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Review

Effectiveness of Public Health Interventions in Reducing Morbidity and Mortality during Heat Episodes: a Structured Review

1
Faculty of Health Sciences, Simon Fraser University, 8888 University Drive, Burnaby, BC V5A 1S6, Canada
2
Dalla Lana School of Public Health, University of Toronto, 155 College Street, Toronto, ON M5T 3M7, Canada
*
Author to whom correspondence should be addressed.
Int. J. Environ. Res. Public Health 2010, 7(3), 991-1001; https://0-doi-org.brum.beds.ac.uk/10.3390/ijerph7030991
Submission received: 29 December 2009 / Revised: 12 February 2010 / Accepted: 13 February 2010 / Published: 10 March 2010

Abstract

:
Increasing concern over the impact of hot weather on health has fostered the development of public health interventions to reduce heat-related health impacts. However, evidence of the effectiveness of such interventions is rarely cited for justification. Our objective was to review peer-reviewed and grey literature evaluating interventions aimed at reducing morbidity and/or mortality in populations during hot weather episodes. Among studies considering public risk perceptions, most respondents were aware when an extreme heat episode was occurring but did not necessarily change their practices, primarily due to a lack of self-perception as vulnerable and confusion about the appropriate actions to be taken. Among studies of health outcomes during and following heat episodes, studies were suggestive of positive impacts in reducing morbidity and mortality. While the limited evaluative work to date suggests a positive impact of public health interventions, concern persists about whether the most vulnerable groups, like the elderly and homeless, are being adequately reached.

1. Introduction

The adverse effects of hot weather on health are of increasing public health concern, particularly for urban areas. With climate change, warmer climates are expected to result in higher mean summer temperatures and fluctuations will likely result in more frequent and intense heat waves and their associated health risks [1]. Environmental health practitioners and policymakers are faced with the challenge of deciding both which public health interventions are most appropriate and when and how they should be implemented at the regional and local level [24]. However, information regarding the effectiveness of public health interventions to reduce morbidity and mortality during heat episodes is often not brought into decision-making and requires further study [5,6].
To better equip environmental/public health practitioners and policymakers in making these important decisions, we recently undertook an examination of the types of public health interventions implemented globally during heat episodes, including media announcements, opening of cooling centres, outreach to vulnerable groups, and website bulletins [7]. The aim of this structured review is to address the question: What is the evidence on effectiveness of public health interventions in reducing morbidity and mortality during heat episodes?

2. Methods

Environmental health practitioners and policymakers were invited to provide advice throughout the project in agreement with recommendations on the process of developing systematic reviews relevant to public health policy [8,9]. Their role was both advisory, to assist us in identifying research gaps and priorities in this area, as well as resourceful, by directing us to relevant materials that may not have been detected by our search.
Two major information sources were explored: peer-reviewed literature; and grey literature, the latter including non-published sources such as conference proceedings, government documents, theses, working papers, and reports.

2.1. Peer-Reviewed Literature

Following initial discussions with our expert advisory group and our initial scan, we anticipated that limited information would be available in the peer-reviewed literature. As a result, our search strategy was designed to be as comprehensive as possible in an effort to capture any relevant materials. We searched the following bibliographic databases: Medline, PreMedline, and Scholars Portal. We did not include a date or other restrictions on the kinds of papers retrieved at this stage. Terms were used in the search strategy included:
At least one of: plan, planning, program, response, intervention, evaluation, response, warning, alert, watch, public health response, implementation, prevention, awareness, education, preparedness, control, measures, strategy, system, risk management, disaster management, emergency management; “And” with at least one of: heat or heat stroke or heatstroke or extreme weather or summer weather or heat wave or heat event or heat stress or heat episode or hot weather or excessive weather.
For each search the titles, abstracts, and sometimes the full text of articles were reviewed to determine relevance. Articles that were selected included those that presented public health interventions used during heat episodes and considered an evaluation of effectiveness. Stringent inclusion and exclusion criteria were not applied, given the limited information encountered but we maintained a focus on interventions designed specifically for human health rather than planning, landscape ecology, or architectural literature, more broadly addressing urban form and heat load.
Reference lists of relevant articles were scanned for other relevant material. Key authors of the papers were contacted via email for additional information and direction to relevant resources. Prominent heat stress researchers, as identified in the literature, were also contacted to identify any evaluative work not identified through our search.

2.2. Grey Literature

Several strategies were used to capture the grey literature related to the review topic.
  • Internet search engines: Similar terms to those used for the peer-review literature were applied through major search engines including Google, GoogleScholar, and Scirus to search for other non-published literature, conference proceedings, government documents, theses, working papers, and reports.
  • Web-sites: Specific global and national web-sites that might include public health/heat information were visited and contacts followed-up to determine any evaluative work completed or in-progress.
  • Institutional repositories: These were searched for faculty publications that may or may not be included in peer-reviewed sources, theses, and conference proceedings.
  • GPO Cat/Pac and the Canadian Research Index: Here we sought policy documents, memos and reports generated by municipalities, public health units and other levels of government.

2.3. Focusing the Review

The majority of evaluations we encountered were evaluations of heat-health warning systems (HHWS) and their robustness as meteorological forecasts. Very few studies evaluated the effectiveness of interventions put in place as a result of warnings generated from these systems, partly due to the challenge in defining “effectiveness” of interventions during heat episodes. Possible meanings or indicators of effectiveness might include: messages actually reaching people (awareness), reported changes in individual practice, use of services (e.g., calls to information lines, visits to cooling centres), subsequent reduced morbidity and mortality. For the purpose of this review we decided to examine effectiveness in terms of two key sets of indicators:
  • Public awareness of an extreme heat episode and any subsequent changes in practices.
  • Documented changes in morbidity and mortality attributed to the implementation of public health interventions.
For studies including these indicators, a data extraction form was developed for each type to capture relevant information. For each type, a pair of reviewers extracted data and noted major strengths and limitations. These in turn informed our synthesis of findings and our ideas regarding research directions. Given the substantial heterogeneity in study design, these findings are presented in the narrative, and summarized in Table 1, which provides an illustration of the breadth of study design and methodologies. It is interesting to note that the majority of the studies are from the US and Western Europe, with a clear lack of studies in other regions, including many developing countries that are particularly vulnerable to the impacts of hot weather.

3. Results

3.1. Public Awareness and Individual Change in Practices

Earlier indirect indicators of awareness and practices were based on routinely collected data coming from services during heat episodes. For example, in Philadelphia during the summer of 2002, their phone information “Heatline” received over 2,300 calls [10]. As the summer progressed, fewer calls were received, likely due to less media attention, less advertising of the Heatline, and a reduced need for information given the acclimatization of the population over the course of the summer. A Toronto study surveyed staff involved in operating HHWS and those working with vulnerable groups as part of public health responses [5]. Respondents felt that although much of the general public were aware of a heat alert being declared this was less true for the vulnerable, elderly and socially isolated.
A recently used method to directly assess awareness and change in practices among the public is through the use of public surveys. These surveys typically take place face-to-face in a public venue, or over the phone. A postal survey was conducted after the 2003 heat wave in Portugal to assess individual heat protective measures both during hot episodes and specifically during the 2003 heat wave [11]. Knowledge of the heat warning was nearly universal (92%). In general, there were significantly better practices by those who had obtained information. However, the elderly (75+) and less-educated were less likely to heed advice, which is of major concern given these are more vulnerable groups.
A survey was conducted in France between 2005 and 2006 to assess the awareness and practices of the public during heat alerts [12]. Recall of heat alerts from radio and television broadcasts was high (74%). This awareness was associated with a relatively high level of change in practice: 63% of respondents took protective measures in 2006 versus 48% in 2005. All practices polled (increased hydration, closing sun-facing windows, etc.) showed increased uptake from 2005 to 2006, from 6–15%. Similarly, respondents reported increased efforts to support vulnerable friends and family, with 73% of respondents reported helping someone. However, only 63% of the elderly respondents reported having been helped and only 14% reported asking for help when they felt discomfort.
A recent study distributed 201 surveys to individuals in metropolitan Phoenix, Arizona, to gauge risk perception and warning response to heat episodes [13]. The majority of individuals surveyed reported that they were aware when a heat advisory was issued. However, there was variation in this awareness across different demographic categories (women more aware than men, respondents over the age of 65 years reported the highest level of awareness). Despite the nearly universal awareness of a heat advisory, it did not necessarily translate into action—less than 50% of those over 65 changed their behaviour during a heat warning. There was an elevated perception of risk among Hispanics that translated to increased response. The conclusions from this study were that while most people receive the messages, only about half of the population actually change their behaviour in response to a heat event.
These perception studies have focused on the general public; given that everyone is a risk to the health effects of heat to varying degrees it is clearly important to understand the general public’s perception and response to such interventions. However, telephone and postal surveys and face-to-face interviews that recruit participants at public places such as shopping plazas, typically in suburban rather than urban areas, do not capture important vulnerable groups like the socially isolated and homeless. More recently, there has been an increasing number of studies that examine such vulnerable groups specifically, particularly the elderly.
A telephone survey of 908 participants over the age of 65 years was conducted in four cities (Dayton, Philadelphia, Phoenix, Toronto) to assess knowledge of heat warnings [14]. Knowledge of the heat warning system was nearly universal (90%) and likely due to pervasive media coverage (primarily television). However, knowledge of the details of the message of the mitigation plans were less well understood, and few individuals actually changed practice in response. Many respondents did not believe they were vulnerable or that the messages applied to them. There was also reported confusion around the difference between ozone precautions and heat precautions.
More recently, a study in the UK interviewed seniors populations living at home (>72 years of age) to assess heat risk perception [15]. While few recognized themselves at risk they did recognize the risks and medical concerns in others. This raises interesting questions regarding the role of self-perception and the challenge in delivering targeted strategies to groups that do not actually consider themselves to be at increased risk. A Canadian study investigated heat perception in people with chronic cardiac and pulmonary disease [16]. By capturing potential participants through medical sites/clinics the researchers were able to capture this particularly vulnerable group. Interestingly, this chronically ill population did perceive themselves to be susceptible to heat and reported implementing preventive actions in response. Given their increased vulnerability, this is an encouraging finding and highlights the importance of future studies targeted at such at-risk groups.
A survey regarding awareness of the “St. Louis Operation Weather Survival” among the elderly and health service providers was conducted in 1995 [17]. Health and social service providers noted that elderly often were not concerned about heat (e.g., “I’ve lived here all my life, never had air conditioning, so why would I have a problem now?”) or not taking advantages of resources (“cooling shelters are only for really poor people”). Interviews with elderly corroborated these perceptions. Including health service providers was a particular strength of this survey, as it provided a unique perspective often not captured in heat health perception work that has important implications for the delivery of interventions, particularly to populations receiving ongoing medical care such as those residing in residential care facilities.
A study evaluating the effectiveness of the National Heatwave Plan in the UK also explored perception by health care providers and staff of regional public health units, social care inspectors, and primary care trusts [18]. Similarly, while the staff found the Heatwave Plan to be useful in preparing for heatwaves, they expressed concern over whether information was actually reaching vulnerable populations given the challenge in contacting such a large number of people. It was suggested that the definition of “vulnerable groups” be refined to focus on those most at risk; for example women over 85 years living alone.

3.2. Change in Health Outcomes (Morbidity and Mortality)

The other commonly used method in the public health heat interventions evaluation literature is to compare the occurrence of adverse health outcomes in time periods with and without warning systems and response plans in place. The outcome typically examined is change in mortality, with change in morbidity infrequently assessed.
One study calculated the number of lives saved and the economic benefit of warnings in reducing heat-related mortality as a result of implementing a HHWS in Philadelphia [19]. By using multiple regression to assess the relationship between excess mortality and several explanatory variables (i.e., daily weather, duration of heatwave, whether a warning was called, etc.) the authors conclude that issuing a warning lowered daily mortality by 2.6 lives. The operational costs of running this warning system was practically at a “noise” level compared to the economic benefits (using the EPA valuation of a statistical life at $6.12 million) of saving 117 lives in three years. This is the only attempt to assign an economic value to the potential lives saved as a result of implementing a HHWS. However, there are challenges in assigning such tangible values. They may only partially reflect the full “value” of a life lost, excluding less quantifiable, intangible components such as the intrinsic value of a person to their family/community. Similarly, appropriate economic evaluation would require full costing of all interventions, at least on a marginal basis.
More commonly, studies make comparisons between different heat wave periods; typically, one where there was not a response plan in place with a subsequent heat wave when interventions were implemented. For example, research in the Czech Republic reported a decrease in mortality during the 2003 European heatwaves as compared with earlier years [20]. Part of this decrease was attributed to greater public awareness of heat warnings that were issued in the 2000s when hot weather was forecasted. This is further supported by lessons from France where fewer heat-related mortalities were reported in 2006 following the implementation of a HHWS and its affiliated interventions in 2004 [21,22]. Another study used heat-related morbidity and mortality during 1995 and 1999 heat waves in Milwaukee, Wisc. to compare heat-related mortality rates and ambulance services [23]. The lower rates in 1999 were attributed to improvements in public health response.
Similarly, another study compared the mortality occurring in heat waves during 1995 and 1999 in the Midwestern US (with a focus on Chicago and St. Louis) [24]. The authors conclude that in 1999, Chicago more successfully mitigated adverse effects than it did in 1995 (119 deaths during the 1999 heatwave compared with more than 500 deaths during the 1995 heatwave). This was attributed to improvements in public health response (in addition to characteristics of the heat wave). A key factor was also felt to be the upgrading and better performance of the electrical supply which was maintained during the 1999 heat wave, whereas it failed during the 1995 episode.
Finally, a study in St. Louis, Missouri compared mortality in the 1980 and 1995 heat waves and found higher mortality in 1980, primarily because the 1980 heat wave was more severe and longer in duration than the 1995 event [25]. A simulated model of 1980 weather conditions and 1995 population suggested the St. Louis population was more vulnerable in 1995 than in 1980 despite an increase in air conditioning availability and improved public health response. The author attributes this to increases in the “frail elderly” population over 74, and rising poverty rates among the general population as well as persons over 65 years. This highlights the challenges in attributing differences in health outcomes to public health interventions. Due to differences in heat events and often the relatively short period between events, it is unclear to what extent the mortality or morbidity reduction could be attributed to intervention efforts versus meteorological factors or reduced susceptibility of the population.

4. Synthesis

From the collected evaluation literature several common themes arise. The first is that awareness of heat events/alerts is nearly universal in the general public. However, most public surveys reported in this paper did not include the most vulnerable groups, including the homeless or “shut-in” elderly (e.g., those who stay at home with limited social interaction) so it is not clear whether these groups are aware of heat events. The uncertainty of whether public health messages actually reach the most vulnerable was one of the most commonly cited concerns in our discussions with public health practitioners. Despite some initial work focusing particularly on the elderly, such information remains incomplete in both the peer-reviewed and grey literature. Nevertheless, the importance of targeting messages and outreach strategies is apparent in the recent assessment of awareness and practices among those with cardio-pulmonary disease [16].
Related to this is the definition of “vulnerable groups” and consideration of other groups that are not commonly included within this term but are also at a higher risk for the adverse effects of heat due to greater exposure. Included would be tourists, organizers/participants of outdoor events, and individuals who work outdoors. Novel methods to both assess awareness and practices, as well as targeting these groups, need to be developed (e.g., contacting employers in parks and recreational jobs to educate and protect outdoor employees during heat events).
Another theme in our review is that although many people are aware of heat events, fewer actually change their practices in response. Some groups like the elderly and those with pre-existing illnesses may not accurately perceive the health impacts given impaired physiologic responses. It is also partly due to the general perception by many that heat is not a killer, or that the heat message only applies to small sub-populations which the interviewees do not consider themselves to be part of; this has changed somewhat since the highly publicized 1995 and 2003 heat waves in Chicago and Europe. One reason for this suggested in conversations with public health practitioners is that the media often tend to focus on stories about occupational dangers in heat (i.e., parks employees, roofers, etc.) or one of the most commonly reported, of children or pets left in cars during heat events. This focus by the media on these specific sub-populations can lead the general population to believe that the messages are not applicable to them. This has important implications for framing the content of the messages and collaboration with media partners in ensuring accurate messages are being presented to the public. It also highlights the importance of providing both broad mass media messages as well as those targeted and tailored specifically to vulnerable groups.
A final theme arising from this work is the confusion in understanding and interpreting these public health messages. One commonly cited reason for this is the overlap between summer smog and heat warnings. Many public health units issue these warnings from separate divisions, but the findings from this report suggest that there should be coordination in these messages to better and more clearly inform the public about how they should respond (e.g., turn on air conditioners to reduce heat load versus turning them off to reduce electrical load and air pollution from coal fired stations). Another example is that during smog days vulnerable groups are often advised to not go outside. This conflicts with messages to go to a cooling centre.

4.1. Challenges in Evaluating Public Health Interventions for Heat

There are several methodological challenges in assessing the effectiveness of interventions for heat. Heat episodes are rare events that have differential impacts on each affected population. This is due to a variety of factors (i.e., differential distributions of individual vulnerability, level of acclimatization, etc.), making it difficult to compare different populations in different cities in response to a heat event. Even if there is the opportunity to study the same population over different time periods, the heat events themselves vary over time due to meteorological variation. The fact that no two heat episodes are the same makes attribution of changes in health outcomes to public health interventions versus different weather conditions or different underlying populations particularly difficult.
There are usually several public health interventions included in a response plan that are implemented simultaneously. This makes it difficult to attribute any beneficial effect to one intervention over another. Furthermore, many of the interventions are aimed at encouraging changes in individual practice.
Most HHWS and their associated response plans have been implemented only recently, with a marked increase in interest following the 2003 heat waves in Europe. This is an added challenge given the relatively short-time frame available for evaluation. Studies typically use historical information, or future projections for modelling the impact of HHWS and make comparisons with health outcomes. Nevertheless, opportunities exist for working with databases such as EM-DAT ( http://www.emdat.be/) and documentation of heat response plan implementation to further such research.
Finally, evaluation of environmental health interventions remains under-developed, in contrast to rigorous evaluations of vaccines, for example. The limited published research thus reflects not only some of the challenges, but also a relative under-investment in program and policy evaluation, certainly compared to the magnitude of the problem and the importance of finding effective responses to the health burden associated with climate variability.

5. Conclusions

While the limited evaluative work to date suggests a positive impact of public health interventions, concern persists about whether the most vulnerable groups, like the elderly and homeless, are being adequately reached. Further studies with a focus on these vulnerable groups are needed to better understand the most effective interventions and approaches that will mitigate the adverse health outcomes they experience. Investigating heat-health risk perception is one way to develop more targeted and effective communication strategies for these groups.
There are real methodological challenges in studying the effectiveness of interventions for heat, however novel methods are being used, and more recently, a combination of methods including modelling techniques and also the incorporation of qualitative data from surveys. There is an important need to continue to improve upon these research methods and increase research activity in this area.
Finally, developing a framework for evaluating public health interventions for heat is the next important step to build on the findings of the current work. These draft criteria, indicators and analytical methods could then be applied to a selection of sites that have heat interventions in place to assess their utility. Ideally resources could be allocated and evaluations could be coordinated through a national or international organization to improve our understanding of the effectiveness of interventions that are currently being used during hot weather.

Acknowledgments

Thanks to our colleagues Alan Abelsohn, Joanna Angus, Mike Callaghan, Lori Greco, Douglas Sider, Karen Tomic, Marco Vittiglio, Sarah Wakefield, and Clare L.S. Wiseman. Production of this manuscript has been made possible through a financial contribution from the Public Health Agency of Canada through the National Collaborating Centre for Environmental Health.

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Table 1. Overview of Studies Included in this Review.
Table 1. Overview of Studies Included in this Review.
StudyDesignLocationPopulation/Health outcome
Abrahamson (2008)Cross-sectional surveyUKElderly
Angus (2006)Cross-sectional surveyCanadaIntervention/response staff
Ebi et al. (2004)Economic analysisUSMortality
Fouillet et al. (2008)Regression analysisFranceMortality
INPES (2006)Cross-sectional surveyFranceGeneral public
Kalkstein et al. (2007)Cross-sectional surveyUSGeneral public
Kosatsky et al. (2009)Cross-sectional surveyCanadaCardiac/pulmonary patients
Kysely & Kriz (2008)Regression analysisCzech RepublicMortality
Nogueria et al (2005)Cross-sectional surveyPortugalGeneral public
Palecki et al. (2001)Regression analysisUSMortality
Sheridan (2007)Cross-sectional surveyUS & CanadaGeneral public
Smoyer (1997)Cross-sectional surveyUSElderly/health care providers
Smoyer (1998)Regression analysisUSMortality
Weisskopf et al. (2002)Regression analysisUSMortality/morbidity

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MDPI and ACS Style

Bassil, K.L.; Cole, D.C. Effectiveness of Public Health Interventions in Reducing Morbidity and Mortality during Heat Episodes: a Structured Review. Int. J. Environ. Res. Public Health 2010, 7, 991-1001. https://0-doi-org.brum.beds.ac.uk/10.3390/ijerph7030991

AMA Style

Bassil KL, Cole DC. Effectiveness of Public Health Interventions in Reducing Morbidity and Mortality during Heat Episodes: a Structured Review. International Journal of Environmental Research and Public Health. 2010; 7(3):991-1001. https://0-doi-org.brum.beds.ac.uk/10.3390/ijerph7030991

Chicago/Turabian Style

Bassil, Kate L., and Donald C. Cole. 2010. "Effectiveness of Public Health Interventions in Reducing Morbidity and Mortality during Heat Episodes: a Structured Review" International Journal of Environmental Research and Public Health 7, no. 3: 991-1001. https://0-doi-org.brum.beds.ac.uk/10.3390/ijerph7030991

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