will bring together a group of experts in urban meteorology, building environmental engineering, architecture, urban planning and social science, to work with local stakeholders to understand the overheating risk in the urban area of Colombo. This project is funded by NERC (Natural Environment Research Council) in the UK.

At the heart of the project are the studies of:

• how the heatwave overheating risk prediction and assessment could be improved at finer urban and building scales
• the useful indigenous design knowledge in Sri Lanka for heatwaves mitigtion, and
• how the designs could be regenerated and re-incorporated into the heatwave action plan and future design practice

COSMA aims to develop an integrated modelling approach by taking into account the urban heat island, building characteristics and vulnerable population to build effective early-warning systems and a city-scale heat action plan. The final outputs of the project will be a series of hierarchical overheating risk and mitigation potential maps across different scales for Colombo, Sri Lanka.

COSMA is a multidisciplinary study that will bring together a group of experts in urban meteorology, building environmental engineering, architecture, urban planning and social science, to work with local stakeholders to deliver SHEAR programme objectives. By working closely with the local community, government and professionals, one important goal of COSMA project is to harvest and regenerate traditional design knowledge (both building and urban scales) from indigenous craftsmen embedded within local culture and traditions, and feed into the heat-exposure risk mitigation plan.

COSMA, led by the University of Reading (UoR), involves collaborations with Glasgow Caledonian University (GCU), and carried out in partnership with a group of well-established Sri Lankan partners: the Department of Meteorology (DoM) and the Institute of Town Planners Sri Lanka(ITPSL) as well as researchers at University of Moratuwa (UoM).

This report aims to support the Nepalgunj Upamahannagar Palika (Sub-Metropolitan City) and other emergency service providers in Nepalgunj, such as the disaster management department and the Banke branch of Nepal Red Cross Society (NRCS), the unit responsible for determining the heat thresholds and heat hotspots, indicating when and where to act before or during heatwave days. Moreover, the report intends to encourage city stakeholders to take fruitful actions in the upcoming heat seasons
to reduce the city’s heat risks and build stakeholder’s capacity on city heat actions.

This policy brief was produced to share insights on how the Nepalgunj City in Nepal could improve its preparedness for extreme heat through existing and new policies and plans. It provides a summary of existing policy frameworks that may be used to address heat; highlights potential gaps and makes recommendations for how heat can be better integrated into policies and plans on both short-term (days to months) and long-term (5+ years) timescales. It is based on desk-based research and key stakeholder interviews with city, disaster management, and health officials in Nepalgunj City.

This review report details the available Heat Action Plans (HAPs) in South Asia, especially India. It is a qualitative review that identifies the key strategies introduced in the Heat Action Plans from the different states and cities within India. It also highlights the need for a Climate Adaptive HAP which can increase the impact and efficiency of the adaptation and mitigation efforts.

This report’s objective is to define and divulgate the knowledge about heat stress and health consequences in general for the Turkish population. The Environment, Climate and Health Cooperation Project (ÇİSİP in Turkish) was launched by the Health and Environment Alliance (HEAL), HASUDER (Association of Public Health Professionals-Turkey) and Kocaeli University Department of Public Health in April 2020. Funded by the European Union, CISIP’s aim is to bring together all environmental health actors in Turkey and to support health professionals in the fields of environmental and climate policies.

This document lays out an action plan for managing heatwaves in Khyber Pakhtunkhwa, Pakistan, which has been facing the brunt of climate change hazards because of its unique topography. Being home to extreme cold and hot weather, significant losses have been incurred which can be linked to climate-change-related disasters i.e. floods, glacial melting, drought, and heat waves.

The plan includes:

• situation analysis
• heat index
• background to heat waves in Khyber Pakhtunkhwa
• heatwave early warning & coordination
• heat wave declaration
• heat wave surveillance & coordination
• roles and responsibilities

Epidemiologic research on extreme heat consistently finds significant impacts on human morbidity and mortality. However, most of these analyses do not use spatially explicit measures of heat (typically assessing exposures at major cities using the nearest weather station), and they frequently consider only ambient temperature or heat index. The field is moving toward more expansive analyses that use spatially resolved gridded meteorological datasets and alternative assessments of heat, such as wet-bulb globe temperature (WBGT) and universal thermal climate index (UTCI), both of which require technical geoscientific skills that may be inaccessible to many public health researchers. To facilitate research in this domain, we created a database of population-weighted, spatially explicit daily heat metrics – including WBGT, UTCI, heat index, dewpoint temperature, net effective temperature, and humidex – for counties in the conterminous United States derived from the ERA5-Land gridded data set and using previously validated equations and algorithms. We also provide an R package to calculate these metrics, including gold-standard algorithms for estimating WBGT and UTCI, to facilitate replication.

Rising temperatures are causing distress across the world, and for those most vulnerable, it is a silent killer. Information about indoor air temperature in residential dwellings is of interest for a range of reasons, such as health, thermal comfort and coping practices. However, there have been only few studies that measure indoor heat exposure, and contrast these to outdoor temperatures in rural-urban areas, of which none are in South Asia. We aim to close this knowledge gap with our indoor and outdoor heat measurement dataset, covering five low-income sites in South Asia. Two sites are in rural areas (Maharashtra, India), while three sites focus on urban areas (Dhaka, Delhi and Faisalabad). Data are based on 206 indoor temperature data loggers and complemented by data from five outdoor automated weather stations. The data-set can be used to examine temperature and humidity variation in low-socioeconomic status households in rural and urban areas and to better understand factors aggravating heat stress. This is important to plan and implement actions for combating heat stress.

Extreme heat events are becoming more frequent and more severe in the Pacific Northwest and in comparable dry-summer climates worldwide, increasing the occurrence of heat-related illness and death. Much of this risk is attributed to overheating in multifamily dwellings, particularly in neighborhoods with abundant asphalt, few trees, and limited financial resources. Air-conditioning expansion is problematic, however, because it creates vulnerability to operational costs and power outages, while expelled hot air intensifies urban heat island effects. In contrast, passive cooling strategies that deflect solar radiation and recruit the cool night air typical of Mediterranean, semi-arid, and arid climates are quite promising, but their abilities to improve residential survivability during extreme heat have not yet been explored. To understand this potential, here we investigate the extent to which well-controlled shading and natural ventilation, in some cases with fan assistance, could have diminished the hours in which indoor heat index levels exceeded ‘caution’, ‘extreme caution’, ‘danger’, and ‘extreme danger’ thresholds during the June 2021 heat wave in the Pacific Northwest; building thermal performance was simulated in EnergyPlus under conditions experienced by Vancouver BC, Seattle WA, Spokane WA, Portland OR, and Eugene OR. Strikingly, we find that in Portland, where the highest temperatures occurred, integrated shading and natural ventilation eliminated all hours above the danger threshold during the 3-day event, lowering peak indoor air temperatures by approximately 14 °C (25 °F); without cooling, all 72h exceeded this threshold. During the encompassing 10-day period, these passive measures provided 130–150h of thermal relief; baseline conditions without cooling provided none. Additionally, passive cooling reduced active cooling loads by up to 80%. Together, these results show the immediate, substantial value of requiring effective operable shading and secure operable windows in apartments in mild dry-summer climates with rising heatwave intensity, as well as public health messaging to support the productive operation of these elements.

Issuing early heat warnings and enhancing public climate change awareness and engagement are important local policy options for heat wave adaptation. Here, we used a laboratory experiment to inform major gaps in making these two policies, including setting proper thresholds for heat alerting systems and figuring out how heat experience shifts individuals’ climate change perceptions. Taking Nanjing as a case city, we simulated a heat event by increasing temperature from 25 °C to 40 °C (70% relative humidity) in a climate chamber and recruited 58 young adults as participants. Physical thermal responses, including skin temperature and heart rate variability, were recorded using portable devices. Subjective thermal perceptions, climate change belief and psychological distance were measured by self-rated scales before, during, and after the exposure. We found physiological responses were correlated with subjective thermal perceptions and showed sharp rises from 30° to 35°C, presenting aggravated thermal discomfort. Moreover, heat exposure increased climate change belief and reduced psychological distance significantly. After the experiment, follow-up surveys showed participants had a short memory of the heat exposure, but daily temperature variations still predicted climate change belief. The findings suggest in our case city, the current threshold (35 °C) for heat warnings may not be safe enough. Local authorities should consider prolonged periods of hot weather with temperature between 30 and 35 °C. Due to strong links between heat experience and climate change perceptions, we encourage to take this “window of opportunity” when heat events occur to communicate climate risks and enact post-event policy changes.

Heat has become a central concern for cities everywhere, but heat governance has historically lagged behind other climate change hazards. This study examines 175 municipal plans from the 50 most populous cities in the United States to understand which aspects of urban heat are included or not in city plans and what factors explain inclusion. We find that a majority of plans mention heat, but few include strategies to address it and even fewer cite sources of information. The term ‘extreme heat event’ (EHE) is significantly more likely to be paired with institutional actions as a part of hazard planning, while ‘urban heat island’ (UHI) is more likely to be paired with green and grey infrastructure interventions as a part of general planning. Disparity and thermal comfort framings are not significantly related to any solutions and are used least. Plan type, followed by environmental networks (e.g. C40, Urban Sustainability Directors Network, Rockefeller 100 Resilient Cities), explain variation in plan content; social and environmental context do not. Findings point to the emergence of two independent heat governance systems, EHE and UHI, and several gaps in heat planning: integration, specificity, solutions, disparity, economy, and thermal comfort.

While recognition of the dangers of extreme heat in cities continues to grow, heat resilience remains a relatively new area of urban planning. One barrier to the creation and successful implementation of neighborhood-scale heat resilience plans has been a lack of reliable strategies for resident engagement. In this research, the authors designed a two-week summer STEM module for youth ages 12 to 14 in Roanoke, Virginia in the Southeastern United States. Participants collected and analyzed temperature and thermal comfort data of varying types, including from infrared thermal cameras and point sensors, handheld weather sensors, drones, and satellites, vehicle traverses, and student peer interviews. Based on primary data gathered during the program, we offer insights that may assist planners seeking to engage residents in neighborhood-scale heat resilience planning efforts. These lessons include recognizing: (1) the problem of heat in neighborhoods and the social justice aspects of heat distribution may not be immediately apparent to residents; (2) a need to shift perceived responsibility of heat exposure from the personal and home-based to include the social and landscape-based; (3) the inextricability of solutions for thermal comfort from general issues of safety and comfort in neighborhoods; and (4) that smart city technologies and high resolution data are helpful “hooks” to engagement, but may be insufficient for shifting perception of heat as something that can be mitigated through decisions about the built environment.

What is already known about this topic?

Exposure to excessive heat is an increasing threat in a warming climate. Some groups, including older adults, are disproportionately affected by heat exposure.

What is added by this report?

Heat exposure and heat-related illness (HRI) increased in Maricopa and Yuma counties, Arizona, during 2010–2020. Heat-related hospitalizations were higher among adults aged ≥65 years than those aged <65 years. Barriers to cooling center access among older adults include awareness of location and transportation.

What are the implications for public health practice?

States and communities can implement adaptation and evaluation strategies to mitigate and assess heat risk, such as the use of cooling centers to protect communities disproportionately affected by HRI during periods of high temperatures.

While previous research on historical changes in heat-related mortality observed decreasing trends over the recent decades, future projections suggest increasing impact of heat on mortality in most regions of the world. This study aimed to analyse temporal changes in temperature-mortality relationships in Prague, Czech Republic in the warm season (May–September), using a daily mortality time series from 1982 to 2019. To investigate possible effect of adaptation to increasing temperature, we divided the study period into four decades (1980s–2010s). We used conditional Poisson regression models to identify decade-specific relative risk of heat-related mortality and to calculate the annual number of heat-attributable deaths and the heat-attributable fraction of total warm season deaths. We estimated their trends over the whole study period by a generalized additive model with non-parametric smoothing spline. Our results showed that the unprecedentedly hot 2010s was associated with approximately twice as large relative risk of heat-related mortality than in previous decades. This resulted in the reversal of the trend in heat-attributable mortality in the 1990s and its increase during the last two decades. Our findings highlight the importance of further improvement of adaptation measures such as heat-and-health warning systems to protect the heat-susceptible population.

The position with Montana State University will lead research as part of a NASA-funded project to assess the relationship between maternal/child health, extreme heat and land-cover/land change (LCLUC) in sub-Saharan Africa.

The Heat Action Platform is a living, engagement-oriented tool for city officials, practitioners, and financial institutions to find guidance, both existing resources and tailor-made solutions, on reducing the human and economic impacts of extreme heat at the regional or municipal level. The platform offers opportunities to engage with world-leading experts across a diversity of disciplines to plan, fund, implement, and measure heat resilience actions.

The platform was developed by the Adrienne Arsht-Rockefeller Foundation Resilience Center and the Extreme Heat Resilience Alliance in collaboration with the UN Environment Programme, the Cool Coalition, RMI, the Global Covenant of Mayors for Climate and Energy, Mission Innovation and the World Economic Forum’s Global Commission on BiodiverCities by 2030.

The platform can support you to:

Background: The populations of developing nations are more vulnerable to high heat due to poor public health infrastructure and their sensitiveness towards changing climate. Excess mortalities caused by high temperatures have been reported from many parts of the world, including India. In the recent future, more warming and frequent hot days during summer are expected.

Methods: An analysis was carried out to study the effect of maximum temperature (Tmax) on gender-specific all-cause mortality during the summer months (May and June) of 2011 to 2015 in Chandigarh city of India. The mortality is calculated at different thresholds of temperatures of ≤35°C, ≤38°C, <40°C, ≥40°C and ≥42°C. The average number of deaths at temperatures <40°C and ≥40°C were calculated at 99% significance. The Welch t-test is applied to test the significance.

Results: Tmax shows a high degree of association with all-cause mortality in both males and females. Male to female all-cause death ratio was found to be 1.67 for the study period. Daily Tmax of 40°C was found to be the point of inflexion as the number of mortalities at Tmax ≥40°C was significantly higher than those at Tmax below 40°C. The analysis also reveals an increase in the number of death among females at the threshold Tmax ≥40°C indicating higher vulnerability of females at higher temperatures of certain threshold.

Conclusion: A temperature of 40°C should be considered a threshold temperature for issuing heatwave alerts for Chandigarh, India. The increase in vulnerability at temperatures ≥40°C was more among the females

Several socio-economic sectors are sensitive to the occurrence of extreme climate events. The ability to predict these extremes will allow precautionary measures to reduce their impacts. This work aims to disseminate a seasonal statistical forecast of daily temperature extremes in Argentina to the international scientific community. At the local level, this forecast is shared at monthly meetings organized by the Argentine National Meteorological Service and attended by different users. For the temperature extremes modeling, several predictors and statistical techniques were applied. We estimated the probability of each tercile category (above-normal, near-normal, and below-normal) by quantifying the percentage of models that predict each of them. The forecasts were verified by calculating different metrics. In general, we observed that the forecast system has less skill to discriminate the near-normal category in all seasons, and the other categories present a skill highly variable according to the season, region, and extreme index. The verification process revealed that predictability increases for all extreme indices with a previous La Niña phase. This product represents an advance towards an operational seasonal forecast of extreme temperatures in Argentina because it offers predictions based on a detailed study of predictors in the region, the incorporation of multiple statistical methodologies, and the predicted variables are not the most typical ones offered by forecasting centers. Finally, it is highlighted that the accuracy rate obtained with this product exceeds a forecast based on climatology, i.e., despite the uncertainties, our forecasts provide additional information to users for decision making.

Both low and high temperatures may be important drivers of increased risk of external causes of death. We suggest that preventive measures against external causes of death should be considered in adaptation policies.

The 7th Master Class on “Role of City Planning in The Mitigation of Extreme Heat” by expert Dr Dr. Rajashree Kotharkar, Professor, Department of Architecture and Planning, Visvesvaraya National Institute of Technology (VNIT), Nagpur, India conducted on 27th, April, 2022

Heat is the number one weather-related killer in the United States. As average global temperatures continue to rise, the threats of both extreme heat events and chronic heat are projected to increase.

Heat disproportionately affects marginalized residents and those who face systematic inequities such as workplace safety, housing quality, energy affordability, transportation reliability, and healthcare access. But planning can shape heat risk. Planners will be key practitioners in helping their communities achieve greater heat resiliency by proactively managing and mitigating heat across the many systems and sectors it affects.

PAS Report 600 provides holistic guidance to help practitioners increase urban heat resilience equitably in the communities they serve. It provides an in-depth overview of the contributors to urban heat and equity implications, and it lays out an urban heat resilience framework and collection of strategies to help planners mitigate and manage heat across a variety of plans, policies, and actions.

Now is the time for the planning profession to step up and take a leading role in coordinating communities’ efforts to proactively build urban heat resilience. This PAS Report equips planners with the background knowledge, planning framework, and catalog of comprehensive approaches they need to advance urban heat resilience and create a more equitable and sustainable future in an increasingly urban and warming world.

This report is available free to all. This project was supported by financial assistance provided by the National Oceanic and Atmospheric Administration’s Extreme Heat Risk Initiative.

This scoping study draws on a review of key policy documents, plans, grey, academic, and scientific literature to outline the role of state and non-state actors in Karachi’s heat governance. It emphasizes the need to understand heat, microclimates, urban planning, infrastructural inequities, and vulnerability in a relational context. It also presents original climate data analysis for the last 60 years in Karachi, to quantify the rapid temperature change in the city: findings that underscore why it is important now, more than ever, to talk about heat in the context of an unequal city.

Context: Tropical areas and small islands are identified as highly vulnerable to climate change, and already experiencing shifts in their temperature distribution. However, the knowledge on the health impacts of temperatures under tropical marine climate is limited. We explored the influence of temperature on mortality in four French overseas regions located in French Guiana, French West Indies, and in the Indian Ocean, between 2000 and 2015.

Method: Distributed lag non-linear generalized models linking temperature and mortality were developed in each area, and relative risks were combined through a meta-analysis. Models were used to estimate the fraction of mortality attributable to non-optimal temperatures. The role of humidity was also investigated.

Results: An increased risk of mortality was observed when the temperature deviated from median. Results were not modified when introducing humidity. Between 2000 and 2015, 979 deaths [confidence interval (CI) 95% 531:1359] were attributable to temperatures higher than the 90th percentile of the temperature distribution, and 442 [CI 95% 178:667] to temperature lower than the 10th percentile.

Discussion: Heat already has a large impact on mortality in the French overseas regions. Results suggest that adaptation to heat is relevant under tropical marine climate.

This study investigate the association between ambient heat and mental health–related emergency department (ED) visits in the contiguous US among adults overall and among potentially sensitive subgroups.

The juxtaposition of climate change and development changes is vital for understanding the future impacts of heat stress in urban areas. However, an approach that considers the relationship between climatic factors and socio-economic vulnerability in a forward-looking and stakeholder-involved manner is challenging. This article demonstrates the application of a future-oriented vulnerability scenarios approach to address human heat stress in Bonn, Germany, in 2035. The study highlights the interplays between climate trajectories and heat exposure associated with urban development scenario corridors. Moreover, this method allows for changing combinations of intersections and conditionalities of projected individual socio-economic vulnerability indicators in response to social and climate governance. However, this study found that a conventional structure within city departments might limit this integrative approach in practice. Thus, the theoretical background and the concept of alternative futures and uncertainties should be the focus of communication with practitioners to maximize the utilization of the results.

Heat-related illness (HRI) is a common occupational injury, especially among workers in the construction industry. Methods need to be developed to predict and minimize HRI risk. The objective of this study was to investigate whether differences in heart rate (HR) can be used to predict HRI risk. We surveyed construction workers during the period from May 1 to October 30, 2020. The physiological data of 79 workers were recorded during their working hours for a period of 3163 person-time. The resting HR was defined as the lowest reading taken within the first hour of wearing the sensor, and HRI risk was determined using the following formula: 180 – (0.65 × age). The rate of increase in HR from rest was calculated using the following formula: (maximum HR – resting HR)/resting HR. On these 3163 person-time, HRI risk was observed at 368 person-time (11.6%). After analyzing the receiver operating characteristics curve, the cut-off value was 132.9%, with a sensitivity of 75.5% and specificity of 85.0%. Our results showed that the difference in HR from rest is a good indicator for predicting HRI risk. Furthermore, continuous physiological monitoring using a wearable sensor can aid in detecting early signs of HRI risk.

Climate change is expected to lead to changes in seasonal temperature-related mortality. However, this impact on health risk does not necessarily scale linearly with increasing temperature. By examining changes in risk relative to degrees of global warming, we show that there is a delayed emergence of the increase in summer mean mortality risk in England and Wales. Due to the relatively mild summer mean temperatures under the current climate and the non-linearity of the exposure–response relationships, minimal changes in summer mean risk are expected at lower levels of warming and an escalation in risk is projected beyond 2.5 °C of global warming relative to pre-industrial levels. In contrast, a 42% increase in mortality risk during summer heat extremes is already expected by 2 °C global warming. Winter attributable mortalities, on the other hand, are projected to decrease largely linearly with global warming in England and Wales.

There is a pressing need for strategies to prevent the heat-health impacts of climate change. Cooling urban areas through adding trees and vegetation and increasing solar reflectance of roofs and pavements with higher albedo surface materials are recommended strategies for mitigating the urban heat island. We quantified how various tree cover and albedo scenarios would impact heat-related mortality, temperature, humidity, and oppressive air masses in Los Angeles, California, and quantified the number of years that climate change–induced warming could be delayed in Los Angeles if interventions were implemented. Using synoptic climatology, we used meteorological data for historical summer heat waves, classifying days into discrete air mass types. We analyzed those data against historical mortality data to determine excess heat-related mortality. We then used the Weather Research and Forecasting model to explore the effects that tree cover and albedo scenarios would have, correlating the resultant meteorological data with standardized mortality data algorithms to quantify potential reductions in mortality. We found that roughly one in four lives currently lost during heat waves could be saved. We also found that climate change–induced warming could be delayed approximately 40–70 years under business-as-usual and moderate mitigation scenarios, respectively.

Excess heat in urban environments is an increasing threat to human health and well-being. Furthermore, the increasingly important phenomenon of the Urban Heat Island (UHI) is exacerbating problems of livability in urban centers. Hence, there should be an increasing effort to assess the impact of heat mitigation strategies (HMSs) on outdoor thermal comfort in cities. This research has investigated how urban areas in steppe climate zones can be more thermally comfortable due to the effects of water bodies and trees, and how this might help to mitigate heat waves. Numerical simulations using the ENVI-met microclimate model have been performed for an urban park in Tabriz, Iran. In-situ measurements of air temperature (Ta) and mean radiant temperature (MRT) have been carried out in the study site and the collected data was used to validate the model (RMSE value 0.98 °C for Ta and 5.85 °C for MRT). Results show that water body evaporation without trees may decrease the air temperature, but on the other hand also increases the humidity, which reduces the positive impact on thermal comfort. However, the combination of water body with trees represents a better performance in the regulation of urban microclimate and thermal comfort.

The last decade was the warmest on record, and leading organisations on climate change indicate that warmer temperatures are not a potential threat but a surety. This report considers ways in which disaster risk reduction (DRR), climate change adaptation (CCA), and related scientific communities can rise to data challenges in order to provide policymakers with the evidence needed to set priorities and make decisions. Given the sizeable threat posed by extreme heat events, the report details the human impacts of heat waves, ranging from individual and community health to the built environment.

The HE²AT Center aims to develop innovative solutions to mitigate the health impacts of climate change in Africa, including Early Warning Systems and monitoring systems. The Center also aims to build capacity on data science and climate change, and to be a resource for climate change initiatives across the continent.

Background

Heat waves and rising temperatures have major, though underappreciated, health implications, particularly among vulnerable populations in low-income settings in Africa. Big data and data science methods can identify promising adaptation interventions and optimise programmes to reduce the impacts of climate change. The current Early Warning Systems in Africa function poorly and are not based on actual health outcome data. Moreover, there is limited knowledge on how to monitor the burden of climate change on health and the effectiveness of relevant health services.

Methods

The HE²AT Center is a U54 grant within the NIH Harnessing Data Science for Health Discovery and Innovation in Africa (DS-I Africa) programme. DS-I Africa is the NIH flagship programme of research in Africa, with USD 62,000,000 funding. The consortium consists of a trans-disciplinary group of academic and non-academic partners from three regions of Africa, and the United States. The study includes partners in South Africa, Côte d’Ivoire and Kenya, with a focus on activities in these countries. The Center includes two sub-projects. Firstly, a project to document the impacts of extreme heat on maternal and newborn health across Africa using existing data from research projects and routine health information systems. We will draw on data from all countries on the continent where data are available. These analyses will also test different indicators of the impacts of extreme heat on health. The second project will investigate the urban heat island effect in Johannesburg, South Africa and Abidjan, Côte d’Ivoire, using multiple data sources from satellites on the natural (e.g., vegetation) and the built environment, combined with weather, air pollution, and health outcome data. We will use health outcome data from large clinical trials and cohorts which has the geolocation of participants houses allowing for very precise measurements of the exposure of these individuals to heat and other environmental risk factors. Based on these analyses we will design an Early Warning System that can warn people when an extreme heat event is forecast. Risk strata will be generates in the Early Warning System, based on the risk profiles of specific risk groups, determined by a machine learning algorithm which takes into account forecasted weather conditions, characteristics such as age, geolocation and other factors that drive risk. The current approach to Early Warning Systems involves a single cut-off temperature threshold that is meant to represent risk for all members of the population. Tis approach lacks sensitivity as the health risks of extreme heat vary between population groups several fold. We will pilot a range of communication channels to deliver risk warnings tailored to different risk groups. This includes using an existing smartphone App (ClimApp). Most importantly, the HE²AT Center serves as a platform for other research projects or programmes related to climate change and health in Africa.

Relevance to the Green Climate Fund and Adaptation Fund The HE²AT Center provides a platform which has the potential to monitor projects funded by the Green Climate Fund, and to identify which interventions should be prioritised in funding proposals. Data science analytics could make a major contribution to optimising climate change and health projects. The prototype Early Warning Systems and monitoring systems that we develop could be adapted to different settings and population groups included in Green Climate Fund applications.

Timelines and anticipated impact Over a five to ten year period, the HE²AT Center will have established a data science and analytical platform capable of documenting the impacts of extreme heat, informing sensitive Early Warning Systems and monitoring systems across sub-Saharan Africa.

Other project partners University of Cape Town, South Africa; Aga Khan University, Kenya; University Peleforo Gon Coulibaly of Korhogo, Côte d’Ivoire; IBM Research Africa; University of Michigan; and University of Washington

Donor

US National Institutes of Health (NIH)

Latest Update: 02 February 2022

For more about HE²AT Center please email rhicomms@wrhi.ac.za

Both climate change and rapid urbanization accelerate exposure to heat in the city of Kampala, Uganda. From a network of low-cost temperature and humidity sensors, operational in 2018–2019, we derive the daily mean, minimum and maximum Humidex in order to quantify and explain intra-urban heat stress variation. This temperature-humidity index is shown to be heterogeneously distributed over the city, with a daily mean intra-urban Humidex Index deviation of 1.2 ^∘C on average. The largest difference between the coolest and the warmest station occurs between 16:00 and 17:00 local time. Averaged over the whole observation period, this daily maximum difference is 6.4 ^∘C between the warmest and coolest stations, and reaches 14.5 ^∘C on the most extreme day. This heat stress heterogeneity also translates to the occurrence of extreme heat, shown in other parts of the world to put local populations at risk of great discomfort or health danger. One station in a dense settlement reports a daily maximum Humidex Index of 40 ^∘C in 68% of the observation days, a level which was never reached at the nearby campus of the Makerere University, and only a few times at the city outskirts. Large intra-urban heat stress differences are explained by satellite earth observation products. Normalized Difference Vegetation Index has the highest (75%) power to predict the intra-urban variations in daily mean heat stress, but strong collinearity is found with other variables like impervious surface fraction and population density. Our results have implications for urban planning on the one hand, highlighting the importance of urban greening, and risk management on the other hand, recommending the use of a temperature-humidity index and accounting for large intra-urban heat stress variations and heat-prone districts in urban heat action plans for tropical humid cities.

The global prevalence of childhood obesity has risen dramatically recently. Previous studies found an association between rapid infant weight gain and childhood overweight. Evidence suggests that exposure to high ambient air temperatures during prenatal life and during adulthood is associated with birthweight and obesity respectively.

Conclusions: Exposure to higher ambient temperatures, of emerging importance in the climate change era, is associated with rapid infant weight gain in Israel. Future studies should use additional exposure, covariate, and outcome data to analyse the nature and the source of this association in more detail.

Outdoor workers perform critical societal functions, often despite higher-than-average on-the-job risks and below-average pay. Climate change is expected to increase the frequency of days when it is too hot to safely work outdoors, compounding risks to workers and placing new stressors on the personal, local, state, and federal economies that depend on them. After quantifying the number of outdoor workers in the contiguous United States and their median earnings, we couple heat-based work reduction recommendations from the U.S. Centers for Disease Control and Prevention with an analysis of hourly weather station data to develop novel algorithms for calculating the annual number of unsafe workdays due to extreme heat. We apply these algorithms to projections of the frequency of extreme heat days to quantify the exposure of the outdoor workforce to extreme heat and the associated earnings at risk under different emissions scenarios and, for the first time, different adaptation measures. With a trajectory of modest greenhouse gas emissions reductions, outdoor worker exposure to extreme heat would triple that of the late 20th-century baseline by mid-century, and earnings at risk would reach an estimated $39.3 billion annually. By the late century with that same trajectory, exposure would increase four-fold compared to the baseline with an estimated $49.2 billion in annual earnings at risk. Losses are considerably higher with a limited-mitigation trajectory. While universal adoption of 2 specific adaptation measures in conjunction could reduce mid-century and late-century economic risks by roughly 90% and 93%, respectively, practical limitations to their adoption suggest that emissions mitigation policies will be critical for ensuring the well-being and livelihoods of outdoor workers in a warming climate.

Among both younger and older adults, days of extreme heat are associated with a higher risk of ED visits for any cause, heat related illness, renal disease, and mental disorders. These results suggest that the adverse health effects of extreme heat are not limited to older adults and carry important implications for the health of adults across the age spectrum.

Road pavement is a known contributor to the urban heat island effect. Several vendors are providing engineered pavements coatings – known as “cool pavement” – to reflect light and therefore heat to reduce the thermal load of roads. The City of Tucson is planning a pilot application of a cool pavement in Fall 2021 as a part of its Parks and Connections Bond work; our team has been working with the city and vendor(s) to set up an evaluation framework of the cool pavement.

Few of these cool pavements have been evaluated outside lab conditions, particularly in the desert southwest. Lab testing tends to rely heavily on surface temperature measurements with the assumption that lower surface temperatures result in the pavement being less of a heat sink and thus lowers ambient temperatures in real-world practice. Further, while heat is detrimental to the pedestrian and cyclist experience and health, almost no research exists documenting the experience of the cool pavement on active travelers including their perception of heat.

We propose a pre/post, case/control quasi-experimental design to evaluate the impacts of the cool pavement on the following heat metrics:

• Surface temperatures of the pavement
• Ambient temperatures of the area
• Thermal comfort as measured by wet bulb globe temperature (WBGT) – Governmental occupational guidance for exertion for heat is based on studies in industrial settings using wet-bulb globe temperature (WBGT), a heat index that incorporates ambient air temperature, humidity, airflow, and radiant solar heat. Known as “thermal comfort”, this index better mirrors the human – and thus pedestrian and cyclist – experience.

We anticipate four 12-hour days in the field. Each day will include seven Kestrel 5400 stations for ambient and WBGT temperatures at least every minute and surface temperatures every hour. Data will be managed and analyzed in R; outputs will include basic summary statistics, graphics, and regression analysis.

Our team has steadily increased capacity for such research over the past 2 years. In summer of 2019, Iroz-Elardo and Keith piloted a methodology to investigate how shade structures and surface materials in school gardens and play structures influenced thermal comfort as measured with a WBGT instrument and thermal heat guns. In late-spring 2020, Keith and Iroz-Elardo applied this knowledge to evaluate heat risk at COVID-19 vaccine point of distribution (POD) drive-in centers in Tucson. One of the more interesting preliminary findings from the vaccine POD evaluation was the extent to which idling vehicles appear to raise the WBGT in outdoor settings due to both mechanical and radiant heat.

Indigenous communities in remote Australia face dangerous temperature extremes. These extremes are associated with increased risk of mortality and ill health. For many households, temperature extremes increase both their reliance on those services that energy provides, and the risk of those services being disconnected. Poor quality housing, low incomes, poor health and energy insecurity associated with prepayment all exacerbate the risk of temperature-related harm. Here we use daily smart meter data for 3,300 households and regression analysis to assess the relationship between temperature, electricity use and disconnection in 28 remote communities. We find that nearly all households (91%) experienced a disconnection from electricity during the 2018–2019 financial year. Almost three quarters of households (74%) were disconnected more than ten times. Households with high electricity use located in the central climate zones had a one in three chance of a same-day disconnection on very hot or very cold days. A broad suite of interrelated policy responses is required to reduce the frequency, duration and negative effects of disconnection from electricity for remote-living Indigenous residents.

The South Asia Heat Health Information Network (SAHHIN) is pleased to invite you to its Fourth Global Master Class on ‘Heat Early Warning Systems-Scientific Approaches for Estimating Thresholds’ by expert Mr. Abhiyant Tiwari, Assistant Professor and Program Manager, Gujarat Institute of Disaster Management (GIDM) Govt. of Gujarat.

Extreme temperatures have reached unprecedented levels in many regions of the globe due to climate change anda further increase is expected. Besides other consequences, high temperatures increase the mortality risk and severely affectthe labour productivity of workers. We perform a high-resolution spatial analysis to assess the impacts of heat on mortality and labour productivity in Switzerland and project their development under different Representative Concentration Pathway (RCP) scenarios, considering that no socio-economic changes takes place. The model is based on the risk framework of the Intergovernmental Panel on Climate Change (IPCC), which combines the three risk components: Hazard, Exposure, and Vulnerability. We model the two impact categories in the same spatially explicit framework and we integrate uncertainties into the analysis through a Monte Carlo simulation. We model, that first, about 670 people die today per year because of heat in Switzerland. Second, the economic costs caused by losses in labour productivity amount to around CHF 413 million (approx. $ 465 million) per year. Should we remain on an RCP8.5 emissions pathway, these values may double (for mortality) or even triple (for labour productivity) by the end of the century. Under an RCP2.6 scenario impacts are expected to slightly increaseand peak around mid-century, when climate is assumed to stop warming. Even though uncertainties in the model are large, theunderlying trend in impacts is unequivocal. The results of the study are valuable information for political discussions and allowfor a better understanding of the cost of inaction.

The Sahelian zone of Senegal is marked by heatwave events due to temperatures increase especially in 2013 exceeding 45 ° C with an impact on morbidity and mortality rise. In order to document health impacts of recurrent extreme temperatures in this part of the country, a study was carried out combining heatwaves detection, occurrence of climate-sensitive diseases and risk factors for exposure. Methods To do this, a set of climatic (temperatures) and health (morbidity, mortality) data were collected for April, May and June season from 2009 to 2019. These data were complemented by surveys on exposure risk factors of 1246 households. Statistical methods were used to carry out univariate and bivariate analyzes while cartographic techniques allowed visualization of the main climatic and health indicators. Results The results show an increase in temperatures compared to seasonal normal for the 1971-2000 reference period with threshold exceedances of the 90th percentiles (42°C) for the maxima and (27°C) the minima and higher temperatures during the months of May and June. From health perspective, it was noted an increase in cases of consultation on health facilities as well as a rise in declared morbidity by households especially in the departments of Kanel (17.7%), Ranérou (16.1%), Matam (13.7%) and Bakel (13.7%). The heatwaves of May 2013 were also associated with cases of death with a reported mortality (observed by medical staff) of 12.4% unevenly distributed according to the departments with a higher number of deaths in Matam (25, 2%) and in Bakel (23.5%) than in Podor (8.4%) and Kanel (0.8%). The morbidity and mortality distribution according to gender shows that women (57%) were more affected than men (43%). These health risks have been associated with a number of factors including age, access to drinkable water, type of fuel, type of housing and construction materials, existence of fan, an air conditioner, health antecedents, etc. Conclusion The heatwaves recurrence has led to an upsurge in certain diseases sensitive to rising temperatures, which is increasingly a public health issue in the Sahelian zone of Senegal.

This study provides evidence of the impact of COVID-19, particularly on the possible roles of physical interventions and behavioral changes, in modifying the temperature-health association. These findings would have implications on subsequent policies or heat-related warning strategies in light of ongoing or future pandemics.

Many studies have shown that heat waves can cause both death and disease. Considering the adverse health effects of heat waves on vulnerable groups, this study highlights their impact on workers. The present study thus investigated the association between heat exposure and the likelihood of hospitalization and death, and further identified the risk of heat-related diseases or death according to types of heat and doseresponse modeling with heat threshold. Workers were selected from the Korean National Health Insurance Service-National Sample Cohort 2002–2015, and regional data measured by the Korea Meteorological Administration were used for weather information. The relationship between hospitalization attributable to disease and weather variables was analyzed by applying a generalized additional model. Using the Akaike information criterion, we selected a model that presented the optimal threshold. Maximum daily temperature (MaxT) was associated with an increased risk of death and outdoor mortality. The association between death outdoors and MaxT had a threshold of 31.2°C with a day zero lag effect. History of medical facility visits due to the health effects of heat waves was evident in certain infectious and parasitic diseases (A and B), cardio and cerebrovascular diseases (I20–25 and I60–69), injury, poisoning, and other consequences of external causes (S, T). The study demonstrated that heat exposure is a risk factor for death and infectious, cardio-cerebrovascular, and genitourinary diseases, as well as injuries or accidents among workers. The finding that heat exposure affects workers’ health has future implications for decision makers and researchers.

The Intergovernmental Panel on Climate Change (IPCC) report highlights the projected increase in heat wave (HW) frequency, intensity, and duration. Globally, HW events have caused massive deaths in the past. India has also experienced severe HWs and thousands have reportedly died during the past decade. The study uses the Local Climate Zone (LCZ) classification developed by Stewart and Oke (2012) for evaluating heat stress at the city level during the summer period. Stationery surveys were conducted to collect micro-meteorological data in different LCZs. The study analyses the unique behaviour of mapped LCZs in Nagpur, a tropical landlocked Indian city using widely adopted heat indices (heat index and humidex). It investigates two kinds of probabilities, the distribution of heat stress levels in a particular LCZ and how vulnerable are various LCZs to a given heat stress level. It adopts a statistical approach fitting a predictive logit model to estimate the probability of heat stress in various LCZs. The results show that temperature regimes differ significantly across the LCZs. Secondly, heat stress varies greatly depending upon the LCZs. The mapping scheme and the corresponding heat stress provides indispensable information for targeted heat response planning and heat stress mitigation strategies in heat-prone areas.

Heat exposure from deforestation and climate change has already started affecting populations in low latitude, industrialising countries, and future global warming indicates substantial health impacts in these regions. Further research should examine how deforestation is currently affecting the health and wellbeing of local communities.

Very little research has documented the exposure of populations in Africa to extreme heat. We measured indoor air temperature and humidity hourly for 13 months in seven houses of contrasted architecture and construction materials all in the northern neighbourhoods of Ouagadougou, Burkina Faso. These measurements are compared to air temperatures recorded at the synoptic weather station of Ouagadougou airport and to land surface temperature estimates from Landsat satellite images at seven dates with clear-sky conditions. The results reveal huge temperature differences (exceeding 10 °C) between houses, especially in the afternoon hours of the warmest season. Indoor temperature is also much more variable than land surface (outdoor) temperature in the same locations, as estimated by satellite imagery. Houses with greater thermal inertia smooth the afternoon temperature peak, reducing heat exposure. Heat stress bioindicators reveal that danger thresholds, while rarely reached in some houses, are frequently exceeded in others year round except for the core of the cold winter season (December and January). In spring, the hottest season, the danger threshold is almost permanently exceeded in these dwellings, exposing their inhabitants to significant heat stress. This pilot study shows the primary role of housing in modulating indoor temperature, raising questions of public health and habitability of Sahelian regions in a warming world. This issue will be of increasing importance with ongoing climate change, hence the need for further, more detailed instrumented campaigns in African settlements.

Problem, Research Strategy, and Findings: Extreme heat is the deadliest climate hazard in the United States. Climate change and the urban heat island effect are increasing the number of dangerously hot days in cities worldwide and the need for communities to plan for extreme heat. Existing literature on heat planning focuses on heat island mapping and modeling, while few studies delve into heat planning and governance processes. We surveyed planning professionals from diverse cities across the U.S. to establish critical baseline information for a growing area of planning practice and scholarship, which future research can build on. Survey results show that planners are concerned with extreme heat risks, particularly environmental and public health impacts from climate change. Planners already report impacts from extreme heat, particularly to energy and water use, vegetation and wildlife, public health, and quality of life. Especially in impacted communities, planners claim they address heat in plans and implement heat mitigation and management strategies such as urban forestry, emergency response, and weatherization, but perceive many barriers related to human and financial resources and political will. Takeaway for practice: Planners are concerned about extreme heat, especially in the face of climate change. They are beginning to address heat through different strategies and plan types, but we see opportunities to better connect planners to existing heat information sources and leverage existing planning tools, including vegetation, land use regulations, and building codes to mitigate risks. While barriers to heat planning persist, including human and capital resources, planners are uniquely qualified to coordinate communities’ efforts to address the rising threat of extreme heat.

The National Action Plan on Heat Related lllnesses, developed with inputs from various governmental and non-governmental experts, is intended to be used by government and private health care facilities, health departments, and policymakers tasked with strengthening health facilities and emergency response. This document provides guidance to manage severe heat-related illnesses and to report them under National Heat Related Illness surveillance.

The humanitarian impact of extreme heat is an increasing concern, especially in low-income countries with limited access to quality healthcare and informal dwellings which can trap heat. This report analyses the knowledge, attitude and practice of Karachi residents in relation to managing extreme heat. It was conducted in 2020 following a messaging campaign led by HANDS related to extreme heat. The project was triggered through a disaster risk financing approach, using a heatwave model to trigger funding automatically when extreme heat was forecast.

Impact of environmental thermal stress on workers’ health and productivity: intervention strategies and development of an integrated weather-climatic and epidemiological heat health warning system for various occupational sectors (WORKLIMATE)

The aim of the project is to deepen, especially through the INAIL injury database, the knowledge on the effect of environmental thermal stress conditions on workers (in particular heat), with specific attention to the estimation of the social costs of injuries at work. Organizational solutions and useful operational procedures in different occupational fields (or tasks), currently not yet available, will also be proposed through the organization of ad hoc case studies in selected companies in the areas of central Italy, a survey on the perception of risk linked to exposure to extreme temperatures will carried out too. An integrated weather-climatic and epidemiological heat health warning system, specific for the occupational sector, will be developed. The heat health warning system will consist of a web forecasting platform and a web app that will provide personalized forecasts based on the individual characteristics of workers and those of the work environment (work in the sun or in shade areas). The project products will be enhanced and made available by the Italian Physical Agents Platform (PAF) in order to provide concrete and operational support helpful not only for workers but also for all actors involved in the occupational prevention and protection process.

Stuttgart’s location in a valley basin, its mild climate, low wind speeds, industrial activity and high volume of traffic has made it susceptible to poor air quality. Development on the valley slopes has prevented air from moving through the city, which worsens the air quality and contributes to the urban heat island effect. A Climate Atlas was developed for the Stuttgart region, presenting the distribution of temperature and cold air flows according to the city’s topography and land use. Based on this information, a number of planning and zoning regulations are recommended that also aim to preserve and increase open space in densely built-up areas.

In inner city Berlin, plans for the development of new buildings are subjected to the Berlin Landscape Programme, which includes a regulation requiring a proportion of the area to be left as green space: the Biotope Area Factor (BAF) or BFF (Biotop Flächenfaktor). All potential green areas, such as courtyards, roofs and walls are included in the BAF. The regulation is a part of a larger set of documents relating to landscape planning and design as well as species protection. It responds to the need to encourage more green space in densely built-up urban areas.

Climate change is expected to increase and intensify heatwaves and water-related extremes; two impacts that are particularly relevant for the urban context. By encouraging the introduction of more green space, the BAF is an important mechanism to reduce local climate change vulnerability as its measures help to lower the temperatures and improve the runoff management. The implementation of the BAF started in 1994 and is still on-going. A considerable number of new built areas in the inner city centre have implemented this regulation, translating it into green areas.

Evidence that elevated temperatures can lead to increased mortality and morbidity is well documented, with population vulnerability being location specific. The elderly are particular vulnerable to extreme heat stress. Being part of the Iberian Peninsula, Portugal has a mild Mediterranean climate. Climate change projections indicate that the number of days with extreme heat in Portugal will increase with urban areas being more sensitive. If future populations become more urbanized and the number of elderly continues to increase, the issue of heat-related mortality will likely become more severe.

During the 2003 heatwave in Europe, Portugal was one of the few countries that already had an early warning system in place: but only for Lisbon, the capital city. Following the 2003 heatwave, the Portuguese Heatwave Contingency Plan was established and has been in operation every year from May to September. This is a national plan covering the whole continental Portugal. The aim of the current Portuguese Heatwave Contingency Plan is to prevent the adverse health effects of heat stress on the population during periods of elevated temperatures. Daily alerts are key factors to the successful implementation of this plan; they indicate what protection measures must be carried out to protect the population during periods of elevated temperatures.

Evidence that increasing temperatures leads to increased mortality and morbidity is well documented, with population vulnerability being location specific. Especially the 2003 heat wave in Europe raised the awareness of negative impacts of heat stress on human health in Austria. Increased incidence of heat waves leads to an increase in heat stress, especially in urban areas; the intensification of the heat-island effect is to be expected. Following the 2003 heat wave, different Austrian provinces like Styria (2011) and Carinthia (2013) developed heat protection plans, based on recommendations from the World Health Organisation, which recommended to develop strategies, plans and packages of measures in order to protect citizens from heat stress.

These plans provide an information basis for public health services. Based on the experience from the two provinces, an Austrian heat protection plan, led by the Ministry of Health and Woman´s Affairs with involvement of several relevant actors on the national and provincial level was prepared and put in action in 2017. The plan sets out the connection between climate change and health as well as the meteorological baseline information for heat warnings, which is provided by the National Met Service (ZAMG). The information and warnings are directed to the citizen via a sound network of institutions and actors in the health field.

Demographic change and climate change together place great challenges on the society. The life expectancy of the population in Germany rises and so does the share of older people. Besides chronic patients and children, the elderly are especially affected by the effects of the climate change. At the same time more and more people live in single person households (increase from 14.56 million in 2004 to 16.83 million in 2016 in Germany), which can influence their social isolation. How can we reach these people in order to prevent negative impacts during heatwaves? This is where the heat hotline parasol from the city of Kassel (around 200.000 inhabitants) in Germany comes into play. The heat hotline parasol is a free of charge hotline that calls registered citizens and provides information on heat-warnings from the German Weather Service and suggest measures how to best deal with and adapt to higher temperatures and heat. With this hotline special support is provided to citizens, especially elderly and their families, to deal with heat in the urban area of the city of Kassel. The Elderly Committee of the City of Kassel and the Health Department of the Kassel region cooperates in the heat hotline parasol.

High temperatures and heatwaves in the summer pose increasing risks to people living in Slovakian cities. In particular older people and children, those living on top floors in poorly insulated buildings, and those relying on facilities such as nurseries, schools or care homes are prone to heat stress. The Carpathian Development Institute, in collaboration with local authorities in Trnava and Košice, carried out an assessment of vulnerability to high temperatures and heatwaves in residential environment, taking into account the social aspects. Factors such as presence of older people, children and location of facilities serving these vulnerable groups were considered.

Based on the results of the assessment, adaptation strategies are being implemented in both Trnava and Košice, including measures such as thickening of tree stands in parks, building and restoration of water elements (blue infrastructure) and fountains in most vulnerable places, actions aiming at changing citizen behavior during heatwaves, etc., Moreover, a neglected public open space in a vulnerable area in Trnava was redesigned to provide shading through planting of trees and other vegetation.

In the last century, heatwaves in Sweden occurred once every 20 years (the last being in 1975). Since the start of the new millennium, four heatwaves (2003, 2007, 2010 and 2018) have been already experienced. The frequency of these events is expected to further increase due to climate change; they will occur once every three to five years towards the end of the century. Heatwaves are already leading to increased mortality. Botkyrka is a municipality in Stockholm County in east central Sweden, not far from the capital with a population of 91.925 inhabitants. In 2010, the municipality experienced prolonged high temperatures, which led among other things to problems in elderly, retirement and nursing homes. The residents were severely hit by the heat and the staff had problems to look after them well enough.

Extensive efforts, partly in the frame of a project held within the Climatools program, have been made in the municipality of Botkyrka to reduce the health risk of heatwaves. Staff of elderly, retirement and nursing homes has acquired knowledge on heatwaves risk and on checklists that must be followed in case of heatwave warnings. If necessary, additional staff can be called and activated to ensure further support to safe care. Therefore, during the 2018 heatwave, the municipality was far better prepared and equipped than in previous situations. Botkyrka is also supporting actions aiming to improve indoor thermal comfort and to create “cool-spots” in various areas of the city.

ClimApp is an ongoing European project to develop a mobile tool to translate climate service into personalized adaptation strategies to cope with thermal stress including heat and cold stress.

This study analysed the heat-related impact on mortality and morbidity for a rural population in Senegal. To evaluate the effect of the duration of heat exposure, we measured heat by the average apparent temperature (with effect of humidity) in a period preceding the event (medical visit, death) ranging from one, five, and ten to thirty days. We investigated the temperature-mortality or -morbidity relationship by vulnerable groups (children and elderly people) and by temperature type (daily minimum, maximum and average). Finally, we used three types of models: GLM, GAM and ARIMAX.

We found that, between 1984 and 2014, high heat resulted in an excess of mortality and medical diagnosed morbidity, especially among children and elderly people.

This research project was developed to fill specific gaps in evidence and data on access to cooling across cities in India, Pakistan, Cameroon and Indonesia. The research design is organised around three main research questions, each anchored in theoretical debates and bodies of academic scholarship:

i. Heat, Inequality and Gender

ii. Cool Infrastructures

iii. Thermal Practices, Needs and Capacities

Cool Infrastructures is a collaboration between research institutions in Scotland, Cameroon, Pakistan, India, Indonesia, France, Germany and Singapore.

The (SIETO) project has produced a national weather and climate risk assessment, focusing in particular on the vulnerabilities of different sectors to hydro-meteorological and climatological hazards. The risk assessment of the project was also used to develop the governance model for future risk assessments. The results of the project support the implementation of the National Climate Change Adaptation Plan 2022 and provide material for the national, EU and global level governance frameworks of weather and climate risk management.

The overall objective of the project is to produce new knowledge on the effects of high temperatures on human health in northern areas, and to provide cost-effective and socially acceptable solutions to adapt to climate change. The consortium project is genuinely multidisciplinary, covering natural, health, and social sciences and engineering, which enables versatile approaches to research questions. The project is coordinated by the University of Eastern Finland; other participants are Aalto University, Finnish Meteorological Institute, and Finnish Institute for Health and Welfare.

During the project, epidemiological analyses of health register data will be performed to evaluate the effects of heat and heatwaves on morbidity and mortality, and to identify susceptible population groups. Social and economic determinants of heat vulnerability will be evaluated using a questionnaire study, complemented with interviews and scenario work. A field study, including environmental and physiological measurements, will be conducted to create thermal comfort models for vulnerable population groups, and to evaluate the efficiency of local cooling methods. Climate modelling will be conducted to improve heat wave predictions for early warning systems and climate scenarios, and to calculate of cooling capacity needs in future climate.

In the last, integrative step of the project, health impact of heat in different climate, societal and adaptation scenarios will be assessed. Results will be used to guide policy makers on the scaling and targeting of adaptation measures. Central questions to be answered include:

• How will the burden of disease caused by heat change in Finland because of climate change?
• Which adaptation options are most efficient considering health effects, costs of the measures, and greenhouse gas emissions?
• How do the costs of adaptation and health effects affect the Finnish economy?

Although many studies have provided evidence for all-cause mortality attributed to extreme temperature across India, few studies have provided a systematic analysis of the association between all-cause mortality and temperature.

Objective: To estimate the risk associated with heat waves during two major heat waves of Nagpur occurred in 2010 and 2014.

Methods: The association between temperature and mortality was measured using a distributed lag non-linear model (DLNM) and the attributable deaths associated with the heat waves with forward perspective in the DLNM framework.

Results: From the ecological analysis, we found 580 and 306 additional deaths in 2010 and 2014, respectively. Moving average results also gave similar findings. DLNM results showed that the relative risk was 1.5 for the temperature above 45 °C; forward perspective analysis revealed that the attributable deaths during 2010 and 2014 were 505 and 376, respectively. Results from different methods showed that heat waves in different years had variable impacts for various reasons. However, all the results were consistent during 2010 and 2014; there were 30% and 14% extra-mortalities due to heat comparing to non-heat wave years.

Conclusion: We strongly recommend the city Government to implement the action plans based on this research outcome to reduce the risk from the heat wave in future.

The CAPS project aimed to reimagine Sydney’s bus shelters as Climate Adapted People Shelters through an open innovation design competition.

This document, Karachi Heatwave Management Plan, outlines what should happen before, during and after periods of extreme heat in Karachi. It sets out strategies that government and non-government agencies will adopt to prevent heat-related illnesses and deaths in Karachi and capacitate the public, particularly the most vulnerable residents, to take protective action. The Plan describes actions of implementation partners to ensure (1) information on weather conditions and heat health is timely and specific, (2) organizations have the capacity to respond according to their roles, and (3) strategies and actions enabling increase in effectiveness over time. In June 2015 Karachi City experienced a severe heatwave that caused over 1,200 deaths and over 50,000 cases of heat illness. The heatwave caught all levels of government and first responders off-guard, highlighting the need for inter-agency coordination, clarity in roles, and a well-publicized trigger to activate a planned response. To address this need and to prevent health impacts from future heatwaves as climate change intensifies, the Commissioner Office Karachi requested support from the Climate and Development Knowledge Network (CDKN) to develop a heatwave management plan. Karachi’s first Heatwave Management Plan is the result of a technical assistance project delivered by national and international experts between October 2016 and May 2017, working closely with the Commissioner Office and other stakeholders. The Plan will be subject to an annual performance review and updated versions will be available to implementation partners accordingly.

Climate change is increasing the frequency, intensity and duration of hot weather in South Asia. When it comes to health, the most detrimental impacts from extreme heat often occur in cities in developing nations, where large populations can become exposed and capacity to prepare and respond is low. In 2015 Karachi, Pakistan, experienced a severe heatwave that caused over 1,200 deaths and over 40,000 cases of heat illness. This heatwave caught government and first responders off-guard, highlighting the need for inter-agency coordination, clarity in roles, and a management plan.

How We Helped & Our Project’s Impacts

Between November 2016 and April 2017, and with funding from the Climate and Development Knowledge Network (CDKN), ESSA and The Urban Unit delivered Karachi’s first Heatwave Management Plan. The Plan builds on the analysis of data from the June 2015 event, as well as input gathered over several stakeholder outreach and engagement sessions. The Management Plan outlines what should happen before, during and after periods of extreme heat in Karachi. It sets out strategies that government and non-government agencies will take together to prevent heat-related illness and death in Karachi and equip the public, particularly the most vulnerable residents, to take protective action. The Management Plan was approved by the City, which has committed to resourcing it and making it operational. It includes an evaluation framework and proposed indicators, which will facilitate annual performance reviews.

As part of the work, ESSA also delivered a Regional Toolkit for Heatwave Management in Asian Cities. The Toolkit is intended for use by local authorities and stakeholders in other large Asian cities so the health risks of extreme heat could be integrated into disaster management, public health and land use planning. It includes guidance to develop and implement a heatwave management plan, examples highlighting cities’ experiences in preparing for and responding to heatwaves, templates, checklists and sample communications material. The chair of Pakistan’s National Disaster Management Authority is “hopeful that this Toolkit will serve as an important contribution in the efforts to make our cities resilient and sustainable.”

Western Sydney is hot and is set to get hotter as green fields make way for new housing developments; exacerbating what scientists call the urban heat island effect. Extreme heat causes major liveability and resilience problems with critical impacts for human health, infrastructure, emergency services and the natural environment.

Turn Down the Heat is a WSROC-led initiative that takes a collaborative, multi-sector approach to tackling urban heat in Western Sydney. The initiative is guided by the Turn Down the Heat Strategy (launched in December 2018). Developed with the input of 55 different organisations, the Strategy lays out a five-year plan for a cooler, more liveable and resilient future.

This study investigates an urban climate vulnerability in Cambodia by constructing an index to compare three different communes, Smach Meanchey, Daun Tong, and Steong Veng, located in the Khemarak Phoumin district, Koh Kong province. It is found that Daun Tong commune is the most vulnerable location among the three communes, followed by Steong Veng. Besides, vulnerability as Expected Poverty (VEP) is used to measure the vulnerability to poverty, that is, the probability of a household income to fall below the poverty line, as it captures the impact of shocks can be conducted in the cross-sectional study. It applies two poverty thresholds: the national poverty line after taking into account the inflation rate and the international poverty line defined by the World Bank, to look into its sensitivity. By using the national poverty line, the study reveals that more than one-fourth of households are vulnerable to poverty, while the international poverty threshold shows that approximately one-third of households are in peril. With low levels of income inequality, households are not highly sensitive to poverty; however, both poverty thresholds point out that the current urban poor households are more vulnerable than non-poor families.

The present work aims to investigate the characteristics of heat waves in Peninsular Malaysia based on the Excess Heat Factor (EHF) Index. This index was calculated based on the daily maximum and minimum temperatures over nine meteorological stations in Peninsular Malaysia during the period 2001 to 2010. The selected station is representing all of the states in Peninsular Malaysia. Statistical analysis found that the highest of the EHF happened at the Kuala Lumpur station in 2002 with an index of 9.1°C² and the lowest was in Alor Setar in 2006 with an index of 0.1°C². The EHF moderate was found at Kuantan with an index of 4.2°C². Moreover, the longest heat wave with 24 days has happened in Ipoh, Perak with amplitude of 29.4°C – 33.0°C. Most of the heat wave characterized in Malaysia occurred during the El Nino events especially moderate El Nino in 2002 until 2005, and 2010. The Southeast, northeast and west part of Malaysia experience the highest average heat wave activity. These results indicated that the heat wave conditions in Peninsular Malaysia are anxious and this requires immediate investigation because it has a direct impact on agriculture, particularly health, economic, and human being.

South Sudan is at risk from the impact of climate change. This paper reviews the climate change issues faced by South Sudan, and the strategy as outlined to the United Nations. The author argues that the policy overlooks a key potential cause of future morbidity and mortality: increased ambient temperatures, particularly in urban centres due to the urban heat island effect.  The capital is especially susceptible to heat-related mortality as it faces a ‘triple threat’: rapidly rising temperatures, an at-risk population profile, and inadequate planning for the pressures of urbanisation. Four low-cost, evidence-based recommendations are given to mitigate the impact of heatwaves on human health, and it is concluded that South Sudan has great potential to become a regional leader in heat resilience.

Depuis 2009, l’Etat de Vaud dispose d’un plan canicule cantonal. Il vise à protéger la santé de la population des effets des vagues de chaleur, à limiter la surcharge du système sanitaire et à coordonner les différents acteurs appelés à intervenir dans ce type de situation. Ainsi, l’Etat définit des mesures de prévention collectives et individuelles et les transmet à la population ainsi qu’aux collectivités publiques et privées. Il prend en compte les situations sanitaire et météorologique ainsi que les prévisions, coordonne les acteurs (partenaires du secteur socio-sanitaire) et prend les décisions nécessaires pour prévenir ou atténuer les atteintes à la santé dues à la canicule.

Suite à une mise en garde de la médecin cantonale, la Ville de Genève active dès samedi 8 août 2020 son Plan canicule en faveur des aîné-e-s et des personnes sans-abri. Un suivi régulier de celles et ceux qui se sont inscrit-e-s auprès du Service social est assuré. Cette année, ce dispositif est particulièrement important compte tenu du contexte sanitaire encore marqué par le COVID-19.

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Following a warning from the cantonal doctor, the City of Geneva is activating its heatwave plan for the elderly and homeless from Saturday August 8, 2020. Regular follow-up of those who have registered with the Social Service is ensured. This year, the plan is particularly important given the health context still marked by COVID-19.

The pilot project envisages the introduction of Forecast-based Action (FbA) in Kyrgyzstan and Tajikistan to reduce the humanitarian impact of the increasing number extreme weather events on the population. The focus is on the development of Early Action Protocols (EAPs) in order to mitigate the impact from cold waves and heat waves in rural parts of Kyrgyzstan and Tajikistan. Through these EAPs, the Red Crescent Societies of both countries will be able to draw on the FbA by the DREF fund of the IFRC in Geneva whenever weather forecasts reach critical thresholds for approaching natural disasters. These funds can be used to carry out predefined short-term measures in affected communities. People are thus better protected: Families can bring their belongings to safety, protect their livestock and better cushion the harmful consequences of extreme weather conditions. In this way, extreme weather does not throw them back again and again in their economic and health development.

World Weather Attribution (WWA) is an international effort to analyse and communicate the possible influence of climate change on extreme weather events, such as storms, extreme rainfall, heatwaves, cold spells, and droughts.

Recognising society’s interest in reducing the human, economic, and environmental costs of weather-related disasters, WWA delivers timely and scientifically reliable information on how extreme weather may be affected by climate change.

Recent studies have quantified the impact of climate change on the likelihood and intensity of bushfires, heatwaves and storms.

Through extensive media engagement – including the Guardian, the Daily Mail, the Times, Scientific American, CBS, BBC and many more – WWA has helped to change the global conversation around climate change, influencing adaptation strategies and paving the way for new sustainability litigation. In 2020, climate change attribution was named one of MIT Tech Review’s top ten breakthrough technologies.

WWA is a partnership of:

• Environmental Change Institute, University of Oxford (ECI)
• Royal Netherlands Meteorological Institute (KNMI)
• Laboratoire des Sciences du Climat et de l’Environment (LSCE)
• University of Princeton
• National Center for Atmospheric Research (NCAR)
• Red Cross Red Crescent Climate Centre (The Climate Centre).

This report proposes a new objective definition for heatwaves and heatwave severity that may be applied to any location in Australia, or for that matter the world. Using this definition, it is now possible to compare severe and extreme heat events across time and space. A heatwave intensity index has been created by combining measures of excess heat, the long-term temperature anomaly characterised by each location’s unique climatology of heat, and heat stress, the short-term temperature anomaly measuring recent thermal acclimatisation. These two measures have been factored together to create the excess heat factor (EHF).

The Australian community understands that heatwaves are a common summertime experience and rarely anticipates significant human health risk. This is borne out by the cumulative distribution function of EHF which indicates that most heatwaves are of low intensity. It is only rarely that heatwaves become severe enough to impact vulnerable people and rarer still that they exhibit extreme intensities capable of causing widespread health problems. Generalised extreme value theory has been used to motivate a severity threshold for the EHF, a level at which the heatwave may be considered to be severe. Case studies of Australian and international severe and extreme heatwaves are examined with the aid of EHF intensity, demonstrating the utility of the index. The methodology applied in the development of this heatwave index appeals to our common understanding of heatwave impact. Additionally, the objective statistical techniques employed here are easily extended to permit the development of a robust coldwave index, the logical extension to coldwaves being also proposed in this report. EHF can be used to appropriately alert communities according to the intensity of impending heatwaves, whilst climates trends and projections of intensity, frequency, spatial extent and length can also be considered for Australian and international locations.

Cool Streets is an initiative out of Sydney, Australia, to empower communities to cool the planet, one street at a time. Cool Streets combines scientific research and public engagement, working with local communities to implement effective street tree plantings that provide shade in heat-affected urban areas and reduce CO2 emissions.

This strategy has been prepared to increase awareness and facilitate a broader and more coordinated response to the challenges of urban heat in Western Sydney.

As part of California’s Fourth Climate Change Assessment, Four Twenty Seven is working with project partners to develop a tool that will inform long-term planning efforts to communicate the urgency of and mitigate the public health impacts of increasing extreme heat events across the state.

Las islas de calor o islas térmicas se refieren al patrón térmico que se encuentra en sitios altamente urbanizados en el centro o en la periferia de las ciudades. Son generadas por la pérdida de cobertura vegetal la cual es substituida por superficies impermeables como las carreteras de asfalto, edificios de concreto, ladrillo y otros materiales de construcción, dando como resultado el cambio en el balance hídrico y radiativo superficial, generando, por lo tanto, aumentos en la temperatura de las áreas urbanizadas. La identificación de estas islas térmicas permite desarrollar medidas de adaptación en sitios puntuales de la ciudad. Con el objetivo de conocer el comportamiento de las islas de calor en el Cantón de Curridabat se realizó un análisis de las temperaturas de los últimos cuatro años obtenidas de imágenes satelitales LandSat 8. Los resultados obtenidos reflejan un patrón de calentamiento diferenciado dependiendo del nivel de urbanización y la presencia de vegetación. Así mismo, se señala la relación de estas islas de calor con diferentes grupos vulnerables de la población y la necesidad de tomar medidas considerando la situación actual y futura con los cambios probables del clima. Análisis relacionados con la vegetación remanente en el cantón muestran la importancia de tomar acciones sobre parches de bosques en propiedades privadas y la atención al espacio verde público por habitante que muestra una situación de desigualdad dependiendo del distrito en que se ubique. Finalmente se propone la necesidad de desarrollar una definición para bosque urbano, y de acciones para atender principalmente todo lo relacionado a la adaptación al cambio climático basada en ecosistemas en la ciudad.

HEATCOST will quantify health risks attributable to heat and air pollution (with a particular focus on air pollution from wildfires) in main world regions under selected climate scenarios and socioeconomic pathways.

The project capitalizes on the H2020 project Exhaustion.eu.

The researtch is co-designed with stakeholder partners engaged in development and implementation of adaptation measures. HEATCOST will increase synergies between teams across partner countries and stakeholder organizations, fostering a new climate and environmental health knowledge platform based on a transdisciplinary and end-user focused approach.

HEATCOST quantifies global current and future changes in cardiopulmonary (CPD) mortality and morbidity due to extreme heat and air pollution (including from wildfires) under selected climate scenarios, while assessing a diverse set of adaptation mechanisms and strategies, and estimates the associated costs. Extreme heat increases the rates of death (mortality) and can exacerbate a range of diseases (morbidity). In particular, heat increases mortality and morbidity for cardiovascular and respiratory diseases (CVD and RD), which together constitute cardiopulmonary diseases (CPD). The risk of wildland fires increases during periods of extreme heat and decreasing precipitation, and can cause intense air pollution. Synergistic effects of extreme heat and air pollution (O3 and PM_2.5) on CPD outcomes have been identified. Complex interactions act to exacerbate the effects of extreme events on CPD outcomes. The health risk varies by region, population vulnerability, the built environment and other factors. Populations at highest risk include older adults, children, socially isolated individuals, and individuals with chronic diseases. Health effects due to heat and air pollution is largely preventable to the extent that adaptation measures can be tailored to alleviate contextual and individual vulnerability factors for vulnerable populations.

To assess future health risks, HEATCOST will review the rich literature on the exposure-response relationships between health effects and non-optimum temperature, including for EU, USA, and China, and establish exposure projections for extreme heat and air pollution based on updated and advanced modelling and downscaling efforts. HEATCOST includes a diverse set of adaptation mechanisms, calculates the associated economic and social costs and identifies effective strategies for minimizing adverse impacts. The results will be disseminated to the general public and to decision- and policy-makers.

HEATCOST will address key knowledge gaps listed by the IPCC and USGCRP: published health risk projections do not adequately reflect the adaptation to a changing climate; there is a lack of knowledge and appropriate models regarding possible interactive effects of extreme heat and air pollution; and the fundamental gap between the approach of global models and observational data for quantitative projections of the costs associated with heat, air pollution and health risks.

The High Impact Weather project (HIWeather) is a ten-year activity within the WMO’s World Weather Research Programme. It serves to promote cooperative international research to achieve a dramatic increase in resilience to high impact weather, worldwide, through improving forecasts for timescales of minutes to two weeks and enhancing their communication and utility in social, economic and environmental applications.”

Heat has the potential to become one of the most significant public health impacts of climate change in the coming decades. Increases in temperature have been linked to both increasing mortality and morbidity. Cities have been recognized as areas of particular vulnerability to heat’s impacts on health, and marginalized groups, such as the poor, appear to have higher heat-related morbidity and mortality. Little research has examined the heat vulnerability of urban informal settlements residents in Africa, even though surface temperatures across Africa are projected to increase at a rate faster than the global average.

This paper addresses this knowledge gap through a mixed-methods analysis of the heat-health vulnerability of informal settlement residents in Dar es Salaam, Tanzania. The heat exposure, sensitivity and adaptive capacity of informal settlement residents were assessed through a combination of climate analyses, semi-structured interviews with local government actors and informal settlement residents, unstructured interviews with health sector respondents, a health impacts literature review, and a stakeholder engagement workshop.

The results suggest that increasing temperatures due to climate change will likely be a significant risk to human health in Dar es Salaam, even though the city does not reach extreme temperature conditions, because informal settlement residents have high exposure, high sensitivity and low adaptive capacity to heat, and because the heat-health relationship is currently an under-prioritized policy issue. While numerous urban planning approaches can play a key role in increasing the resilience of citizens to heat, Dar es Salaam’s past and current growth and development patterns greatly complicate the implementation and enforcement of such approaches. For African cities, the findings highlight an urgent need for more research on the vulnerability and resilience of residents to heat-health impacts, because many African cities are likely to present similar characteristics to those in Dar es Salaam that increase resident’s vulnerability.

La ciudad de La Plata y el Gran La Plata presentan una notoria vulnerabilidad ante eventos hidrometeorológicos severos, que se ve reflejada en el impacto que producen los mismos en la calidad de vida de sus habitantes, daños a bienes espacios públicos y privados. Para una adecuada Gestión Integral del Riesgo de Desastres en el Partido de La Plata, es necesario y prioritario establecer lineamientos para la Gestión de Emergencias, ya sean estas de origen Natural o Tecnológico. Este Plan General de Gestión de Emergencias -establecido a principios de 2014- tiene los siguientes objetivos:

Objetivo General:

• Reconocer las amenazas de origen natural como las provocadas por la actividad de los seres humanos (tecnológicas).

Objetivos Específicos:

• Identificar los actores y sectores involucrados en la gestión de emergencias.
• Establecer roles y funciones para la gestión de emergencias.
• Profundizar las estrategias de coordinación entre los organismos municipales, provinciales y nacionales involucrados en acciones de manejo de crisis (advertencia/alarma y respuesta) y rehabilitación ante un evento adverso.
• Promover actividades de prevención y preparación comunitaria.
• Indicar a la población las acciones a tomar Un Plan de Contingencia es un conjunto de procedimientos específicos que presentan una estructura estratégica y operativa contribuyentes a controlar una situación de emergencia y minimizar sus consecuencias negativas.

Working people are particularly vulnerable to environmental heat. We will study the complex threat heat exposures pose to human health, wellbeing and productivity in working populations in Singapore and other tropical countries (Vietnam and Cambodia), and to identify sustainable preventive policies and actions that can reduce these impacts.

The Climate and Health Program (CLIMA) of the Barcelona Institute for Global Health (ISGlobal) is working to build a prototype of heat health early warning system for Europe. This unified pan-European service will be adapted to all European societies by using daily meteorological and mortality data to account for the regional differences in human vulnerability and societal adaptation to climate variability and change. The development of this epidemiological surveillance tool is aimed at contributing to a better monitoring and forecasting system of temperature-related health risks. The system will provide more realistic warnings, raising awareness and support public health management and decision making.

In advance of a heatwave affecting Hanoi from 18-21 July 2019, Red Cross cooling centres and other early actions were tested in an attempt reduce the occurrence of heat-related symptoms in vulnerable populations.

Although epidemiological studies have reported associations between mortality and both ambient air pollution and air temperature, it remains uncertain whether the mortality effects of air pollution are modified by temperature and vice versa. Moreover, little is known on the interactions between ultrafine particles (diameter75th percentile), an increase of 10,000 particles/cm(3) in PNC corresponded to a 2.51% (95% CI: 0.39%, 4.67%) increase in cardiovascular mortality, which was significantly higher than that on days with low air temperatures (<25th percentile) [-0.18% (95% CI: -0.97%, 0.62%)]. On days with high air pollution (>50th percentile), both heat- and cold-related mortality risks increased. CONCLUSION: Our findings showed that high temperature could modify the effects of air pollution on daily mortality and high air pollution might enhance the air temperature effects.

Exercising in the heat often results in an excessive increase in body core temperature, which can be detrimental to health and endurance performance. Research in recent years has shifted toward the optimum temperature at which drinks should be ingested. The ingestion of cold drinks can reduce body core temperature before exercise but less so during exercise. Temperature of drinks does not seem to have an effect on the rate of gastric emptying and intestinal absorption. Manipulating the specific heat capacity of a solution can further induce a greater heat sink. Ingestion of ice slurry exploits the additional energy required to convert the solution from ice to water (enthalpy of fusion). Body core temperature is occasionally observed to be higher at the point of exhaustion with the ingestion of ice slurry. There is growing evidence to suggest that ingesting ice slurry is an effective and practical strategy to prevent excessive rise of body core temperature and improve endurance performance. This information is especially important when only a fixed amount of fluid is allowed to be carried, often seen in some ultra-endurance events and military operations. Future studies should evaluate the efficacy of ice slurry in various exercise and environmental conditions.

Humans maintain a relatively constant core temperature through the dynamic balance between endogenous heat production and heat dissipation to the surrounding environment. In response to metabolic or environmental disturbances to heat balance, the autonomic nervous system initiates cutaneous vasodilation and eccrine sweating to facilitate higher rates of dry (primarily convection and radiation) and evaporative transfer from the body surface; however, absolute heat losses are ultimately governed by the properties of the skin and the environment. Over the duration of a heat exposure, the cumulative imbalance between heat production and heat dissipation leads to body heat storage, but the consequent change in core temperature, which has implications for health and safety in occupational and athletic settings particularly among certain clinical populations, involves a complex interaction between changes in body heat content and the body’s morphological characteristics (mass, surface area, and tissue composition) that collectively determine the body’s thermal inertia. The aim of this review is to highlight the biophysical aspects of human core temperature regulation by outlining the principles of human energy exchange and examining the influence of body morphology during exercise and environmental heat stress. An understanding of the biophysical factors influencing core temperature will enable researchers and practitioners to better identify and treat individuals/populations most vulnerable to heat illness and injury during exercise and extreme heat events. Further, appropriate guidelines may be developed to optimize health, safety, and work performance during heat stress.

Under normothermic, resting conditions, humans dissipate heat from the body at a rate approximately equal to heat production. Small discrepancies between heat production and heat elimination would, over time, lead to significant changes in heat storage and body temperature. When heat production or environmental temperature is high the challenge of maintaining heat balance is much greater. This matching of heat elimination with heat production is a function of the skin circulation facilitating heat transport to the body surface and sweating, enabling evaporative heat loss.

These processes are manifestations of the autonomic control of cutaneous vasomotor and sudomotor functions and form the basis of this review. We focus on these systems in the responses to hyperthermia. In particular, the cutaneous vascular responses to heat stress and the current understanding of the neurovascular mechanisms involved. The available research regarding cutaneous active vasodilation and vasoconstriction is highlighted, with emphasis on active vasodilation as a major responder to heat stress. Involvement of the vasoconstrictor and active vasodilator controls of the skin circulation in the context of heat stress and nonthermoregulatory reflexes (blood pressure, exercise) are also considered. Autonomic involvement in the cutaneous vascular responses to direct heating and cooling of the skin are also discussed. We examine the autonomic control of sweating, including cholinergic and noncholinergic mechanisms, the local control of sweating, thermoregulatory and nonthermoregulatory reflex control and the possible relationship between sudomotor and cutaneous vasodilator function. Finally, we comment on the clinical relevance of these control schemes in conditions of autonomic dysfunction.

Objective: To present best-practice recommendations for the prevention, recognition, and treatment of exertional heat illnesses (EHIs) and to describe the relevant physiology of thermoregulation.

Background: Certified athletic trainers recognize and treat athletes with EHIs, often in high-risk environments. Although the proper recognition and successful treatment strategies are well documented, EHIs continue to plague athletes, and exertional heat stroke remains one of the leading causes of sudden death during sport. The recommendations presented in this document provide athletic trainers and allied health providers with an integrated scientific and clinically applicable approach to the prevention, recognition, treatment of, and return-to-activity guidelines for EHIs. These recommendations are given so that proper recognition and treatment can be accomplished in order to maximize the safety and performance of athletes.

Recommendations: Athletic trainers and other allied health care professionals should use these recommendations to establish onsite emergency action plans for their venues and athletes. The primary goal of athlete safety is addressed through the appropriate prevention strategies, proper recognition tactics, and effective treatment plans for EHIs. Athletic trainers and other allied health care professionals must be properly educated and prepared to respond in an expedient manner to alleviate symptoms and minimize the morbidity and mortality associated with these illnesses.

Patient coolingtime can impact upon the prognosis of heat illness. Although ice-cold-water immersion will rapidly extract heat, access to ice or cold water may be limited in hot climates. Indeed, some have concerns regarding the sudden cold-water immersion of hyperthermic individuals, whereas others believe that cutaneous vasoconstriction may reduce convective heat transfer from the core. It was hypothesized that warmer immersion temperatures, which induce less powerful vasoconstriction, may still facilitate rapid cooling in hyperthermic individuals.

Although the acquisition of heat acclimation (HA) is well-documented, less is known about HA decay (HAD) and heat re-acclimation (HRA). The available literature suggests 1 day of HA is lost following 2 days of HAD. Understanding this relationship has the potential to impact upon the manner in which athletes prepare for major competitions, as a HA regimen may be disruptive during final preparations (i.e., taper).

The aim of this meta-analysis was to evaluate the effectiveness of heat acclimatization (HA) on time trial (TT) performance, maximum oxygen uptake (VO2max), exercise heart rate (HRE), time trials heart rate (HRTT), maximal heart rate (HRM), core temperature (TC), mean skin temperature (TS), thermal comfort (TComf), plasma volume (PV), blood lactate concentration and rate of perceived exertion (RPE). Cochrane-CENTRAL, EMBASE, CINAHL and PubMed databases and reference lists of included studies were searched for randomized controlled trials that investigated the efficacy of HA in athletes. Data were then extracted from the entered studies for analyses. A total of 11 randomised controlled trials (215 participants; mean age, 26.09 years; 91% men) were included after screening of 508 titles and abstracts and 19 full-text articles. The pooled standard mean difference (SMD) between the HA and non-HA groups were 0.50 (95% CI: 0.03 to 0.97, p = 0.04) for TT performance and 1 (95% CI: 1 to 2, p = 0.007) for HRTT. The pooled mean difference (MD) between the HA and non-HA groups were -7 (95% CI: -13 to -1, p = 0.03) for HRM. The changes in TComf and RPE were too small to be meaningful. There were no significant differences between the HA and non-HA groups for VO2max, HRE, TC, TS, PV and blood lactate concentration (all p > 0.05). This meta-analysis implies that HA may improve tolerance to discomfort during heat exposure, but may not necessarily improve the associated physiological markers of improved performance.

The Tokyo Olympics and Paralympic games in 2020 will be held in hot and humid conditions. Heat acclimation (in a climatic chamber) or heat acclimatization (natural environment) is essential to prepare the (endurance) athletes and reduce the performance loss associated with work in the heat. Based on the 1990–2018 hourly meteorological data of Tokyo and the derived wet bulb globe temperature (WBGT) (Liljegren method), Heat Index and Humidex, it is shown that the circumstances prior to the games are likely not sufficiently hot to fully adapt to the heat. For instance, the WBGT 2 weeks prior to the games at the hottest moment of the day (13:00 h) is 26.4 ± 2.9∘C and 28.6 ± 2.8∘C during the games. These values include correction for global warming. The daily variation in thermal strain indices during the Tokyo Olympics (WBGT varying by 4∘C between the early morning and the early afternoon) implies that the time of day of the event has a considerable impact on heat strain. The Paralympics heat strain is about 1.5∘C WBGT lower than the Olympics, but may still impose considerable heat strain since the Paralympic athletes often have a reduced ability to thermoregulate. It is therefore recommended to acclimate about 1 month prior to the Olympics under controlled conditions set to the worst-case Tokyo climate and re-acclimatize in Japan or surroundings just prior to the Olympics.

This review evaluated the effects of precooling via cold water immersion (CWI) and ingestion of ice slurry/slushy or crushed ice (ICE) on endurance performance measures (e.g. time-to-exhaustion and time trials) and psychophysiological parameters (core [Tcore] and skin [Tskin] temperatures, whole body sweat [WBS] response, heart rate [HR], thermal sensation [TS], and perceived exertion [RPE]). Twenty-two studies were included in the meta-analysis based on the following criteria: (i) cooling was performed before exercise with ICE or CWI; (ii) exercise longer than 6 min was performed in ambient temperature ≥26°C; and (iii) crossover study design with a non-cooling passive control condition. CWI improved performance measures (weighted average effect size in Hedges’ g [95% confidence interval] + 0.53 [0.28; 0.77]) and resulted in greater increase (ΔEX) in Tskin (+4.15 [3.1; 5.21]) during exercise, while lower peak Tcore (-0.93 [-1.18; -0.67]), WBS (-0.74 [-1.18; -0.3]), and TS (-0.5 [-0.8; -0.19]) were observed without concomitant changes in ΔEX-Tcore (+0.19 [-0.22; 0.6]), peak Tskin (-0.67 [-1.52; 0.18]), peak HR (-0.14 [-0.38; 0.11]), and RPE (-0.14 [-0.39; 0.12]). ICE had no clear effect on performance measures (+0.2 [-0.07; 0.46]) but resulted in greater ΔEX-Tcore (+1.02 [0.59; 1.45]) and ΔEX-Tskin (+0.34 [0.02; 0.67]) without concomitant changes in peak Tcore (-0.1 [-0.48; 0.28]), peak Tskin (+0.1 [-0.22; 0.41]), peak HR (+0.08 [-0.19; 0.35]), WBS (-0.12 [-0.42; 0.18]), TS (-0.2 [-0.49; 0.1]), and RPE (-0.01 [-0.33; 0.31]). From both ergogenic and thermoregulatory perspectives, CWI may be more effective than ICE as a precooling treatment prior to exercise in the heat.

Exercise increases core body temperature (Tc), which is necessary to optimise physiological processes. However, excessive increase in Tc may impair performance and places participants at risk for the development of heat-related illnesses. Cooling is an effective strategy to attenuate the increase in Tc. This meta-analysis compares the effects of cooling before (precooling) and during exercise (percooling) on performance and physiological outcomes.

Although it is well understood that dehydration can have a major impact on exercise performance and thermoregulatory physiology, the potential for interactions between female sex hormone influences and the impact of dehydration on these variables is poorly understood. Female reproductive hormonal profiles over the course of the menstrual cycle have significant influences on thermoregulatory and volume regulatory physiology. Increased insight into the interactions among dehydration and menstrual cycle hormonal influences may have important implications for safety, nutritional recommendations, as well as optimal mental and physical performance. The purpose of this review is to summarize what is known in this area and highlight the areas that will be important for future work.

Exercising in the heat induces thermoregulatory and other physiological strain that can lead to impairments in endurance exercise capacity. The purpose of this consensus statement is to provide up-to-date recommendations to optimise performance during sporting activities undertaken in hot ambient conditions. The most important intervention one can adopt to reduce physiological strain and optimise performance is to heat acclimatise. Heat acclimatisation should comprise repeated exercise-heat exposures over 1–2 weeks. In addition, athletes should initiate competition and training in a euhydrated state and minimise dehydration during exercise. Following the development of commercial cooling systems (eg, cooling-vest), athletes can implement cooling strategies to facilitate heat loss or increase heat storage capacity before training or competing in the heat. Moreover, event organisers should plan for large shaded areas, along with cooling and rehydration facilities, and schedule events in accordance with minimising the health risks of athletes, especially in mass participation events and during the first hot days of the year. Following the recent examples of the 2008 Olympics and the 2014 FIFA World Cup, sport governing bodies should consider allowing additional (or longer) recovery periods between and during events, for hydration and body cooling opportunities, when competitions are held in the heat.

Exertional heat illness can affect athletes during high-intensity or long-duration exercise and result in withdrawal from activity or collapse during or soon after activity. These maladies include exercise associated muscle cramping, heat exhaustion, or exertional heatstroke. While certain individuals are more prone to collapse from exhaustion in the heat (i.e., not acclimatized, using certain medications, dehydrated, or recently ill), exertional heatstroke (EHS) can affect seemingly healthy athletes even when the environment is relatively cool. EHS is defined as a rectal temperature greater than 40°C accompanied by symptoms or signs of organ system failure, most frequently central nervous system dysfunction. Early recognition and rapid cooling can reduce both the morbidity and mortality associated with EHS. The clinical changes associated with EHS can be subtle and easy to miss if coaches, medical personnel, and athletes do not maintain a high level of awareness and monitor at-risk athletes closely. Fatigue and exhaustion during exercise occur more rapidly as heat stress increases and are the most common causes of withdrawal from activity in hot conditions. When athletes collapse from exhaustion in hot conditions, the term heat exhaustion is often applied. In some cases, rectal temperature is the only discernable difference between severe heat exhaustion and EHS in on-site evaluations. Heat exhaustion will generally resolve with symptomatic care and oral fluid support. Exercise associated muscle cramping can occur with exhaustive work in any temperature range, but appears to be more prevalent in hot and humid conditions. Muscle cramping usually responds to rest and replacement of fluid and salt (sodium). Prevention strategies are essential to reducing the incidence of EHS, heat exhaustion, and exercise associated muscle cramping.

In an effort to improve the emergency health and safety best practices and policies in youth sport, this document was developed to serve as a road map for policy and procedure recommendations. It addresses the most common conditions resulting in sudden death and outlines recommended policies and procedures designed to improve youth sport safety.

This paper reviews frequently used outdoor thermal comfort indices in hot-humid regions and neutral thermal ranges to offer guidelines for selecting an appropriate index for hot-humid regions. An overview of the development of outdoor thermal comfort (OTC) indices based on type of approach, from linear equation approach – to adaptive thermal comfort model – is provided and the advantages and limitations of each index are presented. Subjective neutral ranges from 31 studies conducted in hot-humid regions were assessed on the basis of geographical location, Köppen-Geiger’s climate classification, parameters, a survey method, instrumentation set-up, respondent profile, method of analysis, neutral range, and coefficient of determinations in order to gain an understanding of their deviations. The review of 31 calibration studies of (m)PET’s, (OUT_)SET*’s and UTCI’s neutral ranges indicated that the lower threshold of (m)PET’s neutral range needs to be lowered, while the lower threshold of (OUT_)SET*’s and UTCI’s ranges should be raised. The appropriateness of (OUT_)SET*’s thermal range for hot climates was proven by its full-coverage neutral range in the evaluation. However, the accurate response to ambient thermal conditions was determined by the advancement of a human thermoregulatory model.

Health effects of heat waves with high baseline temperatures in areas such as India remain a critical research gap. In these regions, extreme temperatures may affect the underlying population’s adaptive capacity; heat wave alerts should be optimized to avoid continuous high alert status and enhance constrained resources, especially under a changing climate. Data from registrars and meteorological departments were collected for four communities in Northwestern India. Propensity Score Matching (PSM) was used to obtain the relative risk of mortality and number of attributable deaths (i.e., absolute risk which incorporates the number of heat wave days) under a variety of heat wave definitions (n = 13) incorporating duration and intensity. Heat waves’ timing in season was also assessed for potential effect modification. Relative risk of heat waves (risk of mortality comparing heat wave days to matched non-heat wave days) varied by heat wave definition and ranged from 1.28 [95% Confidence Interval: 1.11–1.46] in Churu (utilizing the 95th percentile of temperature for at least two consecutive days) to 1.03 [95% CI: 0.87–1.23] in Idar and Himmatnagar (utilizing the 95th percentile of temperature for at least four consecutive days). The data trended towards a higher risk for heat waves later in the season. Some heat wave definitions displayed similar attributable mortalities despite differences in the number of identified heat wave days. These findings provide opportunities to assess the “efficiency” (or number of days versus potential attributable health impacts) associated with alternative heat wave definitions. Findings on both effect modification and trade-offs between number of days identified as “heat wave” versus health effects provide tools for policy makers to determine the most important criteria for defining thresholds to trigger heat wave alerts.

The aim of this study was to assess the relationship between environmental temperatures and occupational injuries (OIs) in construction workers (CWs) from a subalpine region of North-Eastern Italy. Data about OIs from 2000 to 2013, and daily weather for the specific site of the events were retrieved. Risk for daily OIs was calculate through a Poisson regression model. Estimated daily incidence for OIs was 5.7 (95%CI 5.5-5.8), or 2.8 OIs/10,000 workers/d (95%CI 2.7-2.9), with higher rates for time periods characterized by high temperatures (daily maximum ≥35°C), both in first 2 d (3.57, 95%CI 3.05-4.11) and from the third day onwards (i.e. during Heat Waves: 3.43, 95%CI 3.08-3.77). Higher risk for OIs was reported in days characterized temperatures ≥95th percentile (OR 1.145, 95%CI 1.062-1.235), summer days (daily maximum ≥25°C , OR 1.093, 95%CI 1.042-1.146). On the contrary, no significant increased risk was found for OIs having a more severe prognosis (≥40 d or more; death). In conclusion, presented findings recommend policymakers to develop appropriate procedures and guidelines, in particular aimed to improve the compliance of younger CWs towards severe-hot daily temperatures.

Urban heat island is the more documented phenomenon of climate change. Information on the magnitude and the characteristics of the canopy layer urban heat island measured in 101 cities and regions of Asia and Australia and collected through 88 scientific articles, are compiled, evaluated and presented. Data are classified in several clusters according to the experimental protocol used and the type of statistical information reported regarding the magnitude of the urban heat island. Results and detailed analysis are given for each defined cluster. Very significant differences on the UHI intensity are found between the clusters and analyzed in detail. The detailed impact of the main weather parameters and conditions on the magnitude of the UHI is also investigated. The specific influence of anthropogenic thermal fluxes as well as of the urban morphological and construction characteristics to UHI is thoroughly examined. The relation between the UHI intensity and the city size is assessed and global relationships of UHI as a function of the urban population are proposed. The seasonal and diurnal variability of the UHI is analyzed and discussed while specific features and conditions like the urban heat island characteristics in coastal cities and the existence of daytime cool islands are explored. Finally, the impact of the selected reference station and its characteristics is considered.

Future heat stress under six future global warming (ΔT GW ) scenarios (IPCC RCP8.5) in an Asian megacity (Osaka) is estimated using a regional climate model with an urban canopy and air-conditioning (AC). An urban heat ‘stress’ island is projected in all six scenarios (ΔT GW = +0.5 to +3.0 °C in 0.5 °C steps). Under ΔT GW = +3.0 °C conditions, people outdoors experience ‘extreme’ heat stress, which could result in dangerously high increases in human body core temperature. AC-induced feedback increases heat stress roughly linearly as ΔT GW increases, reaching 0.6 °C (or 12% of the heat stress increase). As this increase is similar to current possible heat island mitigation techniques, this feedback needs to be considered in urban climate projections, especially where AC use is large.

The Urban Heat Island (UHI) effect describes the phenomenon whereby cities are generally warmer than surrounding rural areas. Traditionally, temperature monitoring sites are placed outside of city centres, which means that point measurements do not always reflect the true air temperature of urban centres, and estimates of health impacts based on such data may under-estimate the impact of heat on public health. Climate change is likely to exacerbate heatwaves in future, but because climate projections do not usually include the UHI, health impacts may be further underestimated. These factors motivate a two-dimensional analysis of population weighted temperature across an urban area, for heat related health impact assessments, since populations are typically densest in urban centres, where ambient temperatures are highest and the UHI is most pronounced. We investigate the sensitivity of health impact estimates to the use of population weighting and the inclusion of urban temperatures in exposure data.

A majority of high profile international sporting events, including the coming 2020 Tokyo Olympics, are held in warm and humid conditions. When exercising in the heat, the rapid rise of body core temperature (T c ) often results in an impairment of exercise capacity and performance. As such, heat mitigation strategies such as aerobic fitness (AF), heat acclimation/acclimatization (HA), pre-exercise cooling (PC) and fluid ingestion (FI) can be introduced to counteract the debilitating effects of heat strain. We performed a meta-analysis to evaluate the effectiveness of these mitigation strategies using magnitude-based inferences.

A high number of women report experiencing intimate partner violence (IPV). It is of utmost importance to identify possible factors that precipitate IPV and incorporate them into police protocols for evaluating IPV risk. Scientific evidence shows that environmental temperature is associated with a risk of violent behavior. OBJECTIVES: To analyze the effect and impact of heat waves on the risk of IPV. METHODS: Ecological, longitudinal time series study. The dependent variables are: intimate partner femicides (IPF), reports of IPV and 016 IPV telephone help line calls in the Community of Madrid from 05/01 to 09/30 in the years 2008-2016. The principal independent variable is the daily maximum temperature in Celsius (Tmax) above the heat wave threshold of 34 degrees C. A binomial negative regression was used for calls and reports and a Poisson regression was used for IPF. The attributable risk among those exposed (AR%) and the number of attributable cases was calculated for each variable. RESULTS: The risk of IPF increased three days after the heat wave, [RR(IC95%):1.40(1.00-1.97)], police reports of IPV increased one day after [RR (IC95%):1.02(1.00-1.03) and help line calls increased five days after [RR(IC95%):1.01(1.00-1.03)]. The AR% was 28.8% (IC95%: 0.3%-49.2%) for IPF, 1.7% (IC95%:0.3%-3.1%) for police reports and 1.43% (IC95:0.1%;2.8%) for help line calls. CONCLUSIONS: Our results suggest that heat waves are associated with an increase in IPV. The effect of an increase in IPV is delayed in time, with differences according to the violence indicators analyzed.

Heat-related illness (HRI), injury, and death among oil spill cleanup responders can be prevented through training and educational materials. This study assessed heat-related training and educational materials currently used and desired by oil spill cleanup responders. A needs assessment was completed by 65 oil spill cleanup responders regarding their occupational heat-related experiences and training needs. Oil spill cleanup responders reported participating on average in 37 oil spill cleanup activities per year. Most reported experiencing additional HRI risk factors, such as high temperatures and humidity and wearing personal protective equipment and clothing ensembles, respirators, and personal flotation devices. Many reported experiencing symptoms of HRI (profuse sweating, headache, weakness, decreased urine output, high body temperatures) and experiencing heat exhaustion. Although multiple prevention controls were reported, only 1 in 4 reported using an acclimatization plan. The most common training delivery method and education received included just-in-time training and printed materials. The most desirable future training delivery methods and education products were smartphone or tablet applications, printed materials, and online training. Findings from this study may be beneficial to safety and health professionals and health educators, particularly those interested in developing heat stress training and educational materials for oil spill cleanup responders.

This review summarizes current knowledge about heatstroke, which is often misinterpreted or overlooked, focusing on its relevance for medical practitioners.

The co-occurrence of consecutive hot and humid days during a heat wave can strongly affect human health. Here, we quantify humid heat wave hazard in the recent past and at different levels of global warming. We find that the magnitude and apparent temperature peak of heat waves, such as the ones observed in Chicago in 1995 and China in 2003, have been strongly amplified by humidity. Climate model projections suggest that the percentage of area where heat wave magnitude and peak are amplified by humidity increases with increasing warming levels. Considering the effect of humidity at 1.5° and 2° global warming, highly populated regions, such as the Eastern US and China, could experience heat waves with magnitude greater than the one in Russia in 2010 (the most severe of the present era). The apparent temperature peak during such humid-heat waves can be greater than 55 °C. According to the US Weather Service, at this temperature humans are very likely to suffer from heat strokes. Humid-heat waves with these conditions were never exceeded in the present climate, but are expected to occur every other year at 4° global warming. This calls for respective adaptation measures in some key regions of the world along with international climate change mitigation efforts.

Changes in temperature and humidity due to climate change affect living and working conditions. An understanding of the effects of different global temperature changes on population health is needed to inform the continued implementation of the Paris Climate Agreement and to increase global ambitions for greater cuts in emissions. By use of historical and projected climate conditions, we aimed to investigate the effects of climate change on workability (ie, the ability to work) and survivability (the ability to survive).

This study investigates the heat-related impacts of climate change on public health in Cyprus. Most of the health problems in Cyprus and in the Mediterranean generally, are related mainly to the warming already occurred as well as to extreme weather events such as heatwaves. In addition projections indicate that warming and extreme events will increase in future posing serious threats on human health. For the investigation of the relationship bretween hot weather condition and mortality in Cyprus, a statistical model was constructed showing linear increase of mortality with increasing temperature. Humidex is also calculated, using outputs from several regional climate models. The analysis revealed a significant increase in the Humidex in future period mainly during summer months.

This study provides a comprehensive characterisation of future heatwave-related excess mortality across various regions and under alternative scenarios of greenhouse gas emissions, different assumptions of adaptation, and different scenarios of population change. The projections can help decision makers in planning adaptation and mitigation strategies for climate change.

We studied regional characteristics of mortality and meteorological conditions in Seoul and Busan during the extreme heat wave of 1994. We estimated the relationship between EHWS’s fixed criteria and observed deaths during 1991–2005. During the same period, HHWS’s warning criteria and observed excess deaths were calculated and compared to the EHWS’s to test the reliability of the system. Because of increasing urban vulnerability, the application and development of a heat warning system is imperative. Application of HHWS will reduce the urban health risks and provide efficient decision-making for public health officials.

Haze is an extreme weather event that can severely increase air pollution exposure, resulting in higher burdens on human health. Few studies have explored the health effects of haze, and none have investigated the spatiotemporal interaction between temperature, air quality and urban environment that may exacerbate the adverse health effects of haze. We investigated the spatiotemporal pattern of haze effects and explored the additional effects of temperature, air pollution and urban environment on the short-term mortality risk during hazy days. We applied a Poisson regression model to daily mortality data from 2007 through 2014, to analyze the short-term mortality risk during haze events in Hong Kong. We evaluated the adverse effect on five types of cause-specific mortality after four types of haze event. We also analyzed the additional effect contributed by the spatial variability of urban environment on each type of cause-specific mortality during a specific haze event. A regular hazy day (lag 0) has higher all-cause mortality risk than a day without haze (odds ratio: 1.029 [1.009, 1.049]). We have also observed high mortality risks associated with mental disorders and diseases of the nervous system during hazy days. In addition, extreme weather and air quality contributed to haze-related mortality, while cold weather and higher ground-level ozone had stronger influences on mortality risk. Areas with a high-density environment, lower vegetation, higher anthropogenic heat, and higher PM2.5 featured stronger effects of haze on mortality than the others. A combined influence of haze, extreme weather/air quality, and urban environment can result in extremely high mortality due to mental/behavioral disorders or diseases of the nervous system. In conclusion, we developed a data-driven technique to analyze the effects of haze on mortality. Our results target the specific dates and areas with higher mortality during haze events, which can be used for development of health warning protocols/systems.

Exercising in the heat induces thermoregulatory and other physiological strain that can lead to impairments in endurance exercise capacity. The purpose of this consensus statement is to provide up-to-date recommendations to optimise performance during sporting activities undertaken in hot ambient conditions. The most important intervention one can adopt to reduce physiological strain and optimise performance is to heat acclimatise. Heat acclimatisation should comprise repeated exercise-heat exposures over 1–2 weeks. In addition, athletes should initiate competition and training in a euhydrated state and minimise dehydration during exercise. Following the development of commercial cooling systems (eg, cooling-vest), athletes can implement cooling strategies to facilitate heat loss or increase heat storage capacity before training or competing in the heat. Moreover, event organisers should plan for large shaded areas, along with cooling and rehydration facilities, and schedule events in accordance with minimising the health risks of athletes, especially in mass participation events and during the first hot days of the year. Following the recent examples of the 2008 Olympics and the 2014 FIFA World Cup, sport governing bodies should consider allowing additional (or longer) recovery periods between and during events, for hydration and body cooling opportunities, when competitions are held in the heat.

For over three decades, an epidemic of chronic kidney disease (CKD), not related to well-known risk factors like diabetes and hypertension, and thus named CKD of unknown origin (CKDu) has been detected in agricultural and other heavy labourers in Central America, especially sugarcane workers. CKDu is also increasingly observed in manual rural workers in other hot regions, such as Sri Lanka, India, and Egypt.

There are probably multiple risk factors for CKDu, as for most non-communicable diseases, but there is a growing body of evidence that labour practices, specifically strenuous work in heat without sufficient rest or hydration, is an important driver of the disease. Thus, this disease can be seen as having a direct link to climate change and is likely to become even more prevalent in the near future unless workplace heat stress is mitigated. As a response to this disease, members of the current project consortia have collectively implemented the Adelante Initiative at a large sugarcane mill in Nicaragua. Adelante is a scientific evaluation of workplace interventions that focus on adequate water and rest in shade together with improved ergonomics, aiming to prevent CKDu in workers while preserving productivity. The PREP program will build on the Adelante Initiative and will have three different themes:

I. To evaluate the immediate and long-term impact of a Water, Rest, and Shade intervention on workforce health (kidney health and heat related symptoms) and productivity in the sugar industry;

II. To examine the economic and social impacts on individuals, families, communities, the company and health systems affected by CKDu and whether workplace interventions to reduce heat stress and the risk for CKDu aids resilience, including mitigating migration pressures;

III. To examine the policies, or absence of policies (at multiple administrative scales) that have contributed to the CKDu disease and what policies are required to effectively address it in a future changing climate.

This program is an interdisciplinary effort that brings together researchers with expertise in occupational hygiene, medicine, health economics, plus social and political sciences. The research methods range from advanced physiological measurements, focus groups and interviews, document analysis, to semi-structured interviews and participatory workshops. Using this coordinated, interdisciplinary approach we will evaluate how occupational health and safety interventions affects worker’s health at an individual level as well as the social and economic effects in the local community, and company return-of-investment.

Together with workers, management, certifying institutions, national authorities, and consumers we will build toolkits and educational materials for those affected and those wishing to improve protection for workers in industrial agricultural and other manual outdoor work. Our findings will be broadly shared via scientific communications, workshops with worker/management, production of web-based material, films for the general public, and collaboration with media. PREP will enhance our knowledge on risk factors for CKDu in industrial agricultural workers in a hot climate, and produce evidence-based toolkits and other educational material for prevention of heat stress and its consequences, directed to the industry, governments and other stakeholders. By furthering our understanding of where and who are affected, while providing viable solutions, we can help governments and industry take a proactive and cost-effective approach to address CKDu and its associated challenges. There is a need to demonstrate that such an investment will be more economical than suffering the social and economic impact of doing nothing or inadequately attempting to treat an issue that is likely to get worse in a warming world.

The overarching goal of this project was to protect the livelihoods of low-income workers as climate change leads to increased temperatures in Da Nang city. Specifically, the project aspired to increase the resilience of vulnerable urban workers to heat stress and thereby contribute to the resilience of the city as a whole.

The long-term research goal is to identify viable passive housing adaptation technologies with proven health and environmental benefits to reduce the burden of heat stress in communities affected by heat in Africa. As a next step towards this goal, the project proposes to conduct a household-randomized controlled trial (RCT) in Nouna, Burkina Faso to: (i) establish the effect of the cool roof on the primary endpoint heart rate (as an indicator of physiological stress) and (ii) quantify the effects of the cool roof on a range of secondary endpoints, including indoor temperature, indoor humidity, cardiovascular morbidity and mortality, household energy consumption, and socioeconomic outcomes.

This project aims to design an air pollution and heatwave management toolkit, school environmental monitoring program and engage with targeted national and city level governmental and non-governmental actors to support its uptake in development planning. The project is coordinated by Taru Leading Edge and ICLEI South Asia, in partnership with CDKN, and was launched in India in July 2019.

NOAA, in a public-private partnership with CAPA Strartegies, LLC, runs annual community science Urban Heat Island mapping campaigns in cities across the United States. Each year, lea organizations in cities apply for core support funding for this activity. Residents of participating cities use low-cost in-situ sensors attached to their cars to drive transects and sample urban temperatures at a height of 2m. The in-situ data are combined with satellite data in a machine learning model to develop an estimate of the urban heat island intensity across the city. The outputs of the project are open source, and the outcomes of the project include community science engagement, education, and usable datasets showing the distribution of urban heat island intensity across the city.

Le projet VURCA étudie la vulnérabilité des villes à des épisodes futurs de canicules, afin de proposer des stratégies d’adaptation.

The UK Met Office’s Weather and Climate Information Services for Africa (WISER) programme’s mission is to make a step change in the quality, accessibility and use of weather and climate information services at all levels of decision making for sustainable development in Africa.

The Met Office has been commissioned by the UK government’s Foreign, Commonwealth and Development Office (FCDO) to act as fund manager for the East Africa component of the programme, focussing on the Lake Victoria Basin and surrounding region (Burundi, Ethiopia, Kenya, Rwanda, Tanzania and Uganda). This component aims to improve the quality and relevance of weather and climate information and support its uptake and use.

Under the East Africa component five quick-start projects using WISER funding were commissioned in late 2015 and commenced work early in 2016. A further series of projects began in 2017. In the commissioning of new projects, applications will be invited to access WISER funding in line with the WISER strategy. Details of any open application rounds can be found on our WISER programme opportunities page.

For information on projects under the Policy & Enabling Environment Component (PEEC) please visit the ClimDev-Africa website.

The World Weather Research Programme (WWRP) is the WMO’s international programme for advancing and promoting research activities on weather, its prediction and its impact on society. The improvements in science and operational predictions are driven by international cooperation, and in turn international cooperation in weather science is a unique opportunity to drive sustainable development.

The Yale Programme on Climate Change Communication conducts scientific research on public climate change knowledge, attitudes, policy preferences, and behavior, and the underlying psychological, cultural, and political factors that influence them. They also engage the public in climate change science and solutions, in partnership with governments, media organizations, companies, and civil society, and with a daily, national radio program, Yale Climate Connections.

The World Urban Database and Access Portal Tools project is a community-based project to gather a census of cities around the world.

The overall aims of WUDAPT are to:

• use the Local Climate Zone (LCZ) classification framework as the starting point for characterizing cities in a consistent manner
• use Geo-Wiki to sample land cover and land use types across LCZs (e.g. impervious surfaces (buildings, roads, other), pervious surfaces, grassland, etc.)
• develop tools (online and mobile-based) to obtain other parameters such as building materials, building dimensions, canopy widths, etc.
• provide open access to this dataset so that researchers around the world can use the data for many different types of applications, from climate and weather modeling to energy balance studies
• provide basic tools in the portal to allows researchers to aggregate the data to a user-specified reference grid (resolution and starting location) and compare cities around the world.

For WUDAPT to work, we need to build a community of interested urban experts and interested researchers who will take active part by:

• using the training materials to classify your city into LCZs
• contributing your LCZ map to WUDAPT
• helping us to collect other parameters using the online and mobile-based tools that will be developed.

Electric vehicles (EVs) are a promising solution for sustainable transport. However, making EVs a sustainable solution depends on a variety of factors such as the carbon footprint of the electricity mix.

We will focus on two major emerging markets – China and India – to investigate the conditions under which EVs can provide co-benefits for air quality, health and climate change. The growth of EVs relies on curbing the use of coal power plants, building new infrastructure and shifting consumer preferences. We will help develop solutions for these challenges by evaluating the relative importance of country-specific factors such as subsidies, regulations around EVs and the price of electricity. We will design a series of scenarios to represent these key factors and use an integrated assessment modelling method combining emissions analysis, air quality modelling and health impact assessment.

Our findings could inform policy to unlock the air quality, health and climate co-benefits of EVs in China and India.

The main objective of ACASIS is to set-up a pre-operational heat wave warning system over West Africa tailored to health risks of the population living in this region. This is a demonstration project focused on Senegal and Burkina Faso where national weather services have already started developing products dedicated to weather/climate and health relationships, and where several health and demographic observatories have been operating for up to several decades.

This project will estimate air pollution (fine particulate matter (PM2.5) and ozone), heat waves, and days of high or low temperatures under present day conditions and in the future under climate change for two major Brazilian cities. The project will also develop estimates of how weather and air pollution impact mortality in Brazil.

The five-year ASSAR project (Adaptation at Scale in Semi-Arid Regions, 2014-2018) uses insights from multi-scale, interdisciplinary work to inform and transform climate adaptation policy and practice in ways that promote the long-term wellbeing of the most vulnerable and those with the least agency.

Working in 7 countries in the semi-arid regions of India, and East, Southern and West Africa, we focused our case studies on regionally-relevant, socio-ecological risks and dynamics relating to livelihoods, and resource access, use, and management.

CHAMNHA is led by a transdisciplinary team from 3 continents, spanning the natural, health and social sciences, and will address key knowledge gaps around heat and Maternal and Neonatal Health (MNH) in sub-Saharan Africa.

Abstract

The frequency and intensity of heat waves have increased in sub-Saharan Africa (SSA) and are set to escalate in the coming decades. Heatwaves present major health threats, especially for vulnerable population groups, such as those with limited socio-economic resources or compromised physiological ability to respond to heat stress. Pregnant women and neonates (<28 days after birth) have a unique set of health vulnerabilities, particularly in low- and lower-middle income countries (LLMICs), where pregnancy and childbirth are often highly precarious. Heat exposure complicates Maternal and Neonatal Health (MNH), increasing risks for maternal haemorrhage and sepsis, prematurity, low birth weight and neonatal dehydration. Few studies have assessed these impacts in sub-Saharan Africa, where maternal and neonatal deaths are frequent, facilities experience high indoor temperatures, health systems have low adaptive capacity and access to services is increasingly disrupted by climate events.

The proposed study (CHAMNHA) is led by a transdisciplinary team from 3 continents, spanning the natural, health and social sciences, and will address key knowledge gaps around heat and MNH in SSA in collaboration with stakeholders, employing qualitative and quantitative methods, implementation and evaluation science, and climate impact methods. The project is divided into three work packages (WP). WP1 will quantify impacts of heat exposure on MNH outcomes, using trial data, birth cohorts and other data sources from SSA, Norway and Sweden. We will characterize these impacts and identify sub-groups at high-risk. In WP2, qualitative research will document perceptions and local practices relating to heat exposure in pregnant women and neonates in Burkina Faso and Kenya. Then, in conjunction with pregnant women, male partners and health workers, we will co-design community- and facility-based interventions, such as improving preparedness for heat, e.g. through warning systems; changing behaviours and health worker practices to reduce heat impacts on MNH; training birth companions and traditional birth attendants on heat reduction during childbirth; and promoting breastfeeding and optimised hydration for women and neonates. WP3 will test the acceptability, feasibility and effectiveness of selected interventions using a randomized design (Kenya) and pre-post study design (Burkina Faso). In WP4, building on established collaborations with stakeholders, ministries of health and WHO, we will translate research findings into recommendations for improved MNH practice in the health sector, and national adaptation planning to reduce the current and future impacts of climate change on MNH

Using an interdisciplinary modelling approach, this project will quantify the air quality and health co-benefits of mitigation and adaptation policies in Ahmedabad, India in collaboration with the Indian Institute of Tropical Meteorology, Gujarat Energy Research and Management Institute, Public Health Foundation of India and the Natural Resources Defense Council. It will estimate the total electricity demand in 2030, considering climate change and demand for air conditioning. It will model and compare air quality associated with two climate change response strategies: shifting fossil fuel use to solar energy; and expanding cool roof/green landcover interventions. It will also use air quality estimates to calculate health co-benefits in 2030, relative to a 2018 baseline and a 2030 business-as-usual scenario.

In 2013, the city of Ahmedabad, in Gujarat State, India, adopted and started implementing the first Heat Action Plan in South Asia. Based on learning from the project’s first phase, and interest from other state and municipal governments in India, the next phase was building on this momentum to deepen and expand action on extreme heat.

The heat wave in 2003 caused approximately 7% more deaths. As a result, the Swiss Federal Office of Public Health developed an information campaign for the behaviour during heat waves which has been adopted by various cantonal health authorities.

Objectives

1) Assessment of preventive measures which have been recommended or implemented by various stakeholders (communities, cantons, confederacy, MeteoSuisse, international authorities) to reduce heat-related mortality.

2) Analysis of the effect of heat waves on mortality in Switzerland on the basis of empirical data on a national level and stratified by region. The hypothesis will be tested the effect of comparable heat episodes on mortality is reduced since 2003.

3) Evaluation of regional adopted measures on the heat-related excess mortality in single cantons/regions where preventive measures have already been implemented.

4) Identification of the meteorological indicator which best describes the heat effect on mortality and identification of the highest groups at risk.

5) Preparation and dissemination of epidemiological studies on the topic for interested stakeholders with newsletters and workshops.

Methods

In a first step an assessment of the adopted and recommended measures aiming to reduce heat-related mortality will be executed. In a second step, Swiss mortality data (1990-2012) from the Federal Office of Statistics will be linked with the corresponding regional meteorological data provided by MeteoSwiss. The heat-related excess mortality will be investigated using Poisson regression analysis. Furthermore, various meteorological indicators will be investigated for the health effect of heat episodes. An important part of the project addresses the knowledge transfer. During the project, new relevant epidemiological studies will be identified, summarized and evaluated regarding to the practice. Information is made available to the relevant agencies and stakeholders by means of a newsletter.

Expectations

The project will provide an overview of adaptation measures for the prevention of heat-related mortality. It will show which meteorological parameters have the greatest effect on mortality and which age groups are particularly affected. The projects will generate evidence whether an increased sensitivity to the issue and adopted measures in the recent years had an impact on the extent of heat-related mortality.

The EXHAUSTION project aims to quantify the changes in cardiopulmonary mortality and morbidity due to extreme heat and air pollution (including from wildfires) under selected climate scenarios.

EXHAUSTION will address key knowledge gaps as listed by IPCC, including the following:

• Published health risk projections do not properly account for adaptation.
• There is a lack of knowledge and appropriate models regarding possible interactive effects of extreme heat and air pollution.
• Quantitative projections of the costs associated with the health risks are suffering from a simplified modelling of the complex relationship between climatic and non-climatic factors, human health, and the socio-economic consequences.

EXHAUSTION will advance on these issues–adaptation, interactive effects, and socio-economic costs – and quantify the changes in cardiopulmonary disease under selected climate scenarios while including a diverse set of adaptation mechanisms and measures, calculate the associated costs, and identify effective interventions for minimizing adverse impacts. The EXHAUSTION consortium is multidisciplinary, encompassing specialists in climate and air quality modelling, cardiopulmonary medicine, epidemiology, health impact assessment, economics, and science communication. Moreover, the Consortium is pan-European, with participation of 14 partners from 10 countries in Europe and representing the territories subject of study in the project.

EXHAUSTION is a EU-funded research project led by CICERO Center for International Climate Research (Norway), and includes 13 other research institutions and partners: University of Oslo (Norway), Norwegian Institute of Public Health (Norway), Aarhus University (Denmark), Helmholtz Zentrum München (Germany), University of Porto (Portugal), National Meteorological Administration (Romania), National and Kapodistrian University of Athens (Greece), London School of Hygiene and Tropical Medicine (UK), Luxembourg Institute of Socio-Economic Research (Luxembourg), Department of Epidemiology of the Lazio Region Health Service in Roma (Italy), Finnish Meteorological Institute (Finland), InfoDesignLab AS (Norway), DRAXIS Environmental S.A. (Greece).

EXTREMA’s main objectives were to raise awareness, facilitate prevention and protect health from the adverse effects of climate change. EXTREMA was a DG ECHO funded project, 2018-2019, GA 783180.

The EXTREMA project led to EXTREMA Global – see more https://www.extrema-global.com/

The project focuses on heat waves in Hanoi and is the first FbF project to focus on extreme events in urban areas. In Hanoi the average daily temperatures have risen in recent years; past heatwaves have led to a 20.0% increase in hospital admissions for all causes and 45.9% for respiratory diseases. One main element of the project is the identification of early actions that can reduce these health impacts of heatwaves, with a special focus on groups that are particularly affected like the elderly. Research, consultation with experts and field assessments are currently under way.

An interdisciplinary research team will use a mortality database for urban residents in nine Latin American countries to examine the impact of climate change, particularly extreme heat events, on urban population mortality. They will also examine the modifying effect of green space and fine particulate matter on the association between heat events and mortality.

This project will take an interdisciplinary approach to quantify the health impact of changes to urban green infrastructure, and develop an environment and health economics tool, focusing on international cities, including London, Beijing and Nairobi.

The purpose of this study is to develop and test a set of interventions to reduce the impact of extreme heat on urban low-income populations.

The Horizon 2020 research project is dedicated to address the negative impact of increased workplace heat stress on the health and productivity of five strategic European industries: manufacturing, construction, transportation, tourism and agriculture.

LUCID is developing, testing and applying state-of-the-art methods for calculating local climate in the urban environment. The impact on the internal built environment, energy use and the consequences for health will then be explored. The implications for urban planning will be considered in detail.

This study is exploring how low- to moderate-cost interventions can alleviate the impact of high temperatures and humidity in ready-made garment factories in preparation for further climate change. It compares the use of green or white roofs and actively-managed fan-assisted cross-ventilation, compared to no interventions and air-conditioning. Climate-controlled chambers, computer-based modelling temperature monitoring, and worker interviews will be used to explore perceptions of discomfort caused by heat. Findings will help estimate when it will be necessary to invest in interventions and how effective they can be.

The Multi-City Multi-Country (MCC) network is an international collaboration of research teams working on a program aiming to produce epidemiological evidence on associations between weather and health. Interest on this topic has grown in the last few years among both researchers and the general public, due to recent events of extreme weather and alarming climate change scenarios, both linked with increased health risks.The research program benefits from the use of the largest dataset ever assembled for this purpose, including information from hundreds of locations within several countries. This allows standardized analyses on local data to address specific research questions on global weather-health associations, following a formalized yet flexible method of collaboration. The MCC network has developed during the years, through correspondence between the participants and additional meetings held at other scientific conferences.

Many greenhouse gas mitigation actions also benefit air quality and health but assessment of these co-benefits has been limited. Over the next several years, C40 Cities will be working with city governments to develop climate action plans. They will integrate a screening-level air quality model focusing on particulate matter into C40’s climate action planning tool, Pathways, for at least three pilot cities. They will test the tool to explore air quality and health co-benefits of climate action pathways. We will also assess the potential for quantifying additional health co-benefits, such as changes in ozone, nitrogen dioxide levels, physical activity, noise and green space. Data and tools will be publicly available to support additional research into links between climate and health. Their work will build a bridge between scientific evidence on co-benefits to the largest urban climate action planning effort worldwide. Pathways will create a platform to study more cities and enable long-term integration of health co-benefits into climate action planning in cities.

This project will study the complex threat heat exposures pose to human health, wellbeing and productivity in working populations in Singapore and other tropical countries, and to identify sustainable preventive policies and actions that can reduce these impacts. Working people are particularly vulnerable to environmental heat because of their added internal heat production from muscle work. Singapore’s equatorial location means working populations are already chronically exposed to hot conditions (WBGT > 25°C) which are considered detrimental to health and wellbeing. These conditions require people working or engaged in exercise outdoors to take frequent rest and cooling breaks to protect health, If workers cannot or do not take rest in relation to heat stress, serious health effects can occur, including heat stroke death. Such conditions also affect productivity, which is reduced by 15% of potential annual work hours in the sun and by 4% if working in the shade.

Singapore has begun to tackle these issues by supporting mitigation and adaptation to extreme heat associated with climate change and with the urban heat island effect through research focused on public health and urban design. However, heat-health is a complex socioenvironmental problem that transgresses institutional, sectoral and disciplinary boundaries of public and occupational health and the domains of workplace, public space and the home. As such, there is a need to complement these efforts through the provision of a programme focussed on occupational exposures and their knock-on effects to support the overall effectiveness of Singaporean investments in heat-health risk management. Exposed work occurs in outdoor settings, but semi-enclosed workspaces, such as sheds or roofed workshops, can also present very hot thermal environments where cooling systems are inefficient, air conditioning cannot be used for financial or other reasons, and/or additional heat sources are present. These conditions are typical of many industries, including construction, shipping and utilities, including oil and gas transport and storage.

There is also limited evidence available concerning occupational heat exposures, and the impact of age, body mass index, physical fitness, and sex (e.g. pregnancy) on these effects, or their broader effects, such as prolonged discomfort, and mental stress, familial relationships and special health concerns, such as fertility. Improved knowledge is essential for the development of effective prevention programs. The researchers will pursue a multi-disciplinary approach uniquely positioned to address direct occupational heat exposures and impacts on health and productivity, but also the broader health and wellbeing implications that have yet to be comprehensively addressed in chronically heat-exposed countries such as Singapore. For example, physical fitness is one of the best ways of increasing heat tolerance as well as overall health. Ironically, the high heat levels in Singapore do not only discourage engagement in physical exercise, but can also be a direct health threat for people involved in sports and exercise. We will also review and test methods for analysing the most extreme effects of heat, including heat related mortality.

By following impacts on workers as well as workplaces, the study will trace how heat-health impacts emerge through exposure and exertion as a result of behaviours shaped by the climatic, urban, occupational and social environments they traverse every day. Such integrated analysis is required in order to develop policy responses that take into account the spatial and social situation of why heat-health impacts occur and how they can be managed as part of the everyday lives of chronically exposed populations. This also allows for the identification, analysis and management of ‘knock-on’ effects of occupational heat exposures on recreational and domestic life (and vice versa), including psychosocial and physiological impacts on exercise behaviours and fitness, family relationships, mental health and wellbeing and fertility rates. As our focus is on heat effects on working people, one secondary outcome of excessive heat exposure will be economic losses at individual, enterprise, community and national level due to a reduction of labour productivity due to heat. Our analysis will compare such economic impacts of heat to the costs of potential methods for climate change mitigation in selected countries. This will provide new estimates of the value of different alternatives in future climate change policy development.

The Arizona Extreme Weather and Public Health Program’s primary climate-sensitive hazard topics include extreme heat, wildfires, air quality, drought, flooding, extreme cold, and vector-borne diseases. Extreme heat is a major concern to Arizona and a large focus of their work due to the frequency and severity of extreme heat events. A large portion of the state’s population is frequently exposed to outside temperatures above 100 degrees from May through September. Arizona experienced about 1,200 heat caused deaths during 2007–2017. In addition to extreme heat, the arid climate leads to other hazards such as flooding during monsoon season and more wildfires due to increased drought and high temperatures.


The Arizona Extreme Weather and Public Health Program facilitates the development and sharing of local knowledge of climate and health effects and the implementation of public health interventions for climate-related hazards affecting the state’s residents and visitors. Partnerships have led to several projects on extreme heat, such as heat alerts sent to schools and public and healthcare facilities that provide steps for heat safety. Additionally, local projects have assessed and improved cooling center networks, which help provide a cool space to get out of the heat during the summer. The program has created and distributed heat safety toolkits for various specific at-risk populations, including outdoor workers, older adults, and school children. The program and local partners have also increased their capacity to perform heat illness surveillance activities and coordinated a state heat preparedness workgroup.


In addition to adapting to the challenges of heat, other work has focused on understanding climate impacts on vector-borne diseases and the fungal disease called Valley fever. The program has also assisted in developing public health emergency response plans for wildfires and flooding. This work benefits various populations such as the homeless, elderly, children, local officials, and residents of low income and minority neighborhoods.

The Telangana State Heatwave Action Plan 2021 outlines comprehensive strategies to mitigate the adverse health effects of heatwaves. It emphasizes public awareness, interdepartmental coordination, and timely response measures. The plan includes early warning systems, community outreach programs, and specific guidelines for vulnerable populations. By implementing these measures, Telangana aims to reduce heat-related illnesses and fatalities during extreme temperature events.

(National Plan for the prevention of the effects of heatwaves on health)

The Heat-Health Action Plan of the former Yugoslav Republic of Macedonia has been developed to implement adaptation measures and prevent health consequences of extreme heat caused by changing weather conditons as a result of climate change. The primary goal of the Plan is to reduce heat-related morbidity and deaths through issuing heat health warnings, with particular emphasis on the most vulnerable population groups, provide timely advice and announcements of upcoming heat-waves, raise awareness amongst the public and health workers, and coordinate and mobilize all available resources in a timely manner to prevent the health consequences and institurios from the herlath sector as well as other relevant sectors. The aim of the Plan is to provide a multisectorial approach in the response to extreme heat, Through prompt action by all institutions designeted as responsible with this Plan. This document is in line with the National Platform for Disaster Risk Reduction of the former Yugoslav Republic of Macedonia

Working with Cofepris, the Ministry of Health, and the CEC, Sonora’s regional health authority (Comisión Estatal de Protección contra Riesgos Sanitarios del Estado de Sonora—Coesprisson) established several objectives with the goal of creating a real-time SyS system for the city of Hermosillo in a 2016 pilot SyS project that would enable timely identification of health impacts due to extreme temperature and evidence-based policy development to reduce mortality and morbidity rates.

What meteorological factors are going to change? How much will they change? Will there be spatial variation? These are foundational issues for public health agencies in preparing for the impacts of climate change. In the wake of the Building Resilience Against Climate Effects (BRACE) framework developed by the US Centers for Disease Control and Prevention (CDC), health agencies in the United States are using forecasted meteorological data to monitor health vulnerabilities across populations and places resulting from climate change.

Case study of the development of North Macedonia’s National Heat-Health Action Plan, which has been developed within the National Strategy for Adaptation for the health sector to implement adaptation measures and prevent health consequences associated with extreme heat due to climate change.

Following a deadly heat wave in May 2010, the Ahmedabad Municipal Corporation (AMC) realized that coordinated action was needed to protect its residents from extreme heat and to become more climate-resilient

In 2012, consistent with Alberta’s climate change adaption framework, Alberta Health, the Provincial Government Department of Health, initiated a high-level vulnerability assessment that led to the development of a Heat Warning and Information System (HWIS) involving collaboration between several agencies with expertise outside of public health.

As part of a climate change risk assessment, Public Health England took the initiative to analyse the impact of cold winters and warm summers on the number of ambulance call-outs and ambulance response times in London. This study is the first of its kind in the United Kingdom. Initial findings show that there is a clear relationship between air temperature and emergency ambulance calls.

Heatwaves kill more people than any other natural hazard in Australia. Current literature on managing health risks of heatwaves highlights the importance of implementing urban planning measures, and engaging with vulnerable groups on a local level to better understand perceptions of risk and tailor health protection measures. This paper reviews arrangements to reduce heatwave health risks in South East Queensland in response to these themes. A literature search and document analysis, stakeholder interviews, and multi-stakeholder cross-sectoral workshops revealed that although heatwave management is not always considered by local government and disaster management stakeholders, many urban planning measures to minimize urban heat have been pursued. However, greater information from vulnerable groups is still needed to better inform heatwave management measures.

Federal, state, and local agencies are working to provide more advanced warnings and services to help people better prepare for—and respond to—extreme heat events

Close collaboration between SCHSA and HKO highlights the importance of partnership and stakeholder engagement in improving the delivery and communication of useful weather and climate information to the health sector and promoting public awareness on the care of elderly people

The SUPREME system, developed by the INSPQ in 2010 together with a users committee, provides access to indicators that relate exposure to hazards (temperatures, urban heat islands, etc.), socioeconomic characteristics of neighbourhoods (population density, deprivation index, etc.), health problems (deaths, emergency room admissions, etc.), and follow-up during and after an intervention by field teams. Post-event reports are produced regionally and aggregated annually.

The HHWS was developed to reduce the heat related mortality. The HHWS is in operation since 2005 and preliminary studies indicate a reduction in the heat related mortality ever since.

This study provided a pilot assessment of vulnerability to heat exposure in a rural context during the peak summer months of 2016, with a focus on indoor and outdoor temperatures.

Citizen-scientists took to the streets on specially equipped bikes and cars to find out where it’s hottest—and where residents might be most vulnerable to extreme urban heat.

The City of Tatabánya has an approved comprehensive adaptation strategy, the Local Climate Change Action Plan, that is in its implementation stage. This Plan is based upon a comprehensive approach taking into consideration both mitigation and adaptation, incorporating climate considerations into decision-making, and including adaptation concerns in municipal processes. At this time, three measures have been implemented: (1) a local heat alert system; (2) the Smart Sun Educational Programme; and (3) building capacity of the fire brigade.

This report looks at how the local community of Ahmedabad in Western India is preparing for the increasingly extreme heat of the city.

Heat waves bring some level of discomfort to nearly everyone. When excessive heat catches vulnerable populations off guard, though, discomfort can advance to illness and even death. Learn about strategies taken in Minnesota that help protect people in both rural and urban settings.

In the January 2009 heatwave, a prototype heatwave alert system had just been introduced, based on research identifying a threshold temperature above which excess mortality occurred in Melbourne, Australia. By the time of the January 2014 heat wave, the heat alert system had been considerably refined, based on further scientific work (2–4) and intense interactions between climate scientists and public health authorities. The excess mortality associated with the 2014 heat wave was substantially lower than in 2009, even though the 2014 heat wave lasted longer.

Planning with extreme weather thresholds catalyzes a $400,000 green infrastructure investment in a historically underserved neighborhood in Las Cruces, New Mexico.

In order to reduce the vulnerability of elderly people to heat waves in Austria, a new communication approach was developed and tested as part of the CcTalK! Project.

Responding to growing awareness of climate change impacts, the State of Colorado commissioned two of its universities to complete an initial study of the state’s vulnerabilities.

Cincinnati created a dedicated funding stream for its urban forestry program in 1981 that has enabled the city to maintain
a high percentage of its tree canopy. Heat mitigation is a key reason tree canopy is a priority. Although Cincinnati has a temperate climate and harsh, cold winters, the urban heat island effect can make the city up to 17°F hotter than nearby
rural areas during the summer.

Cool Neighborhoods NYC is a strategy developed by the Mayor’s Office of Resiliency to provide and target additional funding and to coordinate multiple extreme heat mitigation and adaptation projects. The objective of Cool Neighborhoods NYC is to “help keep New Yorkers safe during hot weather, mitigate urban heat island effect drivers and protect against the worst impacts of rising temperatures from climate change.”

Los Angeles is the first U.S. city to set a citywide temperature reduction goal, and switching to cool surfaces is a key strategy for achieving that goal. Los Angeles’s goal is to reduce the urban heat island effect by 1.7°F by 2025 and average temperature 3°F by 2035, but the city is 40 percent covered by pavement. Los Angeles’s reflective paving program, which targets both rooftops and public streets, complements other UHI reduction programs including a Million Trees initiative and integrated planning with the Department of Health.

The City of Long Beach, California, sees signs of climate change on land and in the ocean. After compiling the City’s official climate assessment report, local stakeholders also produced a more accessible and user-friendly summary version and shared it broadly to stimulate informed discussion and decision making across the city.

This AdaptNY case study of the Chicago heat wave of 1995 looks at how the urban heat island effect is exacerbated by socio-economic factors and poor city planning.

Residents of the Carolinas are familiar with hot summers, but in some areas excessive heat events bring a higher risk for heat-related illness—and even death. A new tool can help local communities get ahead of heat events so they can reduce risk for their residents.

With the goal to support the development of population heat resiliency and the capacity to withstand the effects of climate change, Michigan’s MDHHS and the CEC partnered to improve the MSSS to include a HRI-specific syndrome.

This issue brief highlights the progress at the city, state and national level in India in 2019 to improve climate resilience to extreme heat, and captures key elements of heat action plans.

Drawing lessons from the ground-breaking 2013 Ahmedabad Heat Action Plan,3 city, state, and national level authorities are ramping up to implement extreme heat warning systems and preparedness plans. In 2020, the national government is working with 23 states and over 100 cities and districts to develop and implement heat action plans across India.

In Spain, the State Meteorological Agency (AEMET) has been successful in using weather prediction models to forecast short- and medium-range extreme temperatures, and an early warning system (Meteolerta) has been implemented in cooperation with European EUMETNET member countries (MeteoAlarm).

Toronto was the first city in North America to require and govern the construction of green roofs on new development. The Green Roof Bylaw (which includes a Green Roof Construction Standard) and the parallel Eco-Roof Incentive Program are responsible for more than 1.2 million square feet of new green space, an estimated reduction in citywide temperature, and widespread promotion of cool roofs.

This case study provides an overview of the active heat health collaborations, projects and research ongoing in Hong Kong and presented during the First Global Forum on Heat and Health.

Hong Kong faces unique challenges from environmental hazards, such as climate change and variability, due to its densely populated and almost entirely urbanized living environment. An increased vulnerability to the urban heat island effect means that its inhabitants are more susceptible to the harmful, and sometimes deadly, health effects of extreme heat. This case study exemplifies how a multidisciplinary partners and agencies are collaborating to protect the most vulnerable communities.

This project, which is part of a broader WHO/UNDP Global Environment Facility (GEF)-funded project, developed and implemented a heatwave early warning system to reduce the health risks and to increase the capacity of health systems and community residents to prepare for and cope with periods of extreme temperatures. The project was piloted in four cities: Harbin, Nanjing, Shenzhen and Chongqing, located in different climate zones within China.