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Long-term mortality of hospitalized pneumonia in the EPIC-Norfolk cohort

Published online by Cambridge University Press:  24 August 2015

P. K. MYINT*
Affiliation:
AGEING (Aberdeen Gerontological & Epidemiological Interdisciplinary Research Group), Epidemiology Group, Institute of Applied Health Sciences, School of Medicine & Dentistry, University of Aberdeen, Aberdeen, Scotland, UK Academic Centre for Applied Clinical & Translational Research into Ageing (ACTRA), Department of Medicine for the Elderly, Aberdeen Royal Infirmary, NHS Grampian, Aberdeen, Scotland, UK Norwich Medical School, University of East Anglia, Norwich Research Park, Norwich, UK Clinical Gerontology Unit, Department of Public Health & Primary Care, School of Clinical Medicine, University of Cambridge, Cambridge, UK
K. R. HAWKINS
Affiliation:
Department of Respiratory Medicine, Norfolk and Norwich University Hospital, Norwich, UK
A. B. CLARK
Affiliation:
Norwich Medical School, University of East Anglia, Norwich Research Park, Norwich, UK
R. N. LUBEN
Affiliation:
Strangeway Research Laboratory, Department of Public Health & Primary Care, Cambridge, UK
N. J. WAREHAM
Affiliation:
MRC-Epidemiology Unit, Institute of Metabolic Science, Addenbrooke's Hospital, Cambridge, UK
K.-T. KHAW
Affiliation:
Clinical Gerontology Unit, Department of Public Health & Primary Care, School of Clinical Medicine, University of Cambridge, Cambridge, UK
A. M. WILSON
Affiliation:
Norwich Medical School, University of East Anglia, Norwich Research Park, Norwich, UK Department of Respiratory Medicine, Norfolk and Norwich University Hospital, Norwich, UK
*
*Author for correspondence: Professor P. K. Myint, 4:013 Polwarth Building, School of Medicine & Dentistry, University of Aberdeen, Foresterhill, Aberdeen AB25 2ZD, UK. (Email: phyo.myint@abdn.ac.uk)
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Summary

Little is known about cause-specific long-term mortality beyond 30 days in pneumonia. We aimed to compare the mortality of patients with hospitalized pneumonia compared to age- and sex-matched controls beyond 30 days. Participants were drawn from the European Prospective Investigation into Cancer (EPIC)-Norfolk prospective population study. Hospitalized pneumonia cases were identified from record linkage (ICD-10: J12-J18). For this study we excluded people with hospitalized pneumonia who died within 30 days. Each case identified was matched to four controls and followed up until the end June 2012 (total 15 074 person-years, mean 6·1 years, range 0·08–15·2 years). Cox regression models were constructed to examine the all-cause, respiratory and cardiovascular mortality using date of pneumonia onset as baseline with binary pneumonia status as exposure. A total of 2465 men and women (503 cases, 1962 controls) [mean age (s.d.) 64·5 (8·3) years] were included in the study. Between a 30-day to 1-year period, hazard ratios (HRs) of all-cause and cardiovascular mortality were 7·3 [95% confidence interval (CI) 5·4–9·9] and 5·9 (95% CI 3·5–9·7), respectively (with very few respiratory deaths within the same period) in cases compared to controls after adjusting for age, sex, asthma, smoking status, pack years, systolic and diastolic blood pressure, diabetes, physical activity, waist-to-hip ratio, prevalent cardiovascular and respiratory diseases. All outcomes assessed also showed increased risk of death in cases compared to controls after 1 year; respiratory cause of death being the most significant during that period (HR 16·4, 95% CI 8·9–30·1). Hospitalized pneumonia was associated with increased all-cause and specific-cause mortality beyond 30 days.

Type
Original Papers
Copyright
Copyright © Cambridge University Press 2015 

INTRODUCTION

Pneumonia is common and in combination with influenza is the fifth leading cause of death in the UK [1]. It is the third leading cause of death globally accounting for 7·1% of all deaths along with other lower respiratory tract infections [Reference Mathers, Fat and Boerma2]. Pneumonia is also one of the main causes of hospital admissions [Reference Guest and Morris3] and according to US statistics up to 10–20% of all hospitalizations with pneumonia require treatment in the intensive care unit [Reference File and Marrie4]. The short-term mortality from pneumonia is well documented and is consistently between 10% and 11% [Reference Lave5, Reference Marrie6]. Mortality from pneumonia is typically assessed at 30 days or at discharge from hospital [Reference Eurich, Majumdar and Marrie7, Reference Hoo and Hyung8] and patients who have clinical resolution of their symptoms at this time are classified as having survived the episode [Reference Ramirez and Anzueto9].

It is also suggested that pneumonia produces a chronic inflammatory response which may accelerate the process of cardiovascular disease in the intermediate term [Reference Yende10]. Indeed, it has been shown in a study of 1799 patients hospitalized with pneumonia, that those with raised pro-inflammatory cytokines at discharge had an increased risk of cardiovascular death at 1 year, which was independent of the severity of the pneumonia [Reference Yende10]. More recent studies suggest that pneumonia may influence the patient's longer term survival [Reference Yende11Reference Johnstone14]. Mortality was 10% higher at 1 year for elderly patients with pneumonia compared to other hospitalized survivors [Reference Kaplan15] and although few studies have analysed specific cause of death post-pneumonia diagnosis, cardiovascular disease caused a third of all deaths from 300 patients at 1-year follow-up in a hospital-based study [Reference Yende10].

It is not known whether pneumonia has impact on longer term mortality in an unselected general population and whether it is linked to cardiovascular cause of death post-1 year follow-up. While there appears to be a greater incidence of cardiovascular disease at 1 year following pneumonia, the risk of cardiovascular disease at different time points post-pneumonia diagnosis has not been assessed. The goals of this study were to examine the association of hospitalized pneumonia on both short (⩾30 days up to 1 year) and long-term all-cause and cause-specific mortality focusing on respiratory and cardiovascular causes of death in a general population of middle and older age participants after taking into account potential confounders.

MATERIALS AND METHODS

Study population

All study participants were selected from the participants of European Prospective Investigation into Cancer (EPIC)-Norfolk prospective population-based cohort study. This cohort forms part of a Europe-wide multicentre prospective population study, primarily designed to investigate the relationship between diet and cancer. The study was approved by the Norwich Research Ethics Committee (R&D reference no. 98CN01).

The methods of the EPIC-Norfolk study have been described in depth elsewhere [Reference Day16]. The Norfolk population is a mix of urban and rural populations and has high coverage of primary-care physicians (General Practitioners). It is for the most part representative of the UK population; however, there is lower ethnic diversity in this area than the general UK population and the EPIC-Norfolk cohort is 99·6% white. Briefly, participants were men and women aged 40–79 years recruited between 1993 and 1998. Participants underwent a detailed baseline health examination in which demographic, physiological and behavioural factors were ascertained. This included prevalent illness, smoking status, body mass index (BMI) measured using standard protocols [Reference Day16]. They were followed up for health events using record linkage.

Hospitalized cases of pneumonia were identified through linkage with hospital records using ICD-10 J12-J18. A total of 1064 cases and 4120 controls (1:4) matched for age, sex and year of recruitment in the EPIC-Norfolk were included. All participants who reported cancer, myocardial infarction and stroke at the EPIC-Norfolk study baseline were excluded. To reduce the bias of excess mortality within 30 days from respiratory cause of death of cases which are identified through death certification from the Office of National Statistics (ONS), we excluded any cases who died within 30 days of hospitalization and their matched controls leaving 503 cases and 1962 controls for the analyses. The start date for analysis for the current study was the date of diagnosis of pneumonia for cases and the same date for case-matched controls. The study follow-up period was from the start date to date of death or end of follow-up (end of June 2012). Prevalent cardiovascular disease (CVD) for the current report was defined as a new diagnosis of CVD after EPIC-Norfolk enrolment but made before the pneumonia date for cases and respective corresponding date for controls.

Outcome measurements

The primary outcome of interest was all-cause mortality. Secondary outcomes were respiratory mortality and cardiovascular mortality. Mortality data were obtained from linkage with ONS in UK. Mortality was assessed between 30 days and <1 year for short term and ⩾1 year for long term [Reference Yende11, Reference Johnstone14, Reference Myles17]. Specific causes of death were coded by a nosologist with ICD-10 codes J00-J99 (ICD-9: 460–496) for respiratory causes, and ICD-10 codes L10–179 (ICD-9: 401–448) for cardiovascular causes, respectively.

Statistical analysis

Statistical analyses were conducted using Stata v. 11·2/SE (StatCorp, USA). The baseline characteristics were given as means and standard deviations for normally distributed continuous data and by number and percentages for categorical data. Comparisons between groups at baseline were based on univariable conditional logistic regression models in order to take into account the non-independence due to the matching of cases and controls. Respiratory and cardiovascular mortality in pneumonia cases compared to controls were analysed at different time-frames. The cut-off between short-term and long-term mortality were 1 year and until the end of follow-up, respectively.

The difference in mortality in pneumonia cases compared to controls was examined using Cox regression [Reference Cox18] with a frailty term to account for the non-independence due to the matching of cases and controls. Covariates in the multiple variable models were chosen for the characteristics that differ significantly between group means for at least one cause of mortality using Cox regression on all of the available risk factors (Table 1) by univariate analysis. Multivariate analysis was thus adjusted for history of asthma, smoking status, pack years, forced expiratory volume 1 (FEV1), forced vital capacity (FVC), and physical activity levels (as outlined previously [Reference Day16]), waist-to-hip ratio, diabetes mellitus, pre-existing CVD and pre-existing respiratory disease. A final model was constructed after additionally adjusting for aspirin use (statin use was not included as there were too few participants who were on statins to provide any meaningful results). No adjustment for age and sex was required due to the matching criteria.

Table 1. Comparison of characteristics of pneumonia cases and controls without pneumonia

n.a., Not applicable.

Data presented are mean (s.d.) for continuous data and number (%) for categorical data.

* Indicates that overall P values are provided for categorical comparisons where there are more than two categories

Prevalent myocardial infarction and stroke at the time of baseline of the EPIC-Norfolk study were excluded from the outset and these numbers indicate the number (%) of participants with incident cardiovascular disease diagnosed between EPIC-Norfolk study enrolment and pneumonia date (baseline of the current report).

RESULTS

A total of 503 participants were identified as hospitalized pneumonia cases and these cases were matched by age, gender and year of entry into the EPIC-Norfolk study with 1962 controls (1:3·9) after exclusion of cases who died within 30 days of pneumonia and their respective controls. Participants were followed from the date of diagnosis of pneumonia in cases or the same date for matched controls for a total of 15 074 person-years (mean 6·1 years, range 0·08–15·2 years). The mean time from entry into EPIC-Norfolk (which began in 1993) and the diagnosis of pneumonia was 9·0 years.

As controls were age- and sex-matched, these baseline characteristics were comparable between cases and controls (Table 1). However, the cases had a significantly higher proportion of current smokers and a higher mean number of pack years than the control group. The prevalence of diabetes mellitus, CVD and respiratory disease, including asthma were significantly higher for cases. Mean FEV1 and FVC were lower within the case group compared to controls. Although the difference in BMI between the two groups was non-significant, the case group had a significantly higher waist-to-hip ratio than controls.

There was a higher incidence of mortality in the case group which was maintained throughout both time-frames and this difference was greatest in terms of respiratory mortality (Table 2). There was an increased risk of mortality for the case group compared to the control group after adjusting for significant risk factors identified (Table 3). There was an increased risk of all-cause mortality and specific-cause mortality between 30 days and 1 year, and longer than 1 year. The all-cause mortality rate was highest initially following pneumonia then reduced over time whereas the initial higher respiratory and cardiovascular mortality rates for cases compared to controls was maintained throughout the study period.

Table 2. Short, intermediate and long-term crude mortality rates for both pneumonia cases and controls by cause of death

Table 3. Hazard ratios and corresponding 95% confidence intervals of incident mortality for cases using the control group as a reference category

HR, Hazard ratio; CI, confidence interval.

Covariates adjusted are smoking status, pack years, physical activity levels, waist to hip ratio, diabetes mellitus, prevalent cardiovascular disease and prevalent respiratory disease for all modes of mortality and all time frames. Matching is account for by a shared frailty term of each matched set.

The risk of cardiovascular mortality was increased in cases for both time periods, and the highest risk period was between 30 days and 1 year. Interestingly risk of death due to respiratory cause was excessively high 1 year post-pneumonia and the overall risk was driven mainly by this.

Additionally adjusting for aspirin use did not alter the results (data not shown).

DISCUSSION

Our findings indicate that hospitalized pneumonia is associated with increased risk of mortality not only in the short term (⩾30 days to <1 year), but also in the longer term (>1 year) compared to age- and sex-matched controls within the general population of middle and older age. This increase in mortality persisted throughout the entire length of follow-up for all-cause respiratory, and cardiovascular mortality. Risk of death due to cardiovascular cause appeared to be particularly high within 1 year of pneumonia and increased risk of mortality from respiratory causes appeared to be very high after 1 year in cases (who did not die within 1 month) compared to the control population who did not have hospitalized pneumonia during the study period.

Our findings support previous studies. Recently, it was reported that hospitalization for pneumonia was associated with increased short-term and long-term risk of CVD, suggesting that pneumonia may be a risk factor for CVD [Reference Corrales-Medina19]. Furthermore, Kaplan et al., found that mortality in elderly patients hospitalized with community-acquired pneumonia (CAP) was 10% higher at 1 year than those hospitalized for other reasons [Reference Kaplan15]. Bordon et al., based on their study on a hospitalized population, also found an increased 7-year all-cause mortality in patients hospitalized with CAP compared to hospitalized controls [Reference Bordon20].

A cohort study, also using the general population as controls, found that the patients with pneumonia were almost 46 times as likely to die in the first 30 days as participants without pneumonia [Reference Myles17]. They found that for pneumonia cases the adjusted risk of all-cause mortality over total follow-up period was 4·6, which is in line with our findings.

This study further supports the evidence that the increase in cardiovascular risk persists past 1 year. In light of this finding, patients admitted to hospital with pneumonia should have a cardiac risk assessment including medication review, to consider interventions for CVD prevention if appropriate. The reason why people with pneumonia had increased cardiovascular mortality risk is unclear. However, there are plausible mechanisms which could lead to this observed link between pneumonia and subsequent cardiovascular mortality. Pneumonia increases the levels of inflammatory cytokines promoting thrombogenesis [Reference Mendall21] and reduces ventricular function [Reference Kumar22, Reference Mann23], both of which could lead to an increase in cardiac events in the short term. It is also thought that pneumonia produces a chronic inflammatory response which would accelerate the process of CVD in the intermediate term [Reference Yende10]. It was shown that patients hospitalized with pneumonia who experience persistently raised pro-inflammatory cytokines at discharge had an increased risk of cardiovascular death at 1 year, independent of the severity of illness [Reference Yende10].

This study has some limitations. First, neither the clinical severity of pneumonia nor the virulence of the disease-causing organisms was accounted for. Neither were the different levels of inflammatory markers which indicate an extent of host immune response, both of which have had a demonstrated effect on mortality [Reference Yende10, Reference Johnstone14]. A possible weakness is the misclassification of pneumonia diagnosis due to variable coding practices and lack of confirmatory radiological evidence as a requirement for inclusion. Evidence is unclear as to how accurate the pneumonia diagnosis is in hospital [Reference Pink, Mitchell and Davies24]. However, the main misclassified diagnosis is likely to be other causes of lower respiratory tract infection (LRTI) and this inclusion bias would result in a lower mortality within the case group as lobar pneumonia is the LRTI with the highest mortality rate [Reference Moellering25], thus the observed associations if any would be attenuation of the actual impact of pneumonia. We identified only individuals with hospitalized pneumonia so those with episodes of pneumonia treated only in the community were not included. Hospitalized pneumonia cases are likely to be more severe so the generalizability of findings to all pneumonias occurring in the community is limited. To reduce such bias associated with high mortality due to pneumonia-related death (i.e. respiratory cause) we deliberately excluded cases within EPIC-Norfolk who died within 30 days of pneumonia diagnosis. We were also unable to examine the specific cause of CVD mortality.

People who are admitted to hospital for pneumonia are also more likely to have comorbidities which may predispose to increased mortality risk. Although we adjusted for many covariates including lung function as well as history of asthma and chronic respiratory illnesses, there may be unknown confounders or there may be residual confounding effect of known confounders. While any hospitalization may increase the risk of mortality, a more relevant issue perhaps is whether people who had pneumonia were associated with increased cardiovascular risk in the longer term. We acknowledge that we were not able to examine this issue in people with pneumonia who were not hospitalized. Indeed, it is possible that a proportion of controls might have had pneumonia which did not result in hospitalization during follow-up of the study. This misclassification as well as any hospitalization with increased risk of death, however, would only attenuate the results. Finally, in clinical practice especially in older people conditions such as pneumonia and heart failure co-exist and there may be possibility of mis-diagnosis. Nevertheless, such error is likely to contribute mostly to ⩽30-day mortality and is unlikely to influence the >30-day relationships between pneumonia and mortality outcome.

The EPIC-Norfolk cohort comprised community-dwelling middle- and older-aged participants who agreed to participate at baseline recruitment, therefore there may be healthy responder bias. However, truncation of sample distribution would be likely to attenuate the findings.

The participants' baseline characteristics (e.g. FEV1/FEV) were taken from entry into the EPIC-Norfolk cohort which predated the current study entry date by a mean of 9·0 years. There could be significant differences between characteristics at entry into the EPIC-Norfolk study and at the point of pneumonia diagnosis, resulting in measurement error in the covariables. However we were able to control for wide-ranging demographic, lifestyle and medical factors including prevalent cardiovascular and chronic lower respiratory tract illnesses.

In summary, hospitalized pneumonia is associated with subsequent increased risk of mortality and this persists beyond 1 year after diagnosis in middle and older ages. Clinicians should be aware of the increased mortality from not only respiratory causes but also cardiovascular causes.

ACKNOWLEDGEMENTS

The EPIC-Norfolk study is supported by programme grants from the Medical Research Council (G1000143) and Cancer Research UK (8257). The funders had no role in study design, analysis, and interpretation of the findings.

We gratefully acknowledge the participants of the study and participating General Practitioners. We also thank our funders.

DECLARATION OF INTEREST

None.

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Figure 0

Table 1. Comparison of characteristics of pneumonia cases and controls without pneumonia

Figure 1

Table 2. Short, intermediate and long-term crude mortality rates for both pneumonia cases and controls by cause of death

Figure 2

Table 3. Hazard ratios and corresponding 95% confidence intervals of incident mortality for cases using the control group as a reference category