Time trends in primary-care morbidity, hospitalization and mortality due to pneumonia

A. B. VAN GAGELDONK-LAFEBER; M. A. H. BOGAERTS; R. A. VERHEIJ; M. A. B. VAN DER SANDE

doi:10.1017/S0950268809002258

Time trends in primary-care morbidity, hospitalization and mortality due to pneumonia

Published online by Cambridge University Press: 04 March 2009

A. B. VAN GAGELDONK-LAFEBER ,

M. A. H. BOGAERTS ,

R. A. VERHEIJ and

M. A. B. VAN DER SANDE

Show author details

A. B. VAN GAGELDONK-LAFEBER*: Affiliation:
National Institute for Public Health and the Environment (RIVM), Centre for Infectious Disease Control Netherlands, Epidemiology and Surveillance Unit, Bilthoven, The Netherlands
M. A. H. BOGAERTS: Affiliation:
Utrecht University, Institute for Risk Assessment Sciences, Utrecht, The Netherlands
R. A. VERHEIJ: Affiliation:
Netherlands Institute for Health Services Research (NIVEL), Utrecht, The Netherlands
M. A. B. VAN DER SANDE: Affiliation:
National Institute for Public Health and the Environment (RIVM), Centre for Infectious Disease Control Netherlands, Epidemiology and Surveillance Unit, Bilthoven, The Netherlands
*: *Author for correspondence: A. B. van Gageldonk-Lafeber, M.Sc., National Institute of Public Health and the Environment, Epidemiology and Surveillance Unit, PO Box 1, 3720 BA Bilthoven, The Netherlands. (Email: rianne.van.gageldonk@rivm.nl)

Article contents

Summary
INTRODUCTION
METHODS
RESULTS
DISCUSSION
References

Rights & Permissions

Summary

Most studies reporting pneumonia morbidity are restricted to hospitalized patients, although only a minority of pneumonia patients are admitted to hospital. To get a better understanding of the burden of disease in the general population, we conducted a population-based retrospective study to examine trends in pneumonia incidence in general practice, hospitalization, and mortality due to pneumonia in The Netherlands between 1997 and 2007. Between 2001/2002 and 2006/2007 there was an adjusted yearly increase of 12% in the clinical diagnosis of pneumonia in patients consulting general practitioners. Hospitalizations increased 5% per year between 1999/2000 and 2006/2007, while mortality annually decreased by 2% between 1997/1998 and 2006/2007. Our study suggests that the morbidity of pneumonia in the Dutch population increased considerably over this period, especially in primary-care settings, and that focusing only on hospitalization might underestimate the increasing public health burden of pneumonia.

Keywords

Epidemiology morbidity mortality pneumonia primary care

Type: Original Papers
Information: Epidemiology & Infection , Volume 137 , Issue 10 , October 2009 , pp. 1472 - 1478

DOI: https://doi.org/10.1017/S0950268809002258 [Opens in a new window]
Copyright: Copyright © 2009 Cambridge University Press

INTRODUCTION

Pneumonia, a common clinical disorder, is defined as an acute symptomatic inflammation of the lower respiratory tract whereby a new infiltrate is visible on a chest X-ray. However, in primary care the diagnosis is usually established on grounds of clinical criteria only [Reference Schouten1–Reference Metlay and Fine3]. Although chest X-ray is considered the gold standard for pneumonia diagnosis, it is only requested for about 20% of patients with a suspected lower respiratory tract infection in primary care [Reference Woodhead4]. Typical symptoms include cough, chest pain, fever, malaise and shortness of breath; crackles in the lungs are heard at auscultation [Reference Cassiere and Niederman5]. Causes of pneumonia are diverse. Infection with microorganisms (bacteria, viruses, fungi or parasites) is most common, but pneumonia may also result from physical or chemical injury of the lungs. A distinction can be made between community-acquired pneumonia (CAP) and nosocomial pneumonia. CAP refers to infections acquired outside hospitals or nursing homes, whereas nosocomial pneumonia describes infections acquired in hospital settings or extended-care facilities.

Despite improved treatment strategies, pneumonia remains a major cause of morbidity and mortality in Western industrial countries [Reference Cassiere and Niederman5–Reference Ochoa-Gondar9]. Both morbidity and mortality of pneumonia are strongly related with age, with about 90% of all deaths due to pneumonia in industrial countries occurring within the ⩾65 years age group [Reference Cassiere and Niederman5, Reference Fry10–12]. In recent years, increasing trends of hospitalization due to pneumonia have been reported in the USA [Reference Fry10], Denmark [Reference Thomsen13], England [Reference Trotter14] and The Netherlands [Reference Oosterheert15], with a shifting of age distribution towards an elderly population offered as the major explanation.

Unfortunately these studies only address hospitalization, whereas admission to the hospital is needed for only 20–40% of all pneumonia patients [Reference Hoare and Lim16]. Including data on general practitioner (GP) consultations, will therefore lead to a better understanding of the total burden of disease. We conducted a population-based retrospective study to assess recent trends in incidence of pneumonia in general practice, in hospitalization, and in mortality due to pneumonia in the Dutch population in the period between 1997 and 2007, adjusted for demographic changes in age and gender of the Dutch population.

METHODS

Data sources

To provide an overall insight in trends in pneumonia in The Netherlands, three datasets were studied for three different outcomes associated with pneumonia: GP consultations, hospital admissions, and mortality. The observed time period differs for the datasets because of the availability of the data.

GP consultations

Data from the Netherlands Information Network of General Practice (LINH), provided by the Netherlands Institute for Health Services Research (NIVEL), from May 2001 to April 2007 was used to investigate trends in the incidence of the clinical diagnosis of pneumonia in general practice. This data was recorded by on average 85 GP practices, with a total registered patient population of about 350 000 patients (December 2004), representative of the Dutch population in respect of age, gender and type of insurance [Reference Braspenning, Wichers and Faber17, 18]. For every consultation, age, gender and the suspected diagnosis are recorded according to the International Classification of Primary Care (ICPC). In addition, referrals and prescribed medications are recorded. For this study we used data on GP consultations for the clinical diagnosis of pneumonia (defined as ICPC R81) in combination with patients' age and gender. Because many patients with pneumonia consult their GP more than once for the same disease episode, we excluded repeated GP consultations within 90 days after the first pneumonia consultation in the data analyses. We regarded these excluded consultations as belonging to the same episode of pneumonia.

Hospital admissions

Data from the Dutch National Medical Register (LMR) from May 1999 to April 2007 was used to investigate trends in hospital admissions due to pneumonia. Data for all patients admitted to every general, teaching and specialized hospital in The Netherlands, registered at the patient's discharge were provided by the LMR and supplied by Prismant, the research and advisory agency for the Dutch Health Care Service [19]. Data include demographic characteristics of the patient as well as the principal and secondary diagnoses at hospital discharge, coded by ICD-9-CM codes (International Classification of Diseases, 9th revision – Clinical Modification). For this study pneumonia was defined as ICD-9-CM codes 003.22, 052.1, 055.1, 0.73.0, 083.0 and 480.XX–487.XX (see Appendix A).

Mortality

The cause-of-death registry from Statistics Netherlands (CBS) from May 1997 to April 2007 was used to investigate trends in mortality due to pneumonia. CBS registers both primary and secondary causes of deaths per month, by 5-year age group and gender, based on the recent international classification of diseases (ICD-10). Pneumonia was defined as ICD-10 codes A15, A16, A48.1, A70, A78 and J12–J18 (see Appendix B).

Statistical analysis

Incidence of pneumonia in general practice was calculated as the number of incident cases with the clinical diagnosis of pneumonia per 1000 registered patients, using seven age groups (0–4, 5–14, 15–24, 25–44, 45–64, 65–74, ⩾75 years). Incidence of hospitalized pneumonia and mortality due to pneumonia were assessed as respectively the number of patients with main discharge diagnosis pneumonia and the number of deceased with pneumonia as primary or secondary cause of death per 1000 inhabitants, using 5-year age bands (i.e. 0–4, 5–9, 10–14, …, ⩾95 years).

The incidence and mortality of pneumonia fluctuates with the season, peaking in December and/or January in most years. This seasonal variation could influence annual trends when looking at calendar years. To correct for this we used so called ‘respiratory years’ for all analyses, defined as 1 May (year n) until 30 April (year n+1). Poisson regression was used to assess the yearly increase in incidence rates and mortality due to pneumonia per age group, adjusted for demographic changes in age and gender of the Dutch population. All statistical analyses were performed using SAS software version 9.1 (SAS Institute, USA).

RESULTS

Pneumonia incidence in general practice

Highest GP consultation rates because of (suspected) pneumonia were seen in the oldest (⩾65 years) and the youngest (0–4 years; Fig. 1 a) age groups. Between 2001/2002 and 2006/2007 there was an increase in patients visiting their GP with a (suspected) pneumonia from 6·0 to 8·8/1000 registered patients (Table 1). Corrected for demographic changes in age and gender of the Dutch population, there is an adjusted increase of 12% (95% CI 10–14) more patients consulting a GP for the clinical diagnosis of pneumonia every year, which represents a total increase of about 75% in the 5-year study period. This increase was lowest in the 15–24 and 25–44 years age groups [respectively 7% per year (95% CI 3–12) and 9% per year (95% CI 5–13); Table 1].

Table 1. Pneumonia incidence in general practice (GP) per 1000 registered patients, and adjusted increase per year for the period 2001/2002 to 2006/2007, by age group and gender

CI, Confidence interval.

* Adjusted for demographic changes in age and gender of the Dutch population.

Fig. 1. Trends, by age group, for (a) pneumonia incidence in general practice per 1000 registered patients for the period 2001/2002 to 2006/2007, (b) incidence of hospital admissions due to pneumonia per 1000 inhabitants for the period 1999/2000 to 2006/2007, (c) incidence of mortality due to pneumonia per 1000 inhabitants for the period 1997/1998 to 2006/2007.

Hospital admissions

Hospitalization because of pneumonia was most common in the youngest (0–4 years) and the oldest age groups (⩾65 years; Fig. 1 b). The number of patients hospitalized with a primary diagnosis of pneumonia increased from 1·2 to 1·7/1000 inhabitants in the period 1999/2000 to 2006/2007 (Table 2). After correcting for demographic changes, hospital admission for pneumonia increased 5% per year (95% CI 4·7–5·9), which represents a total increase of 44% for the observed period. This increase was lowest in the 0–4 and 15–24 years age groups [respectively 3% per year (95% CI 0·5–6·1) and 4% per year (95% CI 1·6–5·5); Table 2].

Table 2. Hospital admissions due to pneumonia per 1000 inhabitants and crude and adjusted increases per year for the period 1999/2000 to 2006/2007, by age group and gender

CI, Confidence interval.

* Adjusted for demographic changes in age and gender of the Dutch population.

Mortality

Pneumonia-related mortality occurred mainly in persons aged ⩾75 years (Fig. 1 c). Between 1997/1998 and 2006/2007 mortality rates in the total population remained constant (0·9/1000 inhabitants; Table 3). After adjusting for demographic changes in age and gender, a significant decrease in mortality rates was seen in all age groups, with the exception of the 45–64 years age group. This decrease was most pronounced in persons aged <25 years (Table 3). In the total population, mortality rates decreased by 2% a year (95% CI 1·7–2·3), representing a total decrease of 17% for the observed period.

Table 3. Mortality due to pneumonia per 1000 inhabitants and crude and adjusted increases per year for the period 1997/1998 to 2006/2007, by age group and gender

CI, Confidence interval.

* Adjusted for demographic changes in age and gender of the Dutch population.

DISCUSSION

This study demonstrates that pneumonia is a great public health concern. Our population-based study is unique in including data on the clinical diagnosis of pneumonia in primary care. We demonstrated that the increasing trend in the incidence of the pneumonia in primary care is considerably steeper than the increasing trend in hospitalization due to pneumonia. Earlier studies addressing only hospitalization might have underestimated the total public health burden of pneumonia.

Both the pneumonia incidence in general practice and the yearly increase in hospitalization was high in the youngest (0–4 years) and oldest (⩾65 years) age groups. Hospital admission because of pneumonia was also high in these age groups, while the yearly increase of hospitalization in older persons (6%) was higher than in younger persons (3%).

In 2006 and 2007, LMR reported a (temporarily) lower coverage of hospitals reporting their discharge data. Still, we found that the incidence of hospitalized pneumonia in 2005/2006 and 2006/2007 was almost similar with that in 2004/2005. The increase in hospitalization found in our study might therefore be slightly underestimated.

The rising incidence of pneumonia seems to involve age groups in addition to the youngest and oldest, since substantial increases in the incidence of clinical diagnosis in general practice (>10%) and in hospitalization (>5%) were seen in the 5–14 and 45–64 years age groups for men and women.

The shift of age distribution towards an elderly population did not fully explain the rising morbidity, because we found increasing trends despite adjustment for demographic changes in the age of the Dutch population.

In contrast with the increasing trend in the incidence of the clinical diagnosis pneumonia in primary care and hospitalization due to pneumonia, we found a slightly decreasing trend in mortality after adjustment for demographic changes in the age and gender of the Dutch population.

Our results in respect of hospitalization and mortality are consistent with recent trends found in Denmark, England and USA [Reference Fry10, Reference Thomsen13, Reference Trotter14]. In Denmark, incidence of hospital admissions increased by 50% between 1994 and 2003, whereas relative in-hospital mortality within 30 days after the admission data decreased by 11% [Reference Thomsen13]. Incidence of hospitalized pneumonia in the elderly in the USA increased by 20% from 1988–1990 to 2000–2002, and in-hospital mortality remained constant [Reference Fry10]. In England a 34% increase in the incidence of hospital admissions for pneumonia was seen in recent years [Reference Trotter14]. A study on pneumonia-related mortality in The Netherlands reported an increase since 1990, although there seems to be a decreasing trend towards the end of the study period (1999–2002) [Reference Oosterheert15]. Our results suggest this decreasing trend in pneumonia mortality has continued. Our findings are not completely comparable with the results of Oosterheert et al. [Reference Oosterheert15], as we used ‘respiratory years’ instead of calendar years.

As previously mentioned, demographic changes do not fully explain the rising morbidity. However, a higher prevalence of chronic diseases due to an ageing population and altered lifestyles might partially explain our findings [Reference Fry10, Reference Thomsen13, Reference Kemper, Stasse-Wolthuis and Bosman20]. The purpose of this study was to explore current trends and there was no possibility to look at comorbidity in all three datasets. The GP dataset does hold this information, making it an interesting option for future research.

There are several other possible explanations for the increasing incidence of clinical diagnosis of pneumonia in primary care and the increasing trend for hospitalization with somewhat declining mortality due to pneumonia. The increase in incidence of GP consultations might be a result of a change of behaviour in regard to seeking medical care in the general population. In that case we would also expect an increase in the total number of GP consultations over the past years. However, the overall frequency of GP consultation in The Netherlands was more or less stable over the observation period [Reference Schouten1, Reference Brown and Lerner8]. Moreover, the increase in hospitalized pneumonia argues against a behavioural change being the main explanation.

The increase in hospitalization might be caused by changes in the policy regarding admission of patients or by treatment strategies. In general, patients with pneumonia in The Netherlands are treated in the ambulatory setting. According to the national guidelines, only patients with severe CAP or antibiotic treatment failure are referred to hospital [Reference Schouten1]. There have been no specific alterations in these guidelines in the recent years that could account for the increase in hospitalization found in our study.

Another possible explanation for the increasing incidence of morbidity but decreasing mortality of pneumonia is variation in the pathogens causing pneumonia. Both changes in the prevalence of pathogens and changes in the virulence of specific pathogens might have caused a higher pathogenicity but lower mortality. These changes might be a result of recent strategies to reduce antibiotic prescriptions. However, the Dutch antibiotic prescribing rates are already low compared with other European countries and the USA and remained almost constant over the past decade [Reference Kuyvenhoven, Van Balen and Verheij21, Reference Prins22].

A limitation of our ecological study is the use of three datasets that do not consist of completely the same type of patients. Moreover, the existence of potential shifts in other respiratory diagnoses was not covered by our study. The comparison between the databases must therefore be interpreted with some caution, but is not expected to affect the overall increasing trend in the incidence of pneumonia in primary care and in hospitalization.

The apparent peak in GP consultations for pneumonia in 2004/2005 is probably related to the relatively high incidence of influenza that year, since pneumonia is a common complication of influenza infection [Reference Dijkstra23]. On the contrary some of the influenza patients might be misclassified as pneumonia cases. The diagnosis pneumonia was based on registered codes, whereas no information was available on clinical symptoms and/or the presence of infiltrative abnormalities on chest X-ray, another limitation of our study. This might also have resulted in some misclassification of other illnesses presenting with similar symptoms, e.g. bronchitis [Reference Speets24]. In addition, a recent study showed that the overall sensitivity for detecting CAP with the ICD-CM codes, which are used in the LMR dataset, is modest (72·4%) [Reference Van de Garde25]. However, there is no reason to believe that the extent of both types of misclassification changed during the observed period, and it is therefore not expected to affect the increasing trend in morbidity.

In conclusion, our study showed that focusing only on hospitalization conceals the increasing public health burden of pneumonia in the general population. Future studies would benefit from linking GP, hospital and mortality data by individual patient. This would allow the investigation of possible changes in primary care treatment of and referral rates for pneumonia that might underlie these changes.

APPENDIX A

List of pneumonia-related ICD-9-CM codes (International Classification of Diseases, 9th revision – Clinical Modification)

APPENDIX B

List of pneumonia-related ICD-10 codes (International Classification of Diseases, 10th revision)

ACKNOWLEDGEMENTS

We thank the following persons for their cooperation in supplying the data concerning this article: A. van der Meulen, M.Sc. (CBS), W. F. Hoogen Stoevenbeld (Prismant, LMR) and all the general practitioners participating in LINH.

DECLARATION OF INTEREST

None.

References

REFERENCES

1. Schouten, JA, et al. Revised SWAB guidelines for antimicrobial therapy of community-acquired pneumonia. The Netherlands Journal of Medicine 2005; 63: 323–335.Google Scholar PubMed

2. NHG Standaard. M78: Acuut hoesten. NHG 2003. (http://nhg.artsennet.nl/upload/104/standaarden/M78/start.htm). Accessed July 2008.Google Scholar

3. Metlay, JP, Fine, MJ. Testing strategies in the initial management of patients with community-acquired pneumonia. Annals of Internal Medicine 2003; 138: 109–118.CrossRef Google Scholar PubMed

4. Woodhead, M, et al. Use of investigations in lower respiratory tract infection in the community: a European survey. European Respiratory Journal 1996; 9: 1596–1600.CrossRef Google Scholar PubMed

5. Cassiere, HA, Niederman, MS. Community-acquired pneumonia. Disease-a-Month 1998; 44: 613–675.CrossRef Google Scholar PubMed

6. Jackson, ML, et al. The burden of community-acquired pneumonia in seniors: results of a population based study. Clinical Infectious Diseases 2004; 39: 1642–1650.CrossRef Google Scholar PubMed

7. File, TM. Community-acquired pneumonia. Lancet 2003; 362: 1991–2001.CrossRef Google Scholar PubMed

8. Brown, PD, Lerner, SA. Community-acquired pneumonia. Lancet 1998; 352: 1295–1302.CrossRef Google Scholar PubMed

9. Ochoa-Gondar, O, et al. The burden of community-acquired pneumonia in the elderly: the Spanish EVAN-65 study. BMC Public Health. 2008 27; 8: 222.CrossRef Google Scholar PubMed

10. Fry, AM, et al. Trends in hospitalizations for pneumonia among persons aged 65 years or older in the United States, 1988–2002. Journal of the American Medical Association 2005; 294: 2712–2719.CrossRef Google Scholar PubMed

11. Meyer, KC. Lung infections and aging. Ageing Research Reviews 2004; 3: 55–67.CrossRef Google Scholar PubMed

12. Statistics Netherlands. Statline (http://statline.cbs.nl/statweb/). Accessed July 2008.Google Scholar

13. Thomsen, RW, et al. Rising incidence and persistently high mortality of hospitalized pneumonia: a 10-year population-based study in Denmark. Journal of Internal Medicine 2006; 259: 410–417.CrossRef Google Scholar PubMed

14. Trotter, CL, et al. Increasing hospital admissions for pneumonia, England. Emerging Infectious Diseases 2008; 14: 727–733.CrossRef Google Scholar PubMed

15. Oosterheert, JJ, et al. The increase in pneumonia-related morbidity and mortality among adults in the Netherlands and possible explanations for it [in Dutch]. Nederlands Tijdschrift voor Geneeskunde 2004; 148: 1765–1769.Google Scholar

16. Hoare, Z, Lim, WS. Pneumonia: update on diagnosis and management. British Medical Journal 2006; 332: 1077–1079.CrossRef Google Scholar PubMed

17. Braspenning, J, Wichers, L, Faber, M. Management of the LINH GP practices is representative [in Dutch]. Huisarts & Wetenschap 2007; 50: 133.Google Scholar

18. NIVEL. Facts and figures about general practitioner care in the Netherlands (http://www.linh.nl/). Accessed July 2008.Google Scholar

19. Dutch National Medical Register (LMR) – Prismant (http://www.prismant.nl/informatieproducten/). Accessed July 2008.Google Scholar

20. Kemper, HCG, Stasse-Wolthuis, M, Bosman, W. The prevention and treatment of overweight and obesity: Summary of the advisory report by the Health Council of the Netherlands. The Netherlands Journal of Medicine 2004; 62: 10–17.Google Scholar PubMed

21. Kuyvenhoven, MM, Van Balen, FAM, Verheij, TJM. Outpatient antibiotic prescriptions from 1992 to 2001 in The Netherlands. Journal of Antimicrobial Chemotherapy 2003; 52: 675–678.CrossRef Google Scholar PubMed

22. Prins, JM, et al. Experiences with the Dutch Working Party on Antibiotic Policy (SWAB). Eurosurveillance 2008; 13.CrossRef Google Scholar

23. Dijkstra, F, et al. Long time trends in influenza-like illness and associated determinants in The Netherlands. Epidemiology and Infection. Published online: 15 September 2008. doi:10.1017/S095026880800126X.Google Scholar PubMed

24. Speets, AM, et al. Chest radiography and pneumonia in primary care: diagnostic yield and consequences for patient management. European Respiratory Journal 2006; 28: 933–938.CrossRef Google Scholar PubMed

25. Van de Garde, MW, et al. International classification of diseases codes showed modest sensitivity for detecting community-acquired pneumonia. Journal Clinical Epidemiology 2007; 60: 834–838.CrossRef Google Scholar PubMed

Table 1. Pneumonia incidence in general practice (GP) per 1000 registered patients, and adjusted increase per year for the period 2001/2002 to 2006/2007, by age group and gender

Table 2. Hospital admissions due to pneumonia per 1000 inhabitants and crude and adjusted increases per year for the period 1999/2000 to 2006/2007, by age group and gender

Table 3. Mortality due to pneumonia per 1000 inhabitants and crude and adjusted increases per year for the period 1997/1998 to 2006/2007, by age group and gender

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

VAN DEURSEN, A. M. M. VERHEIJ, T. J. M. ROVERS, M. M. VEENHOVEN, R. H. GROENWOLD, R. H. H. BONTEN, M. J. M. and SANDERS, E. A. M. 2012. Trends in primary-care consultations, comorbidities, and antibiotic prescriptions for respiratory infections in The Netherlands before implementation of pneumococcal vaccines for infants. Epidemiology and Infection, Vol. 140, Issue. 5, p. 823.

Crocker, Joanna C. Powell, Colin V. E. Evans, Meirion R. Hood, Kerenza and Butler, Christopher C. 2012. Paediatric pneumonia or empyema and prior antibiotic use in primary care: a case–control study. Journal of Antimicrobial Chemotherapy, Vol. 67, Issue. 2, p. 478.

Nair, Harish Simões, Eric AF Rudan, Igor Gessner, Bradford D Azziz-Baumgartner, Eduardo Zhang, Jian Shayne F Feikin, Daniel R Mackenzie, Grant A Moiïsi, Jennifer C Roca, Anna Baggett, Henry C Zaman, Syed MA Singleton, Rosalyn J Lucero, Marilla G Chandran, Aruna Gentile, Angela Cohen, Cheryl Krishnan, Anand Bhutta, Zulfiqar A Arguedas, Adriano Clara, Alexey Wilfrido Andrade, Ana Lucia Ope, Maurice Ruvinsky, Raúl Oscar Hortal, María McCracken, John P Madhi, Shabir A Bruce, Nigel Qazi, Shamim A Morris, Saul S El Arifeen, Shams Weber, Martin W Scott, J Anthony G Brooks, W Abdullah Breiman, Robert F and Campbell, Harry 2013. Global and regional burden of hospital admissions for severe acute lower respiratory infections in young children in 2010: a systematic analysis. The Lancet, Vol. 381, Issue. 9875, p. 1380.

Snijders, Bianca EP van der Hoek, Wim Stirbu, Irina van der Sande, Marianne AB and van Gageldonk-Lafeber, Arianne B 2013. General practitioners' contribution to the management of community-acquired pneumonia in the Netherlands: a retrospective analysis of primary care, hospital, and national mortality databases with individual data linkage. Primary Care Respiratory Journal, Vol. 22, Issue. 4, p. 400.

Huijskens, Elisabeth G. W. van Erkel, Adriana J. M. Palmen, Fernand M. H. Buiting, Anton G. M. Kluytmans, Jan A. J. W. and Rossen, John W. A. 2013. Viral and bacterial aetiology of community‐acquired pneumonia in adults. Influenza and Other Respiratory Viruses, Vol. 7, Issue. 4, p. 567.

de Groot, Mark C. H. Klungel, Olaf H. Leufkens, Hubert G. M. van Dijk, Liset Grobbee, Diederick E. and van de Garde, Ewoudt M. W. 2014. Sources of heterogeneity in case–control studies on associations between statins, ACE-inhibitors, and proton pump inhibitors and risk of pneumonia. European Journal of Epidemiology, Vol. 29, Issue. 10, p. 767.

Kumamaru, Hiraku Tsugawa, Yusuke Horiguchi, Hiromasa Kumamaru, Kanako Kunishima Hashimoto, Hideki and Yasunaga, Hideo 2014. Association between hospital case volume and mortality in non-elderly pneumonia patients stratified by severity: a retrospective cohort study. BMC Health Services Research, Vol. 14, Issue. 1,

Søgaard, Mette Nielsen, Rikke B. Schønheyder, Henrik C. Nørgaard, Mette and Thomsen, Reimar W. 2014. Nationwide trends in pneumonia hospitalization rates and mortality, Denmark 1997–2011. Respiratory Medicine, Vol. 108, Issue. 8, p. 1214.

Huijskens, Elisabeth G. W. Koopmans, Marion Palmen, Fernand M. H. van Erkel, Adriana J. M. Mulder, Paul G. H. and Rossen, John W. A. 2014. The value of signs and symptoms in differentiating between bacterial, viral and mixed aetiology in patients with community-acquired pneumonia. Journal of Medical Microbiology, Vol. 63, Issue. 3, p. 441.

Lang, Pierre-Olivier and Aspinall, Richard 2014. Vaccination in the Elderly: What Can Be Recommended?. Drugs & Aging, Vol. 31, Issue. 8, p. 581.

Millett, Elizabeth R C De Stavola, Bianca L Quint, Jennifer K Smeeth, Liam and Thomas, Sara L 2015. Risk factors for hospital admission in the 28 days following a community-acquired pneumonia diagnosis in older adults, and their contribution to increasing hospitalisation rates over time: a cohort study. BMJ Open, Vol. 5, Issue. 12, p. e008737.

van Deursen, A.M.M. Schurink-van't Klooster, T.M. Man, W.H. van de Kassteele, J. van Gageldonk-Lafeber, A.B. Bruijning-Verhagen, P.C.J.L. de Melker, H.E. Sanders, E.A.M. and Knol, M.J. 2017. Impact of infant pneumococcal conjugate vaccination on community acquired pneumonia hospitalization in all ages in the Netherlands. Vaccine, Vol. 35, Issue. 51, p. 7107.

Shinjo, Daisuke and Fushimi, Kiyohide 2017. The degree of severity and trends in hospital standardized mortality ratios in Japan between 2008 and 2012: a retrospective observational study. International Journal for Quality in Health Care, Vol. 29, Issue. 5, p. 705.

Benincà, Elisa van Boven, Michiel Hagenaars, Thomas van der Hoek, Wim and Shaman, Jeffrey 2017. Space-time analysis of pneumonia hospitalisations in the Netherlands. PLOS ONE, Vol. 12, Issue. 7, p. e0180797.

Torres, Antoni Cillóniz, Catia Blasi, Francesco Chalmers, James D. Gaillat, Jacques Dartois, Nathalie Schmitt, Heinz-Josef and Welte, Tobias 2018. Burden of pneumococcal community-acquired pneumonia in adults across Europe: A literature review. Respiratory Medicine, Vol. 137, Issue. , p. 6.

Rajamaki, Blair Hartikainen, Sirpa and Tolppanen, Anna-Maija 2020. Psychotropic Drug-Associated Pneumonia in Older Adults. Drugs & Aging, Vol. 37, Issue. 4, p. 241.

Lee, Kyunghee Hong, Kyunglan Kang, Sunghong and Hwang, Jieun 2021. Characteristics and Epidemiology of Discharged Pneumonia Patients in South Korea Using the Korean National Hospital Discharge In-Depth Injury Survey Data from 2006 to 2017. Infectious Disease Reports, Vol. 13, Issue. 3, p. 730.

Barratt, Sam Bielicki, Julia A Dunn, David Faust, Saul N Finn, Adam Harper, Lynda Jackson, Pauline Lyttle, Mark D Powell, Colin VE Rogers, Louise Roland, Damian Stöhr, Wolfgang Sturgeon, Kate Vitale, Elia Wan, Mandy Gibb, Diana M and Sharland, Mike 2021. Amoxicillin duration and dose for community-acquired pneumonia in children: the CAP-IT factorial non-inferiority RCT. Health Technology Assessment, Vol. 25, Issue. 60, p. 1.

Kashatnikova, Darya A. Khadzhieva, Maryam B. Kolobkov, Dmitry S. Belopolskaya, Olesya B. Smelaya, Tamara V. Gracheva, Alesya S. Kalinina, Ekaterina V. Larin, Sergey S. Kuzovlev, Artem N. and Salnikova, Lyubov E. 2022. Pneumonia and Related Conditions in Critically Ill Patients—Insights from Basic and Experimental Studies. International Journal of Molecular Sciences, Vol. 23, Issue. 17, p. 9896.

Article contents

Time trends in primary-care morbidity, hospitalization and mortality due to pneumonia

Summary

Keywords

INTRODUCTION

METHODS

Data sources

GP consultations

Hospital admissions

Mortality

Statistical analysis

RESULTS

Pneumonia incidence in general practice

Hospital admissions

Mortality

DISCUSSION

APPENDIX A

List of pneumonia-related ICD-9-CM codes (International Classification of Diseases, 9th revision – Clinical Modification)

APPENDIX B

List of pneumonia-related ICD-10 codes (International Classification of Diseases, 10th revision)

ACKNOWLEDGEMENTS

DECLARATION OF INTEREST

References

REFERENCES

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests