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Ten years of viral and non-bacterial serology in adults with cystic fibrosis

Published online by Cambridge University Press:  12 March 2007

I. J. CLIFTON*
Affiliation:
Regional Cystic Fibrosis Unit, Seacroft Hospital, Leeds, UK
J. A. KASTELIK
Affiliation:
Regional Cystic Fibrosis Unit, Seacroft Hospital, Leeds, UK
D. G. PECKHAM
Affiliation:
Regional Cystic Fibrosis Unit, Seacroft Hospital, Leeds, UK
A. HALE
Affiliation:
Health Protection Agency, Seacroft Hospital, Leeds, UK
M. DENTON
Affiliation:
Department of Microbiology, Leeds General Infirmary, UK
C. ETHERINGTON
Affiliation:
Regional Cystic Fibrosis Unit, Seacroft Hospital, Leeds, UK
S. P. CONWAY
Affiliation:
Regional Cystic Fibrosis Unit, Seacroft Hospital, Leeds, UK
*
*Author for correspondence: Dr I. J. Clifton, Regional Cystic Fibrosis Unit, Seacroft Hospital, Leeds LS14 6UH, UK. (Email: i.j.clifton@btinternet.com)
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Summary

Viral infections are associated with pulmonary exacerbations in children with cystic fibrosis (CF), but few studies have addressed the frequency in adults. This paper investigates the frequency and impact of viral infections in adults with CF receiving intravenous antibiotics. Pre- and post-treatment spirometry, inflammatory markers and antibody titres against influenza A, influenza B, adenovirus, respiratory syncytial virus, Mycoplasma pneumoniae, Chlamydia psittaci, and Coxiella burnetti were analysed over a 10-year period. Non-bacterial infections were identified in 5·1% of 3156 courses of treatment. The annual incidence of admissions per patient associated with viral infection was 4·9%. The presence of viral infection in association with a pulmonary exacerbation did not adversely affect lung function or inflammatory markers in the short term. Adults with CF have a lower incidence of respiratory viral infections associated with pulmonary exacerbations requiring intravenous antibiotics compared to children and infants with CF.

Type
Original Papers
Copyright
Copyright © Cambridge University Press 2007

INTRODUCTION

Cystic fibrosis (CF) is characterized by chronic airway infection, pancreatic insufficiency, elevated sweat chloride concentration, impaired fertility and hepatobiliary disease. Mortality in patients with CF is primarily due to respiratory failure secondary to chronic bacterial infection. Lower respiratory tract infection occurs with a number of pathogens predominantly Staphylococcus aureus, Haemophilus influenzae, Pseudomonas aeruginosa and Burkholderia cepacia complex (Bcc). Chronic infection with P. aeruginosa is associated with an increase in mortality and morbidity in patients with CF [Reference Nixon1]. Respiratory viral infections may be associated with significant clinical deterioration [Reference Conway, Simmonds and Littlewood2] and predispose to infection with P. aeruginosa [Reference Johansen and Hoiby3].

The reported prevalence of respiratory viral infection ranges from 13% to 52% [Reference Abman4Reference Smyth12], and is higher in younger patients [Reference Petersen9]. In infants and young children with CF respiratory viral agents, mainly respiratory syncytial virus (RSV), have been detected in over half of respiratory exacerbations [Reference Armstrong5, Reference Hiatt6, Reference Abman13]. In older children, up to a third of infective exacerbations may be due to viral agents [Reference Pribble10, Reference Ramsey11, Reference Wang14]. In mixed populations of children and adults, viral agents, mainly RSV and parainfluenza have been reported in 20% of exacerbations [Reference Petersen9]. Data on the impact and prevalence of respiratory viruses in adults with CF is limited to one published study which showed that 11 out of 36 patients with symptoms of an exacerbation had serological evidence of infection with influenza virus A, B, cytomegalovirus, adenovirus or human rhinovirus A or B [Reference Ong8].

The aim of this study was to determine the prevalence and clinical impact of serologically defined infection to respiratory viruses, Mycoplasma pneumoniae, Chlamydia psittaci, and Coxiella burnetii in a large cohort of adults with CF receiving intravenous (i.v.) antibiotic treatment.

METHODS

Patients

A retrospective analysis was performed of serological studies to respiratory viruses and atypical organisms collected between 1 January 1994 and 31 December 2003 from patients attending the Leeds Regional Adult CF Unit. Data as to whether or not patients were receiving regular elective three-monthly or non-elective on-demand i.v. antibiotic therapy were recorded. The indications for non-elective i.v. antibiotics were increased respiratory symptoms, >10% reduction in spirometry measurements, reduced exercise capacity and increased sputum purulence. Blood was sampled for viral and atypical organism serology at the beginning and end of each course of i.v. antibiotic treatment. Spirometry measurements, peripheral blood white cell count (WCC), plasma viscosity (PV) and C-reactive protein (CRP) levels were obtained from the Unit's database. Data for annual influenza vaccination were obtained from both the Unit's database and general practitioner records.

Sputum microbiology

Data regarding P. aeruginosa and Bcc status in the year prior to admission were collected from the microbiology database. For each admission the patient's sputum microbiology status from the preceding 12 months was reviewed. The patients were categorized as Bcc-positive or Bcc-negative, chronic P. aeruginosa, intermittent P. aeruginosa or non-P. aeruginosa (by combining free and never categories) using the ‘Leeds’ criteria [Reference Lee15]. Patients were classified as ‘chronic P. aeruginosa’ if P. aeruginosa was isolated from sputum samples in >50% of those months where samples were collected and ‘intermittent P. aeruginosa’ if the percentage of months in which P. aeruginosa was isolated from sputum samples was <50%. If P. aeruginosa was not isolated from the subject's sputum samples in the preceding 12 months, the subject was classified as ‘non-Pseudomonas’.

Serological studies

Blood samples were assayed for antibody against influenza A, influenza B, adenovirus, RSV, M. pneumoniae, C. psittaci, and Cox. burnetii using complement fixation tests. Serum controls, complement, antigen, and known reactive controls were included with each assay. Titres were expressed as the reciprocal of the highest dilution of serum that completely fixed the complement in the presence of a specific antigen. Positive serological evidence of viral or atypical organism infection was defined as a ⩾fourfold increase in titre between paired samples collected at least 7 days apart. Any rise in influenza A and B titres which were temporally associated with combined influenza A and B vaccinations were excluded.

Statistical analysis

Non-normally distributed data were expressed as median and range, and the Mann–Whitney, χ2 and Kruskal–Wallis tests were used (SPSS 12.0, SPSS Inc., Chicago, IL, USA). The Fisher's exact probability test was used when frequencies were too low to justify use of the χ2 test. Normally distributed data were expressed as mean and standard deviation, and the one-way ANOVA was used (SPSS 12.0). Kaplan–Meier survival analysis was used to determine the median time free from P. aeruginosa infection and comparison between survival curves was made using the log rank test (SPSS 12.0). A P value of <0·05 was taken to be significant.

Ethics

Ethical approval for this study was obtained from the Leeds (East) Research Ethics Committee.

RESULTS

Between January 1994 and December 2003 a total of 3453 courses of home and hospital i.v. antibiotics were administered to 305 adult with CF. Of these, 297 treatment courses were excluded from the study as the serological data were incomplete, leaving 3156 courses available for study. The total number of patients with a positive rise in serology for influenza A, influenza B, adenovirus, RSV, M. pneumoniae, C. psittaci, and Cox. burnetii are shown in Table 1. Serological evidence of a viral infection occurred in 152 (4·8%) of treatment episodes. Only five (0·2%) and three (0·1%) courses of i.v. antibiotic courses were associated with evidence of M. pneumoniae or C. psittaci infection respectively. There were no cases of Cox. burnetii infection over the 10-year period. The mean annual incidence of admissions per patient associated with positive viral serology was 4·9% (see Table 2).

Table 1. Serology results

Data are presented as n (%).

* Raised titres to both influenza A and RSV.

Table 2. Annual frequency of treatment with i.v. antibiotics and incidence of positive serology during study period

Data presented as mean (standard deviation).

The presence of positive serology was not related to age, gender, length of treatment, time to next course of i.v. antibiotics, levels of inflammatory markers or spirometry measurements at the beginning and end of treatment (see Table 3) (Mann–Whitney P, n.s.).

Table 3. Demographics, inflammatory markers and spirometry at beginning and end of i.v. antibiotic treatment

Data are presented as median (range) unless otherwise indicated.

WCC White cell count (×109 l−1) normal range 4·00–11·00; PV, plasma viscosity (mPa s−1) normal range 1·50–1·72; CRP, C-reactive protein (mg l−1) normal range <5·0; FEV1, forced expiratory volume in 1 s (l); FVC, forced vital capacity (l).

There was a higher prevalence of positive viral serology during winter months (October–March, 6·0%) compared to summer months (April–September, 3·5%) (χ2P<0·05) (see Fig.). The frequency of positive serology was significantly higher in the winter months for influenza A (χ2P<0·05) and influenza B (χ2P<0·05) (see Fig.). There was no significant difference between the frequency of admissions associated with infection by adenovirus, M. pneumoniae, C. psittaci or RSV in the winter or summer months (χ2P, n.s.).

Fig. Frequency of positive viral serology. * Combined=raised titres to both influenza A and RSV.

Elective and non-elective antibiotic therapy

A total of 2398 courses of treatment were administered to patients receiving non-elective i.v. antibiotic therapy for acute exacerbations. In this group 115 treatment episodes (4·8%) were associated with positive viral serology.

A total of 757 courses of i.v. antibiotics were administered to patients receiving three-monthly elective i.v. antibiotic therapy. A total of 37 (4·9%) treatment episodes were associated with a positive viral serology. There was no significant difference between the prevalence of positive serology in patients receiving elective or non-elective i.v. antibiotic treatment (χ2P, n.s.). All courses of elective courses of i.v. antibiotics administered were to patients chronically infected with P. aeruginosa, apart from one patient chronically infected with Stenotrophomonas maltiphilia and one patient chronically infected with S. aureus.

Microbiology status and positive serology

Table 2 shows the annual frequency of admissions and the incidence of admissions associated with positive viral serology during the study period. Patients with sputum microbiology positive for chronic P. aeruginosa or Bcc had a higher frequency of admissions for treatment with i.v. antibiotics than patients classified as intermittent Pseudomonas or non-Pseudomonas (one-way ANOVA P<0·05). There was no significant difference in the annual incidence of admissions associated with positive viral serology between the four sputum microbiology groups (one-way ANOVA P, n.s.).

Fifty-three courses of i.v. antibiotics were administered to patients not colonized with either P. aeruginosa or Bcc during the 10-year study period The rate of a positive sputum sample for P. aeruginosa in the 3 months following admission was higher in the group with evidence of a viral infection (positive serology 28·6%, negative serology 10·9%), however, this was not statistically significant (Fisher's exact test P, n.s.). Using Kaplan–Meier survival analysis the median time for patients classified as non-Pseudomonas to have a positive sputum sample for P. aeruginosa was longer in patients with evidence of a viral infection (positive serology 399 days, negative serology 776 days), however, this was not statistically significant (log rank test P, n.s.).

Subgroup analysis according to microbiology status showed no significant effect of positive serology on the length of treatment, time to next course of i.v. antibiotics, levels of inflammatory markers or pre- and post-treatment spirometry. The median age for patients classified as non-P. aeruginosa, intermittent P. aeruginosa, chronic P. aeruginosa and Bcc were 20·7, 20·7, 23·4 and 23·1 years respectively. Patients chronically infected with P. aeruginosa or Bcc were significantly older than the patients either intermittently infected or free from infection with P. aeruginosa (Kruskal–Wallis P<0·05).

CONCLUSIONS

Most acute respiratory viral infections in people with CF are probably self-limiting, but may result in increased hospitalization, greater antibiotic use, and worse symptoms [Reference Armstrong5, Reference Wat and Doull16]. Influenza A was the commonest viral infection identified in this study. There are no randomized controlled trial data to support routine influenza vaccination of adults with CF [Reference Tan, Bhalla and Smyth17]. However, we advise all patients to receive annual influenza vaccination and if at all possible to avoid close contact with people with acute viral-like illnesses in an effort to reduce the frequency of viral infections.

Viral and bacterial infections may be synergistic in their capacity to cause airway inflammation and lung damage [Reference Petersen9]. Coincidental RSV infections in patients with intermittent and chronic P. aeruginosa infection are associated with a significant rise in anti-pseudomonal antibody levels [Reference Petersen9]. There are several possible mechanisms by which respiratory viruses may induce pulmonary damage in patients with CF. Viral infection may promote inflammatory cell recruitment and activation through intercellular adhesion molecules [Reference Papi and Johnston18] and induce the expression of stress response genes such as haem-oxygenase-1 and genes encoding for antioxidant enzymes such as glutathione peroxidase [Reference Choi19]. The latter can further affect already reduced epithelial lining fluid levels of glutathione in inflammatory conditions like CF [Reference Roum20]. In the present study we found no significant difference in baseline lung function, inflammatory markers, clinical response to antibiotic therapy, and time to next treatment between patients with or without evidence of a viral infection. This would suggest in the short term that viral infection has no greater clinical impact than exacerbations due to bacterial causes.

It has been reported that a greater proportion of first P. aeruginosa infections occur during the winter months [Reference Johansen and Hoiby3]. During the study of Petersen et al., RSV infections were more common in patients who developed chronic P. aeruginosa infection than in patients with intermittent or without P. aeruginosa infection [Reference Petersen9]. They postulated that viral infection may result in an increased risk of acquisition of chronic P. aeruginosa infection and prevention of viral infection may reduce the risk of subsequent infection with P. aeruginosa. This is important because chronic P. aeruginosa infection is associated with a worse prognosis [Reference Nixon1] and an accelerated decline in lung function [Reference Kosorok21]. The data from the study of Petersen et al. does not demonstrate a causal link between viral infection and subsequent P. aeruginosa infection, an alternative explanation could be that factors related to the risk of acquisition of chronic P. aeruginosa infection are also associated with an increased risk of viral infection. Ong et al. reported that there was a higher rate of viral infections occurring in patients with sputum positive for P. aeruginosa, however, this was non-significant [Reference Ong8]. Armstrong et al. reported 31 infants with CF hospitalized with symptoms of acute respiratory infection [Reference Armstrong5]. Sixteen of these infants had either a bronchoalveolar lavage or nasopharyngeal aspirate positive for a respiratory virus and subsequently 25% of them were infected with P. aeruginosa. In addition, 26% of the 15 infants where no respiratory viruses were detected, subsequently had P. aeruginosa isolated [Reference Armstrong5]. Collinson et al. found that of six patients with a new acquisition of P. aeruginosa during the study period, five occurred during symptoms suggestive of an upper respiratory tract infection (URTI) [Reference Collinson22]. Of the five first growths of P. aeruginosa associated with an URTI, three were associated with a Picornavirus infection. The data presented from the current study do not support the hypothesis that viral infections may predispose patients with CF to infection with P. aeruginosa. We found that following an admission for i.v. antibiotics associated with a viral infection there was no increase in the frequency or decrease in the time to a sputum sample positive for P. aeruginosa.

There is a wide variation in the incidence of viral infections in groups of patients without CF. Falsey et al. prospectively followed 540 adults aged >21 years with a diagnosis of congestive cardiac failure or chronic pulmonary disease over a 4-year period using culture, polymerase chain reaction (PCR) and serology [Reference Falsey23]. Within this population of patients, RSV and influenza A infection developed annually in 4–10% and 0–5% respectively [Reference Falsey23]. Tan et al. reported on 60 patients hospitalized with either life-threatening asthma, acute asthma or an exacerbation of chronic obstructive pulmonary disease (COPD) [Reference Tan24]. Using PCR they found within the respiratory secretions the presence of viral nucleic acid in 52% of patients [Reference Tan24]. They found that picornaviruses and adenoviruses were predominately found in patients with near-fatal asthma, while influenza virus infection was predominantly found in patients with exacerbations of COPD. Unlike patients with asthma or COPD, adults with CF can have chronic lower respiratory tract infection with bacteria such as S. aureus, P. aeruginosa and Bcc. The incidence of viral infections in adults with CF could be expected to be lower as there may be factors associated with the infecting bacteria. Interactions between the host and the bacteria may be more important than viral infections as a cause of exacerbations in patients with CF. It has been postulated that the inflammatory response and clinical symptoms associated with exacerbations may be a result of ‘blooms’ of planktonic bacteria from the anaerobic lung biofilms [Reference VanDevanter and Van Dalfsen25]. This hypothesis is supported by data demonstrating the different patterns of gene expression in airway epithelium cells in response to exposure to mucoid or motile P. aeruginosa. Exposure to motile P. aeruginosa promotes expression of pro-inflammatory genes related to host defence, whereas the response to mucoid P. aeruginosa is not pro-inflammatory [Reference Cobb26].

The frequency of viral infections in adults with CF is higher during the winter months. The data presented suggests that the increased frequency is related to influenza A and influenza B infection which would be in keeping with the known epidemiology of these infections. The frequency of RSV was not significantly higher during the winter months which is contrary to the Health Protection Agency data which demonstrates a large peak of RSV reports during the winter period [27]. However, this may be explained by the majority of these cases occurring in children.

There are several limitations to this study. The prevalence of virally induced respiratory exacerbation in patients with CF may have been underestimated due to a number of factors. Between 10% and 30% of patients with confirmed viral respiratory tract infection have negative serology [Reference Henrickson28]. Modern molecular-based technologies such as immunofluorescence or PCR are more sensitive and quicker than serology or tissue culture. A recent study using multiplex reverse transcriptase PCR (RT–PCR) to detect influenza A, influenza B, parainfluenza viruses 1, 2, and 4, RSV and adenovirus examined 52 samples of sputum from 38 patients with CF during two short periods over 2 years [Reference Punch29]. They reported 12·5% and 32% of the samples were positive in the first and second periods respectively, giving an overall prevalence of 23%. The only other study examining the frequency of viral infections in adults used serology as a basis for diagnosis and reported a higher prevalence of 30·6% but this was only based on 36 patients over a 1-year period [Reference Ong8]. It is our Unit's protocol to advise patients to take appropriate oral antibiotics at the first signs of respiratory symptoms. This may have prevented a secondary bacterial-associated clinical deterioration and the requirement for i.v. antibiotic treatment. Patients with a mild and self-limiting respiratory exacerbation may not have presented to the Unit at the time of exacerbation. Our screening programme did not include detection of serological response to rhinovirus infection which is commonly associated with acute respiratory illness [Reference Murray, Simpson and Custovic30]. Diagnosis of rhinovirus infection by serological methods is difficult due to the large number of serotypes. The incidence of rhinovirus infection declines with age but has been reported in adults with CF [Reference Ong8]. Further data, particularly for evidence of rhinovirus infection, could have been obtained through the use of PCR and nasal pharyngeal aspirate specimens [Reference Smyth12, Reference Collinson22]. Over the study period in our hospital viral serology was the standard tool for screening patients who were suspected of having viral infections.

Our Unit has stopped routine serology measurements due to the low prevalence of positive serology reported in this study, and is currently using nasopharyngeal swabs combined with immunofluorescence as a method of diagnosis for viral respiratory infections. We intend to introduce PCR-based detection in the near future. Serology is still performed where there is concern regarding the possibility of atypical organisms causing infection or where patients are not responding to conventional i.v. antibiotic therapy.

In conclusion, adults with CF have a lower incidence of respiratory viral infections associated with pulmonary exacerbations requiring i.v. antibiotic treatment compared to children and infants. The serological data presented suggest that most of the exacerbations requiring i.v. antibiotics were not caused by a viral infection. Patients with serological evidence of viral infection did not have a worse short-term clinical outcome. Contrary to previous reports the incidence of viral infections was not higher in patients chronically infected with P. aeruginosa. Further prospective studies using modern diagnostic techniques should be undertaken to provide additional data regarding the epidemiology and clinical impact of respiratory viral infections in patients with CF.

DECLARATION OF INTEREST

None.

References

REFERENCES

1. Nixon, GM, et al. Clinical outcome after early Pseudomonas aeruginosa infection in cystic fibrosis. Journal of Pediatrics 2001; 138: 699704.CrossRefGoogle ScholarPubMed
2. Conway, SP, Simmonds, EJ, Littlewood, JM. Acute severe deterioration in cystic fibrosis associated with influenza A virus infection. Thorax 1992; 47: 112114.CrossRefGoogle ScholarPubMed
3. Johansen, HK, Hoiby, N. Seasonal onset of initial colonisation and chronic infection with Pseudomonas aeruginosa in patients with cystic fibrosis in Denmark. Thorax 1992; 47: 109111.CrossRefGoogle ScholarPubMed
4. Abman, SH, et al. Role of respiratory syncytial virus in early hospitalizations for respiratory distress of young infants with cystic fibrosis. Journal of Pediatrics 1988; 113: 826830.CrossRefGoogle ScholarPubMed
5. Armstrong, DS, et al. Severe viral respiratory infections in infants with cystic fibrosis. Pediatric Pulmonology 1998; 26: 371379.3.0.CO;2-N>CrossRefGoogle ScholarPubMed
6. Hiatt, PW, et al. Effects of viral lower respiratory tract infection on lung function in infants with cystic fibrosis. Pediatrics 1999; 103: 619626.CrossRefGoogle ScholarPubMed
7. Hordvik, NL, et al. Effects of acute viral respiratory tract infections in patients with cystic fibrosis. Pediatric Pulmonology 1989; 7: 217222.CrossRefGoogle ScholarPubMed
8. Ong, EL, et al. Infective respiratory exacerbations in young adults with cystic fibrosis: role of viruses and atypical microorganisms. Thorax 1989; 44: 739742.CrossRefGoogle ScholarPubMed
9. Petersen, NT, et al. Respiratory infections in cystic fibrosis patients caused by virus, chlamydia and mycoplasma – possible synergism with Pseudomonas aeruginosa. Acta Paediatrica Scandinavica 1981; 70: 623628.CrossRefGoogle ScholarPubMed
10. Pribble, CG, et al. Clinical manifestations of exacerbations of cystic fibrosis associated with nonbacterial infections. Journal of Pediatrics 1990; 117: 200204.CrossRefGoogle ScholarPubMed
11. Ramsey, BW, et al. The effect of respiratory viral infections on patients with cystic fibrosis. American Journal of Diseases in Children 1989; 143: 662668.Google ScholarPubMed
12. Smyth, AR, et al. Effect of respiratory virus infections including rhinovirus on clinical status in cystic fibrosis. Archives of Diseases in Childhood 1995; 73: 117120.CrossRefGoogle ScholarPubMed
13. Abman, SH, et al. Early bacteriologic, immunologic, and clinical courses of young infants with cystic fibrosis identified by neonatal screening. Journal of Pediatrics 1991; 119: 211217.CrossRefGoogle ScholarPubMed
14. Wang, EE, et al. Association of respiratory viral infections with pulmonary deterioration in patients with cystic fibrosis. New England Journal of Medicine 1984; 311: 16531658.CrossRefGoogle ScholarPubMed
15. Lee, TW, et al. Evaluation of a new definition for chronic Pseudomonas aeruginosa infection in cystic fibrosis patients. Journal of Cystic Fibrosis 2003; 2: 2934.CrossRefGoogle ScholarPubMed
16. Wat, D, Doull, IJ. Respiratory virus infections in cystic fibrosis. Paediatric Respiratory Reviews 2003; 4: 172177.CrossRefGoogle ScholarPubMed
17. Tan, A, Bhalla, P, Smyth, RL. Vaccines for preventing influenza in people with cystic fibrosis. The Cochrane Database of Systemic Reviews. Art. No.: CD001753.Google Scholar
18. Papi, A, Johnston, SL. Rhinovirus infection induces expression of its own receptor intercellular adhesion molecule 1 (ICAM-1) via increased NF-kappaB-mediated transcription. Journal of Biological Chemistry 1999; 274: 97079720.CrossRefGoogle ScholarPubMed
19. Choi, AM, et al. Oxidant stress responses in influenza virus pneumonia: gene expression and transcription factor activation. American Journal of Physiology 1996; 271: L383L391.Google ScholarPubMed
20. Roum, JH, et al. Systemic deficiency of glutathione in cystic fibrosis. Journal of Applied Physiology 1993; 75: 24192424.CrossRefGoogle ScholarPubMed
21. Kosorok, MR, et al. Acceleration of lung disease in children with cystic fibrosis after Pseudomonas aeruginosa acquisition. Pediatric Pulmonology 2001; 32: 277287.CrossRefGoogle ScholarPubMed
22. Collinson, J, et al. Effects of upper respiratory tract infections in patients with cystic fibrosis. Thorax 1996; 51: 11151122.CrossRefGoogle ScholarPubMed
23. Falsey, AR, et al. Respiratory syncytial virus infection in elderly and high-risk adults. New England Journal of Medicine 2005; 352: 17491759.CrossRefGoogle ScholarPubMed
24. Tan, WC, et al. Epidemiology of respiratory viruses in patients hospitalized with near-fatal asthma, acute exacerbations of asthma, or chronic obstructive pulmonary disease. American Journal of Medicine 2003; 115: 272277.CrossRefGoogle ScholarPubMed
25. VanDevanter, DR, Van Dalfsen, JM. How much do Pseudomonas biofilms contribute to symptoms of pulmonary exacerbation in cystic fibrosis? Pediatric Pulmonology 2005; 39: 504506.CrossRefGoogle ScholarPubMed
26. Cobb, LM, et al. Pseudomonas aeruginosa flagellin and alginate elicit very distinct gene expression patterns in airway epithelial cells: implications for cystic fibrosis disease. Journal of Immunology 2004; 173: 56595670.CrossRefGoogle ScholarPubMed
27. Health Protection Agency (http://www.hpa.org.uk/infections/topics_az/rsv/Graphs/Graph20.pdf). Accessed 2 January 2007.Google Scholar
28. Henrickson, KJ. Advances in the laboratory diagnosis of viral respiratory disease. Pediatric Infectious Disease Journal 2004; 23 (1 Suppl.): S6S10.CrossRefGoogle ScholarPubMed
29. Punch, G, et al. Method for detection of respiratory viruses in the sputa of patients with cystic fibrosis. European Journal of Clinical Microbiology and Infectious Diseases 2005; 24: 5457.CrossRefGoogle ScholarPubMed
30. Murray, CS, Simpson, A, Custovic, A. Allergens, viruses, and asthma exacerbations. Proceedings of the American Thoracic Society 2004; 1: 99104.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Serology results

Figure 1

Table 2. Annual frequency of treatment with i.v. antibiotics and incidence of positive serology during study period

Figure 2

Table 3. Demographics, inflammatory markers and spirometry at beginning and end of i.v. antibiotic treatment

Figure 3

Fig. Frequency of positive viral serology. * Combined=raised titres to both influenza A and RSV.