Heat-Related Deaths
Identification
1. Indicator Description
Extreme heat events (i.e., heat waves) have become more frequent in the United States in recent
decades (see the High and Low Temperatures indicator), and studies project that the frequency and
intensity of extreme heat events will continue to increase as a consequence of climate change (USGCRP,
2017). When people are exposed to extreme heat, they can suffer from potentially deadly heat-related
illnesses such as heat exhaustion and heat stroke. Additionally, the incidence of deaths due to
cardiovascular disease (CVD) has been shown to increase with temperature, particularly among older
adults and other vulnerable populations such as non-Hispanic Blacks (Berko et al., 2014; Zanobetti et al.,
2012). Thus, as extreme heat events increase, the risk of heat-related deaths and illness is also expected
to increase (IPCC, 2014; Sarofim et al., 2016). Tracking the rate of reported overall heat-related deaths
and heat-related CVD deaths over time provides a measure of how climate change may affect human
well-being.
Components of this indicator include:
• The rate of U.S. annual deaths between 1979 and 2018 for which heat was classified on death
certificates as the underlying (direct) cause (Figure 1, orange line).
• The rate of U.S. summer deaths between 1999 and 2018 for which heat was classified as either
the underlying cause or a contributing factor (Figure 1, blue line).
• The rate of U.S. summer deaths between 1999 and 2018 for which cardiovascular disease was
classified as the underlying cause and heat was listed as a contributing factor (Figure 2). Rates
are shown for three groups: the general population, individuals age 65 and older, and non-
Hispanic Black individuals.
2. Revision History
April 2010: Indicator published.
December 2012: Updated indicator with data through 2009. Added contributing factors analysis to
complement the existing time series, converted the measure from counts to crude
rates, and added an example figure.
May 2014: Updated indicator with data through 2010.
June 2015: Updated indicator with data through 2013.
August 2016: Updated indicator with data through 2014. Added Figure 2 to show heat-related CVD
death rates.
April 2021: Updated indicator with data through 2018.
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Data Sources
3. Data Sources
This indicator is based on data from the U.S. Centers for Disease Control and Prevention's (CDC's)
National Vital Statistics System (NVSS), which compiles information from death certificates for nearly
every death in the United States. The NVSS is the most comprehensive source of mortality data for the
population of the United States. CDC provided analysis of NVSS data.
Mortality data for the illustrative example figure came from CDC's National Center for Health Statistics
(NCHS). The estimate of deaths in excess of the average daily death rate is from the National Research
Council's report on climate stabilization targets (NRC, 2011), which cites the peer-reviewed publication
Kaiser et al. (2007).
For reference, the illustrative example also shows daily maximum temperature data from the weather
station at the Chicago O'Hare International Airport (GHCND:USW00094846).
4. Data Availability
Underlying Causes
The long-term time series (1979-2018) in Figure 1 is based on CDC's Compressed Mortality File and
Detailed Mortality File, which can be accessed through the CDC WONDER online database at:
https://wonder.cdc.gov (CDC, 2020a, 2020b). CDC WONDER provides free public access to mortality
statistics, allowing users to query data for the nation as a whole or by state or region, demographic
group (age, sex, race), or International Classification of Diseases (ICD) code. Users can obtain the data
for this indicator by accessing CDC WONDER and querying the ICD codes listed in Section 5 for the entire
U.S. population.
Underlying and Contributing Causes
The 1999-2018 time series in Figure 1 is based on an analysis developed by the National Environmental
Public Health Tracking (EPHT) Program, which CDC coordinates. Monthly totals by state are available
online at: https://ephtracking.cdc.gov. but these data cannot be used to tabulate national totals
because numbers are withheld in states with a low number of cases. CDC also provides multi-year
summary statistics at: www.cdc.gov/mmwr/volumes/69/wr/mm6924al.htm. CDC staff from the
National Center for Environmental Health (NCEH) EPHT branch provided annual national totals to EPA
(CDC, 2020c).
Users can query underlying and contributing causes of death through CDC WONDER's Multiple Causes of
Death file (https://wonder.cdc.gov/mcd-icdlO.html). but note that EPHT performed additional steps for
Figure 1 that cannot be recreated through the publicly available data portal (see Section 6).
Underlying and Contributing Causes: Cardiovascular Disease
The 1999-2018 trend lines for heat-related CVD deaths in Figure 2 are based on underlying causes
(diseases of the circulatory system) and contributing causes (heat) data from CDC's Multiple Cause of
Death file, which can be accessed through the CDC WONDER online database at:
https://wonder.cdc.gov/mcd-icdlO.html (CDC. 2020b).
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Death Certificates
Individual-level data (i.e., individual death certificates) are not publicly available due to confidentiality
issues.
Chicago Heat Wave Example
Data for the example figure are based on CDC's Compressed Mortality File, which can be accessed
through the CDC WONDER online database at: https://wonder.cdc.gov. The analysis was obtained from
Kaiser et al. (2007). Daily maximum temperature data for 1995 from the Chicago O'Hare International
Airport weather station are available from the National Oceanic and Atmospheric Administration's
(NOAA's) National Centers for Environmental Information (NCEI) at: www.ncdc.noaa.gov/cdo-web.
Methodology
5. Data Collection
This indicator is based on causes of death as reported on death certificates. A death certificate typically
provides space to designate an immediate cause of death along with up to 20 contributing causes, one
of which will be identified as the underlying cause of death. The World Health Organization (WHO)
defines the underlying cause of death as "the disease or injury which initiated the train of events leading
directly to death, or the circumstances of the accident or violence which produced the fatal injury."
Causes of death are certified by a physician, medical examiner, or coroner, and are classified according
to a standard set of codes called the ICD. Deaths for 1979 through 1998 are classified using the Ninth
Revision of ICD (ICD-9). Deaths for 1999 and beyond are classified using the Tenth Revision (ICD-10).
Although causes of death rely to some degree on the judgment of the physician, medical examiner, or
coroner, the "measurements" for this indicator are expected to be generally reliable based on the
medical knowledge required of the "measurer" and the use of a standard classification scheme based on
widely accepted scientific definitions. When more than one cause or condition is entered, the underlying
cause is determined by the sequence of conditions on the certificate, provisions of the ICD, and
associated selection rules and modifications.
Mortality data are collected for the entire population and, therefore, are not subject to sampling design
error. For virtually every death that occurs in the United States, a physician, medical examiner, or
coroner certifies the causes of death on an official death certificate. State registries collect these death
certificates and report causes of death to the NVSS. NVSS's shared relationships, standards, and
procedures form the mechanism by which the CDC collects and disseminates the nation's official vital
statistics.
Standard forms for the collection of data and model procedures for the uniform registration of death
events have been developed and recommended for state use through cooperative activities of the
states and CDC's NCHS. All states collect a minimum data set specified by NCHS, including underlying
causes of death and basic demographic data (e.g., age, race, and ethnicity). CDC has published
procedures for collecting vital statistics data (CDC, 1995).
This indicator excludes deaths to foreign residents and deaths to U.S. residents who died abroad.
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General information regarding data collection procedures can be found in the Model State Vital
Statistics Act and Regulations (CDC, 1995). For additional documentation on the CDC WONDER database
(EPA's data source for part of this indicator) and its underlying sources, see:
https://wonder.cdc.gov/wonder/help/cmf.html.
CDC has posted a recommended standard certificate of death online at:
www.cdc.gov/nchs/data/dvs/DEATHll-03final-ACC.pdf. For a complete list and description of the ICD
codes used to classify causes of death, see: https://icd.who.int/browsel0/2019/en.
Chicago Heat Wave Example
The mortality data set shown in the example figure includes the entire Standard Metropolitan Statistical
Area for Chicago, a region that contains Cook County plus a number of counties in Illinois and Indiana,
from June 1 to August 31, 1995.
In the text box above the example figure, values reflect data from Cook County only. The number of
deaths classified as "heat-related" on Cook County death certificates between July 11 and July 27, 1995,
was reported to CDC by the Cook County Medical Examiner's Office. More information is available in
CDC's Morbidity and Mortality Weekly Report
(www.cdc.gov/MMWR/preview/mmwrhtml/00038443.htm). Deaths in excess of the average daily death
rate for Cook County were determined from death certificates obtained from the Illinois Department of
Public Health (Kaiser et al., 2007).
6. Indicator Derivation
This indicator reports annual rates of deaths per million population that have been classified with ICD
codes related to exposure to natural sources of heat. The NVSS collects data on virtually all deaths that
occur in the United States, meaning the data collection mechanism already covers the entire target
population. Thus, it was not necessary to extrapolate the results on a spatial or population basis. No
attempt has been made to reconstruct trends prior to the onset of comprehensive data collection, and
no attempt has been made to project data forward into the future.
Underlying Causes
The long-term trend line in Figure 1 reports the rate of deaths per year for which the underlying cause
had one of the following ICD codes:
• ICD-9 code E900: "excessive heat—hyperthermia"—specifically subpart E900.0: "due to
weather conditions."
• ICD-10 code X30: "exposure to excessive natural heat—hyperthermia."
This component of the indicator is reported for the entire year. EPA developed this analysis based on
the publicly available data compiled by CDC WONDER. EPA chose to use crude death rates rather than
death counts because rates account for changes in total population over time. Population figures are
obtained from CDC WONDER.
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Underlying and Contributing Causes
The "underlying and contributing causes" trend line in Figure 1 reports the rate of deaths for which
either the underlying cause or the contributing causes had one or more of the following ICD codes:
• ICD-10 code X30: "exposure to excessive natural heat—hyperthermia."
• ICD-10 codes T67.0 through T67.9: "effects of heat and light." Note that the T67 series is used
only for contributing causes—never for the underlying cause.
To reduce the chances of including deaths that were incorrectly classified, EPHT did not count the
following deaths:
• Deaths occurring during colder months (October through April). Thus, the analysis is limited to
May-September.
• Any deaths for which the ICD-10 code W92, "exposure to excessive heat of man-made origin/'
appears in any cause field. This step removes certain occupational-related deaths.
Foreign residents were excluded. EPHT obtained death counts directly from NVSS, rather than using the
processed data available through CDC WONDER. EPHT has not yet applied its methods to data prior to
1999. For a more detailed description of EPHT's analytical methods, see the indicator documentation at:
https://ephtracking.cdc.gov/showlndicatorPages.action. Crude death rates were calculated in the same
manner as with the underlying causes time series.
Underlying and Contributing Causes: Cardiovascular Disease
The lines in Figure 2 report crude rates of deaths for which diseases of the circulatory system were listed
as the underlying cause of death and heat was listed as a contributing factor. The underlying causes of
death for Figure 2 include the following ICD codes:
ICD-10 codes 100 through 102: "acute rheumatic fever."
ICD-10 codes 105 through 109: "chronic rheumatic heart diseases."
ICD-10 codes 110 through 115: "hypertensive diseases."
ICD-10 codes 120 through 125: "ischaemic heart disease."
ICD-10 codes 126 through 128: "pulmonary heart disease and diseases of pulmonary
circulation."
ICD-10 codes 130 through 151: "other forms of heart disease."
ICD-10 codes 160 through 169: "cerebrovascular disease."
ICD-10 codes 170 through 178: "diseases of arteries, arterioles and capillaries."
ICD-10 codes 180 through 189: "diseases of veins, lymphatic vessels and lymph nodes."
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• ICD-10 codes 195 through 199: "other and unspecified disorders of the circulatory system."
To associate diseases of the circulatory system (underlying cause) with heat, the following ICD codes
were evaluated as a contributing cause for each death:
• ICD-10 code X30: "exposure to excessive natural heat—hyperthermia."
• ICD-10 codes T67.0 through T67.9: "effects of heat and light."
Figure 2 presents data for three demographic groups: the general population, individuals age 65+, and
non-Hispanic Blacks. Specific query parameters were as follows:
• General population: all races and all age groups.
• Age 65+: all races and the following age groups: 65-74 years, 75-84 years, and 85+ years.
• Non-Hispanic Blacks: all age groups, Black or African American race, and Not Hispanic or Latino
origin.
EPA queried all data for Figure 2 directly from CDC WONDER at: https://wonder.cdc.gov/mcd-
icdlQ.html. To reduce the chances of including deaths that were incorrectly classified, EPA removed
deaths occurring during colder months (October through April). Thus, the analysis is limited to May-
September.
Chicago Heat Wave Example
The authors of Kaiser et al. (2007) determined that the Chicago area had 692 deaths in excess of the
background death rate between June 21 and August 10, 1995. This analysis excluded deaths from
accidental causes but included 183 deaths from "mortality displacement," which refers to a decrease in
the deaths of individuals who would have died during this period in any case but whose deaths were
accelerated by a few days due to the heat wave. This implies that the actual number of excess deaths
during the period of the heat wave itself (July 11-27) was higher than 692, but was compensated for by
reduced daily death rates in the week after July 27. Thus the value for excess deaths in Cook County for
the period of July 11-27 is reported as approximately 700 in the text box above the example figure.
7. Quality Assurance and Quality Control
Vital statistics regulations have been developed to serve as a detailed guide to state and local
registration officials who administer the NVSS. These regulations provide specific instructions to protect
the integrity and quality of the data collected. This quality assurance information can be found in CDC
(1995).
For the "underlying and contributing causes" component of this indicator, extra steps have been taken
to remove certain deaths that could potentially reflect a misclassification (see Section 6). These criteria
generally excluded only a small number of deaths.
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Analysis
8. Comparability Over Time and Space
When plotting the long-term data in Figure 1, EPA inserted a break in the line between 1998 and 1999 to
reflect the transition from ICD-9 codes to ICD-10 codes. The change in codes makes it difficult to
accurately compare pre-1999 data with data from 1999 and later. Otherwise, all methods have been
applied consistently over time and space. ICD codes allow physicians and other medical professionals
across the country to use a standard scheme for classifying causes of deaths.
9. Data Limitations
Factors that may impact the confidence, application, or conclusions drawn from this indicator are as
follows:
1. It has been well-documented that many deaths associated with extreme heat are not identified
as such by the medical examiner and might not be properly coded on the death certificate. In
many cases, they might just classify the cause of death as a cardiovascular or respiratory
disease. They might not know for certain whether heat was a contributing factor, particularly if
the death did not occur during a well-publicized heat wave. By studying how daily death rates
vary with temperature in selected cities, scientists have found that extreme heat contributes to
far more deaths than the official death certificates would suggest (Medina-Ramon and
Schwartz, 2007). That is because the stress of a hot day can increase the chance of dying from a
heart attack, other heart conditions, and respiratory diseases such as pneumonia (Kaiser et al.,
2007). These causes of death are much more common than heat-related illnesses such as heat
stroke. Thus, this indicator very likely underestimates the number of deaths caused by
exposure to heat. However, it does serve as a reportable national measure of overall deaths
and CVD deaths attributable to heat.
2. ICD-9 codes were used to specify underlying cause of death for the years 1979 to 1998.
Beginning in 1999, cause of death was specified with ICD-10 codes. The two revisions differ
substantially, so data from before 1999 cannot easily be compared with data from 1999 and
later.
3. The fact that a death is classified as "heat-related" does not mean that high temperatures were
the only factor that caused the death. Pre-existing medical conditions can greatly increase an
individual's vulnerability to heat.
4. Heat waves are not the only factor that can affect trends in "heat-related" deaths. Other
factors include the vulnerability of the population, the extent to which people have adapted to
higher temperatures, the local climate and topography, and the steps people have taken to
manage heat emergencies effectively. In particular, heat-response measures can make a big
difference in death rates. Response measures can include early warning and surveillance
systems, air conditioning, increased access to cooling centers, health care, public education,
infrastructure standards, and air quality management. For example, after a 1995 heat wave,
the city of Milwaukee developed a plan for responding to extreme heat conditions in the
future. During a 1999 heat wave, this plan cut heat-related deaths nearly in half compared with
what was expected (Weisskopf et al., 2002).
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Other studies may shed some light on the extent of undercounting inherent in this data set. As
described in Sarofim et al. (2016), some statistical approaches estimate that more than 1,300 deaths per
year in the United States are due to extreme heat, compared with about 600 deaths per year in the
"underlying and contributing causes" data set shown in Figure 1. The Chicago heat wave example shows
that a single extreme heat event likely caused about 700 deaths that would not otherwise have occurred
during that time period, even though only 465 deaths were attributed to extreme heat on death
certificates during that period.
10. Sources of Uncertainty
Uncertainty estimates are not available for this indicator. Because statistics have been gathered from
virtually the entire target population (i.e., all deaths in a given year), these data are not subject to the
same kinds of errors and uncertainties that would be inherent in a probabilistic survey or other type of
representative sampling program.
Some uncertainty could be introduced as a result of the professional judgment required of the medical
professionals filling out the death certificates, which could potentially result in misclassification or
underreporting in some number of cases.
11. Sources of Variability
There is substantial year-to-year variability within the data, due in part to the influence of a few large
events. Many of the spikes apparent in Figures 1 and 2 can be attributed to specific severe heat waves
occurring in large urban areas.
12. Statistical/Trend Analysis
This indicator does not report on the slope of the apparent trends in heat-related deaths, nor does it
calculate the statistical significance of these trends.
References
Berko, J., D.D. Ingram, S. Saha, and J.D. Parker. 2014. Deaths attributed to heat, cold, and other weather
events in the United States, 2006-2010. National Health Statistics Reports, Number 76. National Center
for Health Statistics, www.cdc.gov/nchs/data/nhsr/nhsr076.pdf.
CDC (U.S. Centers for Disease Control and Prevention). 1995. Model State Vital Statistics Act and
Regulations (revised April 1995). DHHS publication no. (PHS) 95-1115.
www.cdc.gov/nchs/data/misc/mvsact92aacc.pdf.
CDC (U.S. Centers for Disease Control and Prevention). 2020a. Mortality data on CDC WONDER:
Underlying cause-of-death: All ages deaths from compressed mortality: Mortality for 1999-2016 with
ICD 10 codes, mortality for 1979-1998 with ICD 9 codes. Accessed June 2020.
https://wonder.cdc.gov/mortSQL.html.
CDC (U.S. Centers for Disease Control and Prevention). 2020b. Underlying cause of death, 1999-2018
request. Accessed June 2020. https://wonder.cdc.gov/mcd-icdlO.html.
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CDC (U.S. Centers for Disease Control and Prevention). 2020c. Indicator: Heat-related mortality. National
Center for Health Statistics. Annual national totals provided by National Center for Environmental Health
staff in July 2020. https://ephtracking.cdc.gov.
IPCC (Intergovernmental Panel on Climate Change). 2014. Climate change 2014: Impacts, adaptation,
and vulnerability. Working Group II contribution to the IPCC Fifth Assessment Report. Cambridge, United
Kingdom: Cambridge University Press, https://ipcc.ch/report/ar5/wg2.
Kaiser, R., A. LeTertre, J. Schwartz, C.A. Gotway, W.R. Daley, and C.H. Rubin. 2007. The effect of the
1995 heat wave in Chicago on all-cause and cause-specific mortality. Am. J. Public Health 97(Supplement
1):S158-S162.
Medina-Ramon, M., and J. Schwartz. 2007. Temperature, temperature extremes, and mortality: A study
of acclimatization and effect modification in 50 U.S. cities. Occup. Environ. Med. 64(12):827-833.
NRC (National Research Council). 2011. Climate stabilization targets: Emissions, concentrations, and
impacts over decades to millennia. Washington, D.C.: National Academies Press.
Sarofim, M.C., S. Saha, M.D. Hawkins, D.M. Mills, J. Hess, R. Horton, P. Kinney, J. Schwartz, and A. St.
Juliana. 2016. Chapter 2: Temperature-related death and illness. In: The impacts of climate change on
human health in the United States: A scientific assessment. U.S. Global Change Research Program.
https://health2016.globalchange.gov.
USGCRP (U.S. Global Change Research Program). 2017. Climate science special report: Fourth National
Climate Assessment, volume I. Wuebbles, D.J., D.W. Fahey, K.A. Hibbard, D.J. Dokken, B.C. Stewart, and
T.K. Maycock (eds.). https://science2017.globalchange.gov. doi:10.7930/J0J964J6
Weisskopf, M.G., H.A. Anderson, S. Foldy, L.P. Hanrahan, K. Blair, T.J. Torok, and P.D. Rumm. 2002. Heat
wave morbidity and mortality, Milwaukee, Wis, 1999 vs. 1995: An improved response? Am. J. Public
Health 92:830-833.
Zanobetti, A., M.S. O'Neill, C.J. Gronlund, and J.D. Schwartz. 2012. Summer temperature variability and
long-term survival among elderly people with chronic disease. P Natl. Acad. Sci. USA 109(17):6608-6613.
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