Hostname: page-component-586b7cd67f-2brh9 Total loading time: 0 Render date: 2024-11-20T06:24:22.795Z Has data issue: false hasContentIssue false

Risk of hospitalization during influenza season among a cohort of patients with congestive heart failure

Published online by Cambridge University Press:  29 August 2006

C. SANDOVAL
Affiliation:
Department of Clinical Epidemiology and Biostatistics, McMaster University, Hamilton, Ontario, Canada
S. D. WALTER
Affiliation:
Department of Clinical Epidemiology and Biostatistics, McMaster University, Hamilton, Ontario, Canada
P. KRUEGER
Affiliation:
Department of Clinical Epidemiology and Biostatistics, McMaster University, Hamilton, Ontario, Canada
M. SMIEJA
Affiliation:
Department of Clinical Epidemiology and Biostatistics, McMaster University, Hamilton, Ontario, Canada
A. SMITH
Affiliation:
Department of Clinical Epidemiology and Biostatistics, McMaster University, Hamilton, Ontario, Canada
S. YUSUF
Affiliation:
Department of Clinical Epidemiology and Biostatistics, McMaster University, Hamilton, Ontario, Canada
M. B. LOEB*
Affiliation:
Department of Clinical Epidemiology and Biostatistics, McMaster University, Hamilton, Ontario, Canada
*
*Address for correspondence: Dr M. Loeb, McMaster University, Rm 3200 MDCL, 1200 Main St West, Hamilton, Ontario, Canada. (Email: [email protected])
Rights & Permissions [Opens in a new window]

Summary

It is uncertain whether hospitalization among patients with congestive heart failure (CHF) increases during the influenza season. This retrospective cohort study used influenza surveillance data from the United States (1986–1987 to 1990–1991), clinical information from the Studies of Left Ventricular Dysfunction (SOLVD) database, and daily temperature data from the National Climatic Data Center to assess the effect of influenza season on hospitalizations in this cohort of patients. The overall hospitalization rate was higher during influenza seasons compared to non-influenza seasons [relative risk (RR) 1·08, 95% confidence interval (CI) 1·01–1·16]. Multivariable Cox modelling revealed an adjusted hazard ratio (HR) of 1·11 for hospitalization during the influenza season (95% CI 1·03–1·20, P=0·005). Overall death rates were also higher during influenza seasons than non-influenza seasons (RR 1·09, 95% CI 0·97–1·21), but the corresponding adjusted HR for death was not significant (HR 1·01, 95% CI 0·98–1·24, P=0·11). Patients with CHF have a greater risk of hospitalization during the influenza season than in the non-influenza season, supporting the current belief that patients with CHF should be regarded as a high-risk group.

Type
Research Article
Copyright
Copyright © Cambridge University Press 2006

INTRODUCTION

Influenza is a major cause of morbidity and mortality in both the United States and Canada [Reference Simonsen1, 2]. Individuals with chronic medical conditions, such as lung or heart disease, are identified as being at higher risk for complications of influenza [3, 4]. Although there is evidence to suggest that respiratory infections lead to worse outcomes in patients with chronic lung disease [Reference Glezen5], less is known about the impact of the influenza season on excess hospitalization and death in patients with congestive heart failure (CHF).

Higher rates of hospital admissions for CHF have been reported during influenza epidemic periods compared to non-epidemic periods [Reference McBean, Babish and Warren6Reference Upshur, Knight and Vivek8], but the findings have been inconsistent. Previous studies have also been limited by use of population-based analyses without access to patient-level comorbidities. Since patients with CHF may be hospitalized for other causes that are related to influenza, but which are not listed on the discharge certificate as the primary or secondary cause, the impact of influenza on patients with CHF has not, to our knowledge, previously been determined. About five million people in the United States and 350 000 in Canada have CHF [9, Reference Wilson10]. Therefore, obtaining estimates of risk of complications associated with influenza season in this population is of major public health importance.

To test the hypothesis that there is increased hospitalization during influenza seasons in adults with CHF, we conducted a retrospective cohort study from 1986 to 1990 using a large clinical database and US national influenza surveillance data. This database allowed us to conduct an analysis that included two influenza seasons (1987–1988, 1989–1990) that were remarkable for an increased severity of illness due to H3N2, the predominant influenza subtype that was circulating [Reference Simonsen11]. We conducted a separate analysis to examine the secondary outcome of all-cause mortality.

METHODS

Overview

All-cause hospitalization and death rates during the 1986–1990 influenza and non-influenza seasons were compared to provide crude estimates of the overall risk of hospitalization and death associated with circulating influenza among patients with CHF. Cox regression models were constructed to assess these same risks while adjusting for potential confounding variables.

Study population

Data collected for the Studies of Left Ventricular Dysfunction (SOLVD) trials were used as the clinical database. SOLVD consisted of two double-blind, placebo-controlled randomized trials that examined the effect of the angiotensin-converting-enzyme (ACE) inhibitor enalapril on morbidity and mortality in moderately severe CHF patients [12, 13]. Participants with CHF and left ventricular ejection fractions ⩽35% who were already taking drugs other than an ACE inhibitor were eligible. Participants were ineligible if they were aged >80 years or if they had any of the following: haemodynamically serious valvular disease requiring surgery, unstable angina, angina thought to be serious enough to require revascularization procedures, myocardial infarction in the previous month, severe pulmonary disease, serum creatinine >177 μmol/l, or any other disease that might substantially shorten survival or impede participation in a long-term trial. Asymptomatic CHF patients, defined as those with no clinical symptoms of CHF, were enrolled in the SOLVD Prevention trial, while symptomatic CHF patients were enrolled in the SOLVD Treatment trial. Participants were followed prospectively from 1986 to 1991. During this period, 39 924 patients with ejection fractions ⩽35% were identified. Of these 6·4% (n=2569) were enrolled in the Treatment trial and 7·4% (n=4228) were enrolled in the Prevention trial. The reasons for exclusion included the following: use of an ACE inhibitor (28%), cardiovascular problems (12%), contraindications to use of an ACE inhibitor (11%), lack of consent (11%), administrative reasons (21%), cancer or other life-threatening disease (12%), other reasons (5%). There were 24 study sites of which 21 were located throughout the continental United States, two in Canada, and one in Belgium [14]. Each was comprised of 1–8 hospitals [14]. Only participants from the 21 US sites were included in our analysis, since weekly influenza isolate data were available. A small number (<1%) of the participants were excluded because the exact date of their first hospitalization post-randomization could not be determined, leaving 5448 people in the study population. Individual-level longitudinal clinical and medical data, including demographics, medication history, comorbidities, and records of hospitalizations and deaths, were ascertained. To control for comorbidity, we used the Charlson Index to calculate a comorbidity score for each participant [Reference Charlson15].

The influenza season

National influenza surveillance data from 1986–1987 to 1990–1991 were obtained from the Influenza Branch of the Centers for Disease Control and Prevention. The weekly number of isolates submitted for testing each year and the weekly number of positive tests obtained during each year (by virus type and subtype) were used to calculate 3-week moving averages of positive influenza isolates. Study years were defined to begin on 1 July and end on the following 30 June. The start of the influenza season was defined as the first week in which the moving average of positive influenza isolates was at least 5% of all respiratory isolates submitted, and the end of the season was defined as the last week in which it was at least 5%. Two additional weeks were added to the end of each influenza season to capture cases associated with any lagged effect of influenza [Reference Nichol16, Reference Nordin17]. Isolate data and SOLVD study sites were classified into four regions: Central, Northeast, West, and South. The influenza season for each study year was used as a proxy for exposure to circulating influenza at that time. These seasons were specific to each region. All events that occurred during an influenza season for a given study year were considered as influenza-season events. All weeks not included in the influenza season for a particular study year were defined as the non-influenza season.

Study outcomes

The primary outcome of interest was first-time hospitalization during the entire study period. For this analysis, each SOLVD participant was considered to be at risk of an event until his/her first hospitalization occurred. If a patient died, was lost to follow-up, or if the study follow-up period ended, the last SOLVD follow-up visit was taken as that person's last day at risk. All patient-days at risk during the influenza season and non-influenza seasons for each year and for all-years combined were calculated based on date of randomization, dates of the beginning and end of each influenza season, and the date of hospitalization, death or last SOLVD visit.

A separate analysis examined the secondary outcome of all-cause mortality. In this case, each SOLVD participant was defined to be at risk until the date of death or until the end of the study follow-up period. State and national records were consulted to confirm all reports of death [14]. If a patient was lost to follow-up or the study ended, the last SOLVD follow-up visit was taken as the last day at risk of death for that individual.

Statistical analysis

Incidence rates of first-time hospitalization during each of the five study years (1986–1987, 1987–1988, 1988–1989, 1989–1990, 1990–1991) and all-years combined were determined by dividing the number of events during a given time period by the total days at risk for eligible individuals during the same period. Days at risk were calculated from the date of enrolment into the study until the date of the first hospitalization or, if no hospitalization occurred, until the date of the final follow-up visit. We calculated the rate ratio [relative risk (RR)] and 95% confidence intervals (CI) for hospitalization and mortality during the combined influenza seasons compared to combined non-influenza seasons. Subgroup analyses were performed to determine the effect of influenza on hospitalization and death for the following groups, which were specified a priori: trial, age group, geographic region, and study drug.

A Cox regression model with time-dependent effects [Reference Allison18] was used to estimate the effect of influenza season on hospitalization when adjusted for the following variables: symptomatic CHF (i.e. trial), age, Charlson Comorbidity Index score, New York Heart Association (NYHA) CHF classification [19], ejection fraction, therapy with enalapril, study site, and maximum daily temperature. The influenza season for each individual was defined as a time-dependent variable [Reference Thompson20] based on the randomization date and follow-up time of each participant and the dates of the influenza season of his/her region during each study year. The cumulative risk of hospitalization over the entire study period was calculated based on the number of days that each person contributed to the five influenza seasons under study. The cumulative risk of hospitalization during the non-influenza season was also determined similarly. Given that winter has been associated with increased cardiovascular morbidity and mortality, we adjusted the analysis for ambient temperature [Reference Wilkinson21Reference Curriero25]. We obtained temperature readings for each day of the 5 years of the study from the National Climatic Data Center, for each of the study sites. We defined days as ‘cold’ if the maximum daily temperature was ⩽5°C [Reference Wilkinson21]; this variable was used as a time-dependent factor in the Cox model, referring to the temperature on the day of the event being considered.

The adjusted hazard ratio (HR) associated with the influenza season compared to the non-influenza season and a 95% CI was calculated. A similar analysis was adopted with death as the outcome. The effect of changing the lag period for cold temperature was done for hospitalization and death analyses.

RESULTS

A total of 5448 patients were followed until first-time hospitalization, death, or loss to follow-up over a median time of 485 days. The mean follow-up times of patients who were asymptomatic for CHF (i.e. in the Prevention trial) and symptomatic for CHF (i.e. in the Treatment trial) were significantly different (617 days and 506 days respectively, P<0·001). Sixty-two per cent of the study population was hospitalized during the study period. Patients were followed until death (or loss to follow-up) for a median time of 961 days. In the mortality analysis, the mean follow-up times for the patients in the two trials were also significantly different (951 days and 927 days respectively, P=0·03). Twenty-four per cent of the population died during the study; <3% were lost to follow-up.

Risk of hospitalization during the influenza season compared to the non-influenza season

Overall hospitalization rates during the influenza and non-influenza seasons and the relative risk for the entire population and subgroups are summarized in Table 1. The hospitalization rate during the combined influenza season was significantly higher than the combined non-influenza season (113·9 and 105·2 hospitalizations per 100 000 patient-days respectively; RR 1·08, 95% CI 1·01–1·16). In the subgroup analyses, significant season effects were seen among the Treatment trial patients and in patients on placebo (Table 1). No significant season effects were seen in any of the other subgroups. Patients with overt CHF symptoms, patients on placebo, and patients aged ⩾65 years had the highest hospitalization rates during the combined influenza season (155·3, 137·4 and 130·7 per 100 000 patient-days respectively).

Table 1. Overall incidence of hospitalization among patients with congestive heart failure during the influenza season vs. non-influenza season and their relative risk, 1986–1987 to 1990–1991

RR, Relative risk; CI, confidence interval.

* Ratesare per 100 000 patient-days.

Statistically significant at 95% confidence level.

Risk of death during the influenza season compared to the non-influenza season

The corresponding analyses of overall death rates are summarized in Table 2. Mortality during the influenza season was higher than during the non-influenza season, but the difference was not statistically significant (27·1 and 24·9 deaths per 100 000 patient-days respectively; RR 1·09, 95% CI 0·97–1·21). However, among Treatment trial patients (i.e. those who had overt heart failure), the difference was statistically significant (RR 1·19, 95% CI 1·02–1·36).

Table 2. Overall incidence of death among patients with congestive heart failure during the influenza season vs. non-influenza season and their relative risk, 1986–87 to 1990–91

RR, Relative risk; CI, confidence interval.

* Rates are per 100 000 patient-days.

Statistically significant at 95% confidence level.

Adjusted risk of hospitalization and death during influenza season

The multivariable Cox model revealed a higher risk of hospitalization during the influenza season than the non-influenza season (adjusted HR 1·11, 95% CI 1·03–1·20, P=0·005, when adjusted for trial, age group, Charlson Comorbidity Index score, NYHA CHF class, ejection fraction, enalapril, cold temperature, and study site). The HRs for each independent predictor in the model for hospitalization are shown in Table 3. Factors associated with an increased risk of hospitalization included: participation in the Treatment trial, age ⩾50, Charlson score >2, and NYHA CHF class >I. The adjusted risk of death associated with the influenza season was 1·01 (95% CI 0·98–1·24, P=0·11, when adjusted for trial, age group, Charlson Comorbidity Index score, NYHA CHF class, ejection fraction, enalapril, cold temperature, and study site). The HRs obtained for each independent predictor in the model for death are shown in Table 4. The same factors associated with an increased risk of hospitalization were significantly associated with death. Analyses run with cold temperature 1, 7, and 14 days prior to hospitalization or death yielded results similar to those presented above (data not shown).

Table 3. Hazard ratios for all cause hospitalization in patients with congestive heart failure associated with each risk factor adjusted for the other variables in the table, 1986–1987 to 1990–1991

HR, Hazard ratio; CI, confidence interval; NYHA, New York Heart Association; CHF, congestive heart failure; ACE, angiotensin-converting enzyme.

* Adjusted for influenza season, trial, age, Charlson Comorbidity Index score, NYHA class, enalapril therapy, ejection fraction, and study site.

Table 4. Hazard ratios for all cause death in patients with congestive heart failure associated with each risk factor adjusted for the other variables in the table, 1986–1987 to 1990–1991

HR, Hazard ratio; CI, confidence interval; NYHA, New York Heart Association; CHF, congestive heart failure; ACE, angiotensin-converting enzyme.

* Adjusted for influenza season, trial, age, Charlson Comorbidity Index score, NYHA class, enalapril therapy, ejection fraction, and study site.

The adjusted HR for hospitalization during the influenza season without cold temperature in the model was similar to forcing cold temperature into the model (HR 1·11, 95% CI 1·04–1·19, P=0·003). In contrast, the adjusted HR for death during the influenza season without cold temperature in the model showed a substantial effect and was highly significant (HR 1·16, 95% CI 1·04–1·29, P=0·009).

DISCUSSION

We found an increased risk of overall hospitalization among patients with CHF, rather than an increase in risk of CHF admissions during the influenza season as in some previous studies [Reference McBean, Babish and Warren6, Reference Barker7]. Our study adds to previous work by assessing all-cause hospitalization in a well-defined cohort. Using a random sample of 5% of elderly hospitalized Medicare recipients, McBean and colleagues showed that the risk of hospitalizations for CHF during a circulating influenza A period was higher than during the non-circulating period (RR 1·20, 95% CI 1·18–1·22) [Reference McBean, Babish and Warren6]. Barker examined national hospital discharge data and found a slight excess in hospitalization due to CHF during epidemic periods among older adults [Reference Barker7]. Upshur et al. performed a time-series analysis using national discharge data and reported an inconsistent relationship between hospital admissions (including for CHF) and circulating influenza viruses among older people in Ontario [Reference Upshur, Knight and Vivek8]. An important strength of our study is that patient-level covariates were included. Since there is evidence that hospital admissions and deaths due to cardiac-related causes are higher during winter months compared to summer months [Reference Stewart22Reference Barnett26], we adjusted for cold temperature.

Our data reveal that patients with more comorbidity, less functional ability, overt symptoms for CHF, and greater age had higher risk of hospitalization during the influenza season. These latter findings were not unexpected given the known increased morbidity with older people during influenza epidemics [3]. Other investigations have indicated that people aged ⩾80 years may be at greatest risk for complications due to influenza [Reference Nordin17, Reference Thompson20].

Although the risk of death associated with influenza season was increased when we did not adjust for the effect of temperature, after adjustment we could not demonstrate an effect independent of temperature (HR 1·01, 95% CI 0·98–1·24). It is possible that there were too few deaths in our dataset to be able to detect an effect. However, the upper limit of the confidence limit does not rule out the possibility of an important effect. A recent report provides strong support for influenza as the cause of increase risk of winter mortality [Reference Reichert27].

The diagnosis of influenza virus infection is usually not confirmed in the laboratory, and influenza infection is often cleared before the onset of secondary complications that might result in hospitalization or death [Reference Noble and Beare28, Reference Nguyen-Van Tam, Nicholson, Webster and Hay29]. The lack of individual-level data on exposure to and infection with influenza may have led to an underestimation of risks associated with influenza in patients with CHF. We acknowledge that lack of information on influenza vaccination status may also have led to an underestimation of risk. However, only 43% of people with chronic pulmonary and cardiac conditions in the United States were vaccinated against influenza in 1998, and it is probable that vaccination coverage was even lower during the study period used in this analysis [30]. An assumption of determining cumulative risk in this study was that the risks of hospitalization and death were similar during each year. In our study period, year 1 involved mostly A(H1N1), years 2 and 4 predominantly A(H3N2), and years 3 and 5 predominantly influenza B (Table 5). Influenza A(H3N2) is associated with more serious morbidity and mortality than the other two strains [31]. The predominant strain, however, was usually the same across regions in a given year (Table 5). The relative risks of hospitalization or death by season were highest in years 1 and 3 where A(H1N1) predominated (Tables 6 and 7). Since respiratory syncytial virus (RSV) often co-circulates with influenza, the results could have been due to both RSV and influenza [Reference Neuzil32]. We acknowledge that the cohort studied was highly selective and it is likely that they had fewer co-existing comorbidities than the general population of patients with CHF. Furthermore, the medical attention paid to these clinical participants may have led to interventions to prevent hospitalization and death that would not have been in place for patients with CHF who did not participate in the clinical trial. These factors may have led to an underestimate of the effect of influenza on hospitalization and death.

Table 5. Regional distribution of predominant influenza type and subtype in the United StatesFootnote *, 1986–1987 to 1990–1991

n.a., Data not available.

* Regional data obtained from National Surveillance Influenza data from the Influenza Branch of the Centers for Disease Control and Prevention. Overall data obtained from Morbidity and Mortality Weekly Reports.

Table 6. Overall incidence of hospitalization among patients with congestive heart failure during the influenza season vs. non-influenza season and their relative risk, by year, per 100 000 population

RR, Relative risk; CI, confidence interval.

Table 7. Overall incidence of death among patients with congestive heart failure during the influenza season vs. non-influenza season and their relative risk, by year, per 100 000 population

RR, Relative risk; CI, confidence interval.

In summary, we conclude that all-cause hospitalizations are increased during influenza season in patients with CHF. These findings support the current belief that patients with CHF should be regarded as a high-risk group [3, 4].

ACKNOWLEDGEMENTS

We gratefully acknowledge the assistance of Keiji Fukuda, Lynette Brammer, and Alicia Postema from the Influenza Branch of the Centers for Disease Control and Prevention.

DECLARATION OF INTEREST

None.

References

REFERENCES

1. Simonsen, L, et al. . The impact of influenza epidemics on mortality: introducing a severity index. American Journal of Public Health 1997; 87: 19441950.CrossRefGoogle ScholarPubMed
2.Laboratory Centre for Disease Control. Canadian consensus conference on influenza. Canadian Communicable Disease Report 1993; 19: 136146.Google Scholar
3.Centers for Disease Control and Prevention. Prevention and control of influenza: recommendations of the Advisory Committee on Immunization Practices (ACIP). MMWR Recommendations and Reports 2005; 54: 140.Google Scholar
4.National Advisory Committee on Immunization (NACI). Statement on influenza vaccination for the 2005–2006 season. Canadian Communicable Disease Report 2006; 31 (ACS-6).Google Scholar
5. Glezen, WP, et al. . Impact of respiratory virus infections on persons with chronic underlying conditions. Journal of the American Medical Association 2002; 283: 499505.CrossRefGoogle Scholar
6. McBean, AM, Babish, JD, Warren, JL. The impact and cost of influenza in the elderly. Archives of Internal Medicine 1993; 153: 21052111.CrossRefGoogle ScholarPubMed
7. Barker, WH. Excess pneumonia and influenza associated hospitalization during influenza epidemics in the United States, 1970–1978. American Journal of Public Health 1986; 76: 761765.CrossRefGoogle Scholar
8. Upshur, REG, Knight, K, Vivek, G. Time-series analysis of the relation between influenza virus and hospital admissions of the elderly in Ontario, Canada, for pneumonia, chronic lung disease, and congestive heart failure. American Journal of Epidemiology 1999; 149: 8592.CrossRefGoogle ScholarPubMed
9.American Heart Association. Congestive heart failure (http://www.americanheart.org/presenter.jhtml?identifier=1486). Accessed 9 August 2006.Google Scholar
10. Wilson, E. Congestive heart failure: a national priority. Canadian Journal of Cardiology 2001; 17: 12431244.Google ScholarPubMed
11. Simonsen, L, et al. . Theimpact of influenza epidemics on mortality: introducing a severity index. American Journal of Public Health 1997; 87: 19441950.CrossRefGoogle Scholar
12.The SOLVD Investigators. Effect of enalapril on survival in patients with reduced left ventricular ejection fractions and congestive heart failure. New England Journal of Medicine 1991; 325: 293302.CrossRefGoogle Scholar
13.The SOLVD Investigators. Effect of enalapril on mortality and the development of heart failure in asymptomatic patients with reduced left ventricular ejection fractions. New England Journal of Medicine 1992; 327: 685691.CrossRefGoogle Scholar
14.The SOLVD Investigators. Studies of left ventricular dysfunction – rationale, design, and methods: two trials that evaluate the effect of enalapril in patients with reduced ejection fraction. American Journal of Cardiology 1990; 66: 315322.CrossRefGoogle Scholar
15. Charlson, ME, et al. . A new method of classifying prognostic comorbidity in longitudinal studies: development and validation. Journal of Chronic Diseases 1987; 40: 373383.CrossRefGoogle ScholarPubMed
16. Nichol, KL, et al. . Influenza vaccination and reduction in hospitalizations for cardiac disease and stroke among the elderly. New England Journal of Medicine 2003; 348: 13221332.CrossRefGoogle ScholarPubMed
17. Nordin, J, et al. . Influenza vaccine effectiveness in preventing hospitalizations and deaths in persons 65 years or older in Minnesota, New York, and Oregon: data from 3 health plans. Journal of Infectious Diseases 2001; 184: 665671.CrossRefGoogle ScholarPubMed
18. Allison, PD. Survival Analysis Using the SAS System: A Practical Guide. Cary, NC: SAS Institute Inc., 1995.Google Scholar
19.Criteria Committee of the American Heart Association. Nomenclature and Criteria for Diagnosis of Diseases of the Heart and Great Vessels, 9th edn. Boston, MA: Little, Brown & Co., 1994, pp. 253256.Google Scholar
20. Thompson, WW, et al. . Mortality associated with influenza and respiratory syncytial virus in the United States. Journal of the American Medical Association 2003; 289: 179186.CrossRefGoogle ScholarPubMed
21. Wilkinson, P, et al. . Vulnerability to winter mortality in elderly people in Britain: population based study. British Medical Journal 2004; 329: 647.CrossRefGoogle ScholarPubMed
22. Stewart, S, et al. . Heart failure in a cold climate. Journal of the American College of Cardiology 2002; 39: 760766.CrossRefGoogle Scholar
23. van Rossum, CTM, et al. . Seasonal variation in cause-specific mortality: are there high-risk groups? 25-year follow-up of civil servants from the first Whitehall Study. International Journal of Epidemiology 2001; 30: 11091116.CrossRefGoogle ScholarPubMed
24. Boulay, F, et al. . Seasonal variation in chronic heart failure hospitalizations and mortality in France. Circulation 1999; 100: 280286.CrossRefGoogle ScholarPubMed
25. Curriero, FC, et al. . Temperature and mortality in 11 cities of the Eastern United States. American Journal of Epidemiology 2002; 155: 8087.CrossRefGoogle ScholarPubMed
26. Barnett, AG, et al. . Cold periods and coronary events: an analysis of populations worldwide. Journal of Epidemiology and Community Health 2005; 59: 551557.CrossRefGoogle ScholarPubMed
27. Reichert, TA, et al. . Influenza and the winter increase in mortality in the United States, 1959–1999. American Journal of Epidemiology 2004; 160: 492502.CrossRefGoogle ScholarPubMed
28. Noble, GR. Epidemiological and clinical aspects of influenza. In: Beare, AS ed. Basic and Applied Influenza Research. Boca Raton, FL: CRC Press; 1982, pp. 1150.Google Scholar
29. Nguyen-Van Tam, JS. Epidemiology of influenza. In: Nicholson, KG, Webster, RG, Hay, AJ eds. Textbook of Influenza. Oxford, England: Blackwell Science, 1998, pp. 181206.Google Scholar
30.Centers for Disease Control and Prevention. Prevention and control of influenza: recommendations of the Advisory Committee on Immunization Practices (ACIP). MMWR Recommendations and Reports 2000; 51 (No. RR-3).Google Scholar
31.Centers for Disease Control and Prevention. Surveillance Summaries, October 25, 2002. MMWR Surveillance Summaries 2002; 51 (No. SS-7).Google Scholar
32. Neuzil, KM, et al. . Winter respiratory viruses and health care use: a population-based study in the northwest United States. Clinical Infectious Diseases 2003; 37: 201207.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Overall incidence of hospitalization among patients with congestive heart failure during the influenza season vs. non-influenza season and their relative risk, 1986–1987 to 1990–1991

Figure 1

Table 2. Overall incidence of death among patients with congestive heart failure during the influenza season vs. non-influenza season and their relative risk, 1986–87 to 1990–91

Figure 2

Table 3. Hazard ratios for all cause hospitalization in patients with congestive heart failure associated with each risk factor adjusted for the other variables in the table, 1986–1987 to 1990–1991

Figure 3

Table 4. Hazard ratios for all cause death in patients with congestive heart failure associated with each risk factor adjusted for the other variables in the table, 1986–1987 to 1990–1991

Figure 4

Table 5. Regional distribution of predominant influenza type and subtype in the United States*, 1986–1987 to 1990–1991

Figure 5

Table 6. Overall incidence of hospitalization among patients with congestive heart failure during the influenza season vs. non-influenza season and their relative risk, by year, per 100 000 population

Figure 6

Table 7. Overall incidence of death among patients with congestive heart failure during the influenza season vs. non-influenza season and their relative risk, by year, per 100 000 population