Background: Several studies have identified strong effects of high temperatures on mortality at population level; however, individual vulnerability factors associated with heat-related in-hospital mortality are largely unknown. The objective of the study was to evaluate heat-related in-hospital mortality using a multi-city case-crossover analysis.
Methods: We studied residents of four Italian cities, aged 65+ years, who died during 1997–2004. For 94 944 individuals who died in hospital and were hospitalised two or more days before death, demographics, chronic conditions, primary diagnoses of last event and hospital wards were considered. A city-specific case-crossover analysis was performed to evaluate the association between apparent temperature and mortality. Pooled odds ratios (OR) of dying on a day with a temperature of 30°C compared to a day with a temperature of 20°C were estimated with a random-effects meta-analysis.
Results: We estimated an overall OR of 1.32 (95% confidence interval: 1.25, 1.39). Age, marital status and hospital ward were important risk indicators. Patients in general medicine were at higher risk than those in high and intensive care units. A history of psychiatric disorders and cerebrovascular diseases gave a higher vulnerability. Mortality was greater among patients hospitalised for heart failure, stroke and chronic pulmonary diseases.
Conclusions: In-hospital mortality is strongly associated with high temperatures. A comfortable temperature in hospitals and increased attention to vulnerable patients during heatwaves, especially in general medicine, are necessary preventive measures.
Statistics from Altmetric.com
After the disturbing increase in number of deaths observed in several European countries during the summer of 2003,1 2 a considerable research effort is being conducted to evaluate the impact of the high temperature-related mortality,3–5 the geographical differences in the impact,6 the development of watching/warning systems7 8 and the specific individual social and clinical factors that confer susceptibility to heat stress, especially among the elderly.9 People living alone and of low socioeconomic status seem to be particularly vulnerable.10 11 The research efforts are also intended to guide acute medical care, public health interventions and social services during heatwaves.
We have recently reported the results of a multi-city, population-based, case-crossover analysis conducted in four Italian cities to evaluate the overall impact of heat-related mortality and the specific subpopulations that are vulnerable to hot weather.9 Extensive record linkage procedures were used to characterise mortality records for subjects aged 35+ with respect to previous morbidity. We found that the elderly, women, widows/widowers and subjects with psychiatric disorders, depression, heart conduction disorders and previous stroke are at higher risk of dying during extremely hot days. Unexpectedly, we found that the increase in mortality caused by high temperature was not limited to individuals residing in private or nursing homes (as suggested in the literature12) but also among those in hospital. This finding has been explained by the lack of air conditioning facilities in Italian hospitals during the period of the study.
The results of the previous study have public health implications. If a large proportion of heat-related mortality occurs among already hospitalised people, public health activities during heatwaves should not be concentrated solely on susceptible populations at home but also towards people who are already under medical care in hospitals. A study conducted in France during summer 2003 clearly suggested that hospital-acquired heat stroke is a nosocomial disease.13 Therefore, it is important to understand the specific vulnerability factors for those individuals who are already in hospital during heatwave events.
The aim of the present study was to evaluate hospital-related factors, demographic and clinical characteristics that increase heat-related mortality among hospitalised patients during a heatwave. In the present study, the dataset of the largest city has been extended to include 2004, we have focused on elderly subjects (65+ years) and the analysis has been restricted to patients who were already hospitalised two days before death, and thus were inside a care facility when exposed to hot weather.
MATERIALS AND METHODS
The original study has been conducted among 205 019 subjects aged 35+ years, residing and dying in four Italian cities from all non-injury causes (International Classification of Diseases, 9th revision, ICD-9: 1–799) in the following periods: 2000–3 in Bologna, 1999–2003 in Milan, 1998–2001 in Rome and 1997–2003 in Turin.9 We have now extended to 2004 the data collection for Rome so as to encompass 267 611 individuals. Since the previous analysis showed that heat-related mortality was clearly present among the elderly, for the present study we have restricted the analysis to 228 596 subjects aged 65+ years.
Data sources were the Regional Registers of Causes of Death (causes of deaths already coded) and the Regional Hospital Discharge files (which include hospitalisations in public and private hospitals nationwide of all resident citizens). A record linkage was performed (using the individual fiscal code) to attribute hospitalisation history of the past two years for each deceased subject. We collected information on gender, age, marital status, median income of the census block of residence and location of death. The information on income was used to attribute to each subject a socioeconomic level according to one of four categories from the city-specific distribution: up to the 20th percentile, 20th–50th percentile, 50th–80th percentile and 80th–100th percentile. These percentiles were chosen to better discriminate between extreme and intermediate social conditions. The use of city-specific distributions, rather than the cumulative one, was motivated by the city-specific analysis in the first stage (see below) and the need to better represent local situations. Given the administrative nature of our sources, we could not collect other individual factors, like tobacco smoke or alcohol consumption.
Considering location of death, date of hospitalisation and date of death, we distinguished between those who died in a nursing home, died out of hospital, died in hospital and were hospitalised during the last two days before death, died in hospital and were hospitalised two or more days before death. For the latter subgroup, we considered the type of the hospital (public under the Italian National Health Service (NHS), private but with a financial agreement with the NHS, and entirely private) and the specific hospital ward where the patient was present two days before death (general medicine, medical or surgical wards with low-moderate care load, medical or surgical wards with high care load, intensive care units).
For each individual, all hospital admissions during the two years preceding death (excluding the last 28 days) were selected, considering both primary causes of admission and secondary contributing diagnoses. Each subject was classified according to having been hospitalised for a list of 26 groups of diagnoses chosen by adapting the Elixauser list of comorbidities.14 The 28-day window was applied to distinguish between chronic conditions and a sudden deterioration of health in the few weeks or days before death.
Finally, we evaluated the acute clinical conditions that contributed to the fatal outcome considering a selected group of conditions noted as primary diagnoses on the hospitalisation records during the last 28 days. In most of the cases, the hospitalisation record was the last one on which the fatal outcome was recorded.
Daily information on temperature, humidity and barometric pressure were provided by the Italian Air Force Meteorological Service. The average of the current and the preceding day mean apparent temperature (lag 0–1) was used as the exposure variable15 on the basis of previous investigations.12 Apparent temperature is a composite index which combines information from air temperature and humidity, and better takes into account the actual physical stress in the warmer days. We also collected daily mean data on particulate matter with aerodynamic diameter lower than 10 μm, PM10 (lag 0–1), and ozone (daily maximum 8-hour running mean, lag 0) from the regional environmental protection agencies, since air pollution has been associated with short-term increase in mortality (a separate report on air pollution and mortality is in preparation).
The methods for data analysis have been extensively explained elsewhere.9 Briefly, the association between apparent temperature and daily mortality was analysed using the case-crossover approach,16 with the time-stratified strategy for the selection of control days.17 Each case-day was compared with a set of control-days matched on the year, month and day of the week by fitting a city-specific conditional logistic regression model, and the results were finally pooled in a random-effects meta-analysis.18
Since the relation between temperature and mortality turned out to be J-shaped, we first explored the concentration-response function by adapting a cubic penalised spline of apparent temperature for each centre, and then approximated the smooth curves with three straight lines so as to simplify the relation while at the same time taking into account the main curvature of the function. The models also controlled for PM10, influenza epidemics (defined on the basis of the weekly estimates of influenza incidence, as reported by the Italian NHS), population decrease during the vacation periods, holidays and barometric pressure, while time-trends and day of the week were controlled for by design. No need to control for ozone was evident from exploratory analyses.
The results are expressed as pooled odds ratios (OR), with 95% confidence intervals (95% CI), of dying on a day with a 30°C apparent temperature relative to a day with a 20°C apparent temperature. We investigated the potential effect modification of sociodemographic characteristics, hospital characteristics, chronic and acute clinical conditions by calculating ORs in the subgroup of interest and in the reference category. Since possible effect modification may be due to age differences of the compared subgroups, all the analyses were repeated with adjustment for age (three groups, 65–74, 75–84 and 85+) using as standard weights the frequency distribution of age in the whole population. The relative effect modification (REM) index, calculated as the ratio between the OR of the specific category by the OR of the reference category, provides a useful measure of effect modification together with its p value.
Rome is located in central Italy and it is the largest city in the study; Turin, Milan and Bologna are located in northern Italy, are smaller than Rome and have slightly different meteorological conditions. Environmental data and city-specific mortality counts by place of death are reported in table 1.
Rome displays the most concentrated distribution of mean apparent temperature, while Bologna and Milan the most dispersed. The difference between apparent temperature in case-days and the respective control-days, considered the relevant exposure indicator in case-crossover studies,19 is also reported. We computed the differences between all control-days and their case-day so that the different number of control-days (three or four) was considered. The four distributions are centred on zero, and show little difference in the interquartile ranges between cities, with Rome having slightly less variability. At the bottom of the table, the city-specific numbers of subjects are shown. Out of a total of 228 596 individuals older than 64 years, 10 041 died in a nursing home (information available for Milan and Turin only), 96 451 died out of hospital, 27 155 died within the two days after being hospitalised, and 94 944 died two days or more after hospitalisation (five missing information for Bologna).
The overall OR for the total population of 65+ years of the four cities was 1.40 (95% CI: 1.29 to 1.51)—namely, there was a 40% increase in mortality at 30°C when compared with 20°C after adjustment for several factors. Figure 1 shows how the association between temperature and mortality varies by location of death, with the highest OR recorded for subjects in nursing homes or in hospital for less than two days (OR: 1.63; 95% CI: 1.42 to 1.86, and OR: 1.46; 95% CI: 1.26 to 1.70, respectively) and an intermediate effect was estimated for out-of-hospital deaths (OR: 1.40; 95% CI: 1.26 to 1.55), whereas subjects hospitalised for more than two days who died in hospital had an OR of 1.32 (1.25 to 1.39), which is the lowest effect but still highly statistically significant.
All the additional analyses were restricted to the last subgroup of subjects already within a hospital when exposed to the lagged apparent temperature.
Table 2 shows the results of the subgroup analysis by sociodemographic and hospital characteristics.
Unadjusted and age-adjusted ORs are reported, with the summary index of relative effect modification (REM) and p values. Gender does not seem to play an important role in the temperature-mortality association in this population (although a slightly higher risk is present among women), while age increases the risk of heat-related death with a higher odds ratio (1.50; 95% CI: 1.35 to 1.66) found for those 85+ years. Not married, divorced and widowed patients were at higher risk of dying from heat stress (OR: 1.42) than married people (OR: 1.16), and the difference remains when adjusting for age. Income shows a uniform effect among the four categories. The risk of dying was not modified by the type of hospital, whereas the specific hospital ward was a significant effect modifier in the analysis not adjusted for age, with subjects in general medicine having a higher risk of death (OR: 1.40) than those hospitalised in other wards, suggesting a reduction of the risk in the more specialised departments and intensive care units. However, this pattern was less clear when adjusting for age.
The simultaneous effect modification by age (three classes) and hospital ward is reported in table 3.
In all age groups, subjects in general medicine were always at high and statistically significant risk of dying due to high temperature. However, people younger than 85 years were less affected by high summer temperatures when they were admitted in wards other than general medicine and the effect becomes nil in intensive care units. These differences, however, do not hold for the 85+ years age group, where the point estimate for those in intensive care units (a total of 1505 subjects) is the highest (OR: 1.82; 95% CI: 1.20 to 1.77). The online table reports the distribution of acute medical conditions of the patients by age groups and hospital wards. The relative frequencies of various conditions, especially acute myocardial infarction and cerebrovascular diseases, are different by ward type, but these differences are similar across the age groups investigated.
Table 4 shows the unadjusted and age-adjusted ORs for 26 groups of diagnoses figuring as the primary or secondary cause of hospital admission in the two years before death, with the exclusion of the last four weeks. The REM indicates the comparison between the subjects with the specific condition and those without it.
Psychiatric disorders and cerebrovascular diseases are the most important effect modifiers with ORs of 2.05 (1.44 to 2.93) and 1.50 (1.32 to 1.70), respectively, and p values of REM Indexes lower than 0.10. In addition, a previous diagnosis of diseases of the central nervous system (other than paralyses), heart conduction disorders and hip fracture seem to confer a higher vulnerability, although the p values for REM are far from significant. On the contrary, hospitalised subjects with a previous history of cancer or with fluid and electrolyte disorders have a lower relative risk of dying during hot days (OR: 1.18; 95% CI: 1.03 to 1.36 and OR: 0.94; 95% CI: 0.63 to 1.41, respectively). No noticeable effect modification was detected for the other conditions.
When we evaluated the role of the acute conditions leading to death (table 5), heart failure (OR: 1.69; 1.34 to 2.14), cerebrovascular diseases (OR: 1.59; 1.37 to 1.84) and chronic pulmonary diseases (OR: 2.48; 1.50 to 4.09) emerged as strongly associated with heat-related mortality, with REM indexes statistically significant at the 5% level. Similarly, changes of pulmonary circulation, which is usually related to lung diseases and failure of the right side of the heart, were also associated with increase in mortality related to high temperature.
The study confirms that high summer temperatures are associated with an increase in mortality among patients already in hospital at the time of the heat stress. In the age group 65–84 years, the hospital ward is an important effect modifier as higher heat-related mortality was found in general medicine wards, whereas no increased risk due to heat was found in intensive care units. On the other hand, for those aged 85+ this effect modification was not present. The susceptibility factors identified in this high-risk population are similar to what has been observed on the entire population living in the four cities.9 Being alone (widow or not married), previous psychiatric and cerebrovascular disorders are strong risk factors as shown in the previous study, but unexpectedly there was no higher risk among women. Finally, acute heart failure (including changes of pulmonary circulation—that is, cor pulmonale), stroke and exacerbations of chronic pulmonary disease are strong risk indicators of heat-related mortality.
From the study design adopted, it is clear that we have studied a selected group of high-risk patients. For elderly people at home, living conditions including availability of air conditioning, family, social and medical support, as well as presence of chronic comorbidities are likely to be the important modifiers of the effect of summer temperatures on mortality. In the case of hospitalised patients, the hospital and ward characteristics including availability of thermal comfort, quality of medical care, and severity of the acute clinical conditions are likely important risk indicators. Unfortunately, there are no official statistics on the availability of air conditioning in Italian health care centres. It is known, however, that most of the hospitals in the cities we have investigated did not have air conditioning at the time of the study, except for operating rooms and intensive care units. The increased risk of heat-related mortality in general medicine among 65–84-year-olds may be interpreted as the result of various factors, such as the absence of air conditioning in these wards, lower attention to the medical care needs of the patients and a specific case-mix (for example, heart failure, cerebrovascular diseases, and chronic pulmonary diseases, as indicated in the online table). However, we also found an increased heat-related mortality in intensive care units among individuals aged 85+ years that cannot be simply explained by the most common acute medical conditions of these patients (for example, myocardial infarction). It should be noted that a study conducted in France during summer 2003 suggests that heat-related deaths may be observed in intensive care during heat waves, especially if air conditioning is lacking.20
The increased risk found among the single and widowed people, which is similar to what has been found in the previous study conducted on out-of-hospital deaths,9 indicates that family and social support may also be relevant for hospitalised patients. The lack of a family support may be associated with a more isolated hospital stay and a limited attention to individual requirements, including adequate fluid and electrolyte repletion. The attention on these aspects is usually under the control of hospital nurses who may not be in sufficient number or may lack appropriate instructions. Similarly, patients with psychiatric disorders and with a previous cerebrovascular accident, both requiring specific medical control, are more at risk of dying in the hospital during heatwaves, presumably because of inadequate medical care.
In order to discuss the specific results for the acute clinical conditions, some methodological aspects should be considered. As previously indicated, the case-crossover design is a powerful method to evaluate the effect of environmental variables and to test for effect modification. The extensive record linkage procedures of individual data from different sources offered us the opportunity to exploit individual information, a condition that is rarely available in environmental epidemiology. On the other hand, the quality of the clinical variables considered, based on hospital discharge files, suffers from a series of limitations.21 We have tried to increase the sensitivity of the definition of chronic conditions by using all the hospital admissions in the 29-day to 2-year period before death and considering both primary and contributory causes. The information is independent of the patient’s final outcome and possible biases can be excluded. The study of the clinical conditions which characterised the subjects in the few weeks before death is more complex. The information from the last hospitalisation record was used, which in most of the cases coincides with the fatal outcome. In order to increase the specificity of the definition, the analysis was restricted to primary causes only. However, we cannot evaluate whether the acute clinical conditions actually precede the effect of heat (in other words are real effect modifiers) or if these conditions represent the ultimate cause of death due to heat stress.
Given the limitation indicated above, it is noteworthy that heart failure, stroke and chronic pulmonary diseases are associated with an increased heat-related mortality. The results for cerebrovascular diseases are not surprising since this is a condition that has been associated with heat exposure in clinical studies, and increased platelet, red cell counts and blood viscosity have been noted among volunteers exposed to heat.22 23 Moreover, it has been shown that body heat stress reduces baseline cerebral blood velocity and increases cerebral vascular resistance.24 Recent clinical evidence suggests that tolerance to heat stress may be impaired in patients with cardiovascular diseases, particularly those associated with impaired ventricular function and congestive heart failure as they exhibit attenuated cutaneous vasodilator responses to heating, a potential mechanism for heat intolerance.25 The extremely high risk found for patients with chronic pulmonary diseases is a new finding that requires further confirmation. These patients are likely to be admitted for an acute exacerbation, also for respiratory infection, and they generally have respiratory failure and are at high risk because of pulmonary hypertension and cor pulmonale.26 Increased mortality due to respiratory conditions during hot days has been described in several time-series studies.27 However, the specific mechanism among patients with chronic pulmonary diseases that confers such a strong vulnerability should be researched.
In conclusion, we have indicated that patients admitted to the hospital two or more days before relevant heat-stress conditions are at increased risk of dying in hospital wards because of extreme heat. It seems that the hospital care available does not provide sufficient protection for these patients, especially if they are hospitalised in general medical wards. Heart failure, stroke and chronic pulmonary diseases are associated with an increased heat-related mortality. Better hospital conditions as well as more intensive health care for high-risk patients during the critical days of increased temperature may result in a significant health gain.
What is already known
Epidemiological research indicates that high summer temperatures are strongly associated with increased mortality in the general population. It is not known whether increase in temperature is associated with mortality among already hospitalised patients. Susceptibility factors of hospitalised subjects in relation to high temperatures are not known.
What this paper adds
Temperature-related mortality is high among patients already hospitalised at the time of a heatwave.
Elderly subjects and those hospitalised in general medicine wards are especially vulnerable.
Acute heart failure, stroke and exacerbation of chronic pulmonary diseases are associated with an increased heat-related mortality among hospitalised patients.
It emerges that the hospital care available does not provide sufficient protection to vulnerable patients, especially if they are hospitalised in general medicine and low-care wards. Better hospital conditions as well as more intensive health care for high-risk patients during the critical days of increased temperature may result in a significant health gain.
Funding: partially supported by the Italian Department of Civil Protection (contract number: 491, 15/04/04).
Competing interests: None.
If you wish to reuse any or all of this article please use the link below which will take you to the Copyright Clearance Center’s RightsLink service. You will be able to get a quick price and instant permission to reuse the content in many different ways.