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Effect of low-dose theophylline plus beclometasone on lung function in smokers with asthma: a pilot study

M. Spears, I. Donnelly, L. Jolly, M. Brannigan, K. Ito, C. McSharry, J. Lafferty, R. Chaudhuri, G. Braganza, I. M. Adcock, P. J. Barnes, S. Wood, N. C. Thomson
European Respiratory Journal 2009 33: 1010-1017; DOI: 10.1183/09031936.00158208
M. Spears
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I. Donnelly
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L. Jolly
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M. Brannigan
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K. Ito
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C. McSharry
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J. Lafferty
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R. Chaudhuri
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G. Braganza
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I. M. Adcock
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P. J. Barnes
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S. Wood
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N. C. Thomson
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Abstract

Smoking is common in asthma and is associated with worse asthma control and a reduced therapeutic response to corticosteroids. The present authors hypothesised that treating smokers with asthma with low-dose theophylline added to inhaled corticosteroids would enhance steroid sensitivity and thereby improve lung function and symptoms.

In a double-blind, parallel group exploratory trial, 68 asthmatic smokers were randomised to one of three treatments for 4 weeks: inhaled beclometasone (200 μg·day−1), theophylline (400 mg·day−1) or both treatments combined. Outcome measures included change in lung function and Asthma Control Questionnaire (ACQ) scores.

At 4 weeks, theophylline added to inhaled beclometasone produced an improvement in peak expiratory flow (39.9 L·min−1, 95% confidence intervals (CI) 10.9–68.8) and ACQ score (-0.47, 95% CI -0.91– -0.04) and a borderline improvement in pre-bronchodilator forced expiratory volume in one second (mean difference 165 mL, 95% CI -13–342) relative to inhaled corticosteroid alone. Theophylline alone improved the ACQ score (-0.55, 95% CI -0.99– -0.11), but not lung function.

In the present pilot study, the combination of low-dose theophylline and inhaled beclometasone produced improvements in both lung function and symptoms in a group of smokers with asthma. Larger trials are required to extend and confirm these findings.

  • Asthma
  • corticosteroid insensitivity
  • histone deacetylase
  • smoking
  • theophylline

Inhaled corticosteroids are recommended as a first-line treatment for chronic persistent asthma 1, although a significant proportion of individuals fail to establish complete control of their asthma despite this approach 2. Smokers with asthma form part of this poorly controlled group as demonstrated by their increased symptoms 2, 3, increased emergency department visits for asthma 4, 5 and an impaired response to both inhaled and oral corticosteroids 6–9 compared with nonsmokers with asthma. The prevalence of smoking in asthma reflects that of the general population and therefore smokers with asthma comprise a large group of patients with poorly controlled disease 10. Smoking cessation is an effective intervention for smokers with asthma 11, but as sustained quitting rates are low, additional or alternative therapies are needed for individuals with asthma who smoke.

The anti-inflammatory actions of corticosteroids are mediated, in part, by the recruitment of histone deacetylase (HDAC), a nuclear enzyme involved in the switching off of activated inflammatory genes 12. Cigarette smoke reduces HDAC activity in vitro 13, which could explain corticosteroid insensitivity in smokers with asthma. At standard doses, theophylline produces bronchodilation, whereas low doses increase HDAC activity with associated reductions in inflammatory gene expression 14. Therefore, the present authors undertook an exploratory clinical trial to examine the effects of low-dose theophylline in combination with low-dose inhaled corticosteroids and theophylline alone on lung function and other outcomes in comparison with inhaled corticosteroids alone in smokers with asthma.

METHODS

Subjects

Mild-to-moderate 1 stable asthmatics aged 18–60 yrs on ≤1,000 μg·day−1 beclometasone (or equivalent), who were current smokers (≥5 cigarettes·day−1 with ≥5 pack·yrs−1 smoking history) were eligible for enrolment. All subjects demonstrated reversible airflow obstruction 15. Exclusion criteria included diabetes, recent myocardial infarction or other active pulmonary diseases (full criteria available at www.clinicaltrials.gov; identifier No. NCT00119496) . Patients were recruited from general practice, hospital clinics and research databases. The West Glasgow Research Ethics Committee (Glasgow, UK) approved the study and all patients gave written informed consent.

Study design

The current study was a randomised, prospective, double-blind, double-dummy, active comparator, parallel group design. Subjects taking inhaled corticosteroids alone or in combination with inhaled long acting β2-agonists completed a step-down in therapy during a 6 week run-in period where they were monitored for loss of asthma control. At the end of a 2-week corticosteroid-free period each subject (if deemed to have stable asthma) attended a randomisation visit, which comprised of spirometry, peak expiratory flow (PEF), completion of an Asthma Control Questionnaire (ACQ) 16, induced sputum for differential counts, supernatant and sputum macrophage HDAC activity and bloods for safety (full blood count, renal and liver function testing) and characterisation (total and specific immunoglobulin E).

Subjects were then randomised to one of three arms: 1) 200 μg·day−1 inhaled hydrofluoroalkane beclometasone dipropionate (Qvar©; IVAX, Runcorn, UK; equivalent to ∼400 μg·day−1 chlorofluorocarbon beclometasone) 17; 2) 400 mg·day−1 oral theophylline (Uniphyllin® Continus®; NAPP, Cambridge, UK); or 3) 400 mg·day−1 oral theophylline in combination with 200 μg·day−1 inhaled beclometasone. Pre-bronchodilator lung function was re-assessed at 14 days and all tests performed at the randomisation visit were repeated after 28 days with the addition of serum theophylline level.

Measurements

Lung function assessments conformed to consensus guidelines 15. Sputum induction, differential count and supernatant analysis were performed as previously stated 11 with minor modifications to optimise HDAC measurement 18. Sputum macrophages were encouraged to adhere through plating on six well plates for 1 h at 37°C and then processed for HDAC activity using a Fluor-de-LysTM assay kit (Biomol International, Exeter, UK) and analysed using fluorimetry. Sputum supernatants were collected for interleukin (IL)-8, myeloperoxidase (MPO) and RANTES/CC chemokine ligand (CCL) 5 measurement using enzyme immunoassays (R&D Systems, Abingdon; Immundiagnostik, Oxford Biosystems, Oxford; and Invitrogen Ltd, Paisley, all UK, respectively). Theophylline levels were assessed using an automated processing system (ARCHITECT c8000; Abbot Diagnostics, Maidenhead, UK). Continuation of smoking was confirmed by the detection of urinary nicotine metabolites at each visit using the SmokeScreenTM system (GFC Diagnostics, Bicester, UK). Subjects were regarded as current smokers if their urine cotinine equivalent concentration was >1.1 mg·mL−1. Treatment compliance was assessed by tablet count, inhaler weight and serum theophylline level.

Statistical analysis

The reduced response to inhaled corticosteroids in smokers with asthma meant standard power calculations could not be performed. The present study was informed by a previous clinical trial employing oral corticosteroids in smokers with asthma 9. This resulted in the estimation that 22 subjects per group were needed to detect a 230 mL difference in forced expiratory volume in one second (FEV1) between the treatment arms and to allow for a 10% dropout.

The randomisation schedule was generated in blocks using a previously validated system (RandAll) 19. The primary end-point was difference in pre-bronchodilator FEV1 between the treatments and beclometasone alone at 4 weeks. The last value obtained was carried forward for analysis. Lung function changes were examined using ANCOVA (incorporating the Kenward and Roger 20 method for small groups). The level of statistical significance was set at p<0.05. No adjustment was performed for multiple comparisons. Parametric data was examined using paired t-testing, two-sided t-testing or ANOVA and nonparametric data with Mann–Whitney or Kruskal–Wallis testing as appropriate.

RESULTS

A total of 3,895 smokers with asthma were invited to participate between August 2005 and May 2007, of whom 294 gave positive responses. Following telephone screening, visits were arranged for 187 subjects and 91 subjects were randomised (fig. 1⇓). In total, 23 subjects were allocated to the inhaled beclometasone alone and theophylline alone groups and 22 subjects to the combination of theophylline and inhaled beclometasone. In addition, 23 subjects were randomised to receive another treatment not discussed in the present paper. The baseline demographic, clinical (including previous inhaled corticosteroid and long-acting β2-agonist use) and inflammatory characteristics of each group were well matched (tables 1⇓ and 2⇓). All the lung function and ACQ results presented in the text are changes derived by ANCOVA relative to the inhaled corticosteroid group response.

Fig. 1—
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Fig. 1—

Randomisation schedule. Subjects were randomly allocated to one of four treatments and reviewed at 14 and 28 days. Treatment ceased at 28 days. Serious adverse effects: theophylline plus inhaled beclometasone, n = 0; theophylline, n = 2 (viral meningitis and chest pain secondary to reflux oesophagitis); inhaled beclometasone, n = 0.

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Table 1—

Baseline demographics

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Table 2—

Baseline sputum counts and histone deacetylase activity(HDAC)

Lung function

Theophylline and inhaled beclometasone

After 4 weeks, the subjects treated with the combination of theophylline and inhaled beclometasone demonstrated a significant improvement in morning PEF (39.9 L·min−1; 95% confidence interval (CI) 10.9–68.8; p = 0.008; fig. 2a⇓) and a borderline significant improvement in mean pre-bronchodilator FEV1 (mean difference 165 mL; 95% CI -13–342; p = 0.069; fig. 2b⇓) and pre-bronchodilator forced vital capacity (FVC; 254 mL; 95% CI 63–445; p = 0.010). After 2 weeks, low-dose theophylline and beclometasone showed a trend for improvement in morning PEF (24.9 L·min−1; 95% CI -1.5–51.2; p = 0.064) and pre-bronchodilator FVC (132 mL; 95% CI -23–286; p = 0.094). There were no detectable differences in other lung function end-points (table 3⇓).

Fig. 2—
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Fig. 2—

Change in a) peak expiratory flow (PEF), b) forced expiratory volume in one second (FEV1) and c) Asthma Control Questionnaire (ACQ) scores from randomisation to 28 days of treatment (paired t-test). Error bars represent 95% confidence intervals. p-values were derived from comparison of groups with inhaled beclometasone change using ANCOVA. BD: bronchodilator; ICS: inhaled corticosteroids; Theo: theophylline; Theo+ICS: theophylline and inhaled beclometasone combination. #: p = 0.008; ¶: p = 0.135; +: p = 0.069; §: p = 0.158; ƒ: p = 0.033; ##: p = 0.016.

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Table 3—

Changes in lung function and biomarkers following treatment compared with response to treatment with inhaled beclometasone alone

Theophylline

Theophylline alone did not improve lung function except for post-bronchodilator FVC at 4 weeks (304 mL; 95% CI 5–604; p = 0.046; table 3⇑ and fig. 2a⇑ and b).

ACQ score

After 4 weeks, the combination of theophylline and inhaled beclometasone produced a significant improvement in ACQ score (-0.47; 95% CI -0.91− -0.04; p = 0.033; fig. 2c⇑ and table 3⇑). Theophylline alone also reduced the ACQ score (-0.55; 95% CI -0.99− -0.11; p = 0.016; fig. 2c⇑ and table 3⇑).

Sputum samples

Induced sputum cytology

Overall, 97% of subjects produced a sample adequate for analysis both pre- and post-treatment. Treatment with the combination of theophylline and inhaled beclometasone was associated with a reduction in the mean absolute (-10.99; 95% CI -18.15− -1.65; p = 0.018) and percentage sputum lymphocyte count (table 3⇑). No other relative treatment differences were observed.

Inflammatory biomarkers in sputum

At 4 weeks, treatment with theophylline alone was associated with a reduction in sputum supernatant IL-8 (-1,201.3 pg·mL−1; 95% CI -2409.6− -276.6; p = 0.009) and MPO (-215.0 ng·mL−1; 95% CI -556.0− -36.7; p = 0.026; table 3⇑). No difference was detected in RANTES/CCL5 levels following treatment with theophylline and inhaled corticosteroids (-0.131 pg·mL-1; 95% CI -0.849–0.528). No other significant differences were detectable.

HDAC activity

HDAC activity was measurable for a subgroup within each treatment group (inhaled beclometasone n = 4, theophylline alone n = 7 and theophylline plus inhaled beclometasone n = 7). Nearly all samples obtained had a low level of HDAC activity. No difference was observed between the groups at baseline or after treatment (tables 1⇑ and 2⇑ and fig. 3⇓).

Fig. 3—
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Fig. 3—

Change in histone deacetylase activity (HDAC) from randomisation to 28 days of treatment. Individual plots of HDAC activity are shown. Error bars represent 95% confidence intervals. ICS: inhaled corticosteroids; Theo: theophylline; Theo+ICS: theophylline and inhaled beclometasone combination.

Serum theophylline levels

The mean±sd serum concentration for the theophylline alone group (4.9±2.4 μg·mL−1) was similar to that achieved in the theophylline and inhaled beclometasone group (4.3±2.0 μg·mL−1).

Compliance

Overall, 90% of the subjects who completed the study achieved ≥80% compliance with therapy.

Adverse events

Two serious adverse events occurred during the trial. Both occurred in the theophylline alone arm. One subject was admitted to hospital with viral meningitis, a condition felt to be unrelated to the medication and another with chest pain due to gastro-oesophageal reflux (a pre-existing condition), which was considered as exacerbated by the treatment. Neither subject withdrew from the study. There were two withdrawals due to adverse events. One each in the inhaled beclometasone alone (diarrhoea and vomiting) and theophylline and inhaled beclometasone (headache) arms. The frequency of headache was equal between the groups (six for theophylline and inhaled corticosteroids, seven for theophylline and five for low-dose beclometasone). Gastrointestinal upset was common in the theophylline alone group with 14 episodes being reported. Two subjects reported nausea whilst on theophylline and low-dose beclometasone. Pharyngitis was reported by three subjects in the low-dose beclometasone alone group.

DISCUSSION

The therapeutic response to inhaled corticosteroids is impaired in smokers with asthma 6–8, highlighting the need for alternative treatment approaches for this large subgroup of asthma patients. Based on previous research 21, 22, it was hypothesised that the addition of low-dose theophylline to inhaled corticosteroid would improve lung function to a greater degree than that produced with inhaled corticosteroid alone. The present study found that the combination of theophylline and inhaled corticosteroid produces improvements in indices of lung function and asthma control score in smokers with asthma.

Treatment with theophylline in combination with inhaled beclometasone for 4 weeks was associated with a large improvement in both pre-bronchodilator PEF and FVC and a borderline significant increase in pre-bronchodilator FEV1. A post hoc power calculation, based on the between patient sd (46.4 L·min−1) for the theophylline and inhaled corticosteroid group, reveals that 23 subjects per group would be required to provide 80% power for the detection of a 40 L·min−1 difference in PEF between the combination and inhaled corticosteroid alone groups. The improvement seen in both PEF and FVC (and the associated drop in ACQ score) suggest that the increase in FEV1 in the group treated with low-dose theophylline and inhaled beclometasone is likely to be a real effect. The size of the improvement seen after treatment with low-dose theophylline and inhaled beclometasone is also likely to be clinically significant as it is larger 23 or equivalent 24 to the improvement in PEF seen when long-acting β2-agonists are added to inhaled corticosteroids in nonsmoking asthmatics. Furthermore, the improvement in PEF demonstrated herein is much larger than that seen with montelukast 8 and high-dose inhaled corticosteroids 7 in previous studies in smokers with asthma. The improvements in lung function with low-dose theophylline and inhaled beclometasone were also associated with a reduction in ACQ score, just below the clinically significant threshold of 0.5 25. Given these findings further research should be carried out using low-dose theophylline and inhaled corticosteroids to confirm and extend the current understanding of the efficacy of this combination in smokers with asthma.

Theophylline alone did not produce any significant changes in pre-bronchodilator lung function. Nevertheless, low-dose theophylline treatment did increase post-bronchodilator FVC, produce a clinically significant reduction in ACQ score and a reduction in sputum supernatant cytokines. Previous research has demonstrated that theophylline has a similar effect in subjects with chronic obstructive pulmonary disease 26. Theophylline has many modes of action including nonspecific phosphodiesterase inhibition and adenosine receptor antagonism 27 and both of these mechanisms could produce bronchodilation. However, the present authors believe that the improvement in lung function with low-dose oral theophylline in combination with inhaled beclometasone is unlikely to be due to a bronchodilating effect of theophylline alone, given the absence of a statistically significant improvement in pre-bronchodilator lung function with low-dose theophylline alone. A previous study has demonstrated superiority for the combination of low-dose theophylline and inhaled beclometasone to high-dose beclometasone alone in nonsmokers with moderate persistent asthma 28. The present results confirm this finding and conclude that there appears to be a synergistic interaction between low-dose theophylline and corticosteroids in smokers with asthma.

Given the many suggested mechanisms of action of theophylline there are several ways by which low-dose theophylline could synergise with corticosteroids to improve lung function in smokers with asthma. One potential mechanism the current authors attempt to address in this study is the ability of low-dose theophylline to restore HDAC activity. In vitro HDAC activity can be reduced by cigarette smoke and restored by low-doses of theophylline 13, 14. Therefore, it was hypothesised that reduced HDAC activity was responsible for the reduced corticosteroid response seen in smokers with asthma and that this could be restored by low-dose theophylline resulting in an improved steroid response. The serum concentration of theophylline achieved in the subjects was within the range previously demonstrated to stimulate HDAC activity. The present authors were not able to confirm an increase in HDAC activity in those subjects treated with theophylline and inhaled corticosteroids despite the subjects being able to produce specimens of sufficient quality for differential counting and supernatant analysis. The reason for this failure was that the number of sputum macrophages harvested for HDAC was low and thus at the detection limit of the technique. Future investigations examining theophylline in smokers with asthma to address the underlying mechanism/s responsible may need to use bronchoalveolar lavage samples to ensure sufficient macrophages for HDAC analysis. As theophylline can also act as a nonspecific phosphodiesterase inhibitor and an adenosine receptor antagonist, the contribution of these (and other) mechanisms to synergism between theophylline and inhaled beclometasone needs to be examined in smokers with asthma.

In the present study, it was demonstrated that treatment with theophylline and inhaled beclometasone is associated with a reduction in sputum lymphocytes. How this contributes to an improved response to inhaled corticosteroids is unclear. A possible explanation is that the reduction observed is merely due to the group treated with theophylline and inhaled corticosteroids having a slightly higher sputum lymphocyte count at baseline (albeit nonsignificantly different). Previous work addressing the reproducibility of induced sputum counts has also demonstrated that sputum lymphocyte counts display lower reproducibility compared with eosinophils and neutrophils 29 so the current authors may be observing the inherent variability of this aspect of induced sputum. However, low-dose theophylline has been demonstrated to reduce airway lymphocyte numbers associated with a reduction in the late asthmatic response to allergen challenge and an alteration in CD4/CD8 T-lymphocyte ratio 30. Therefore, the reduction in sputum lymphocytes observed may be a true effect.

Finally, apart from the main trial end-point, there were 40 other comparisons made to produce the data presented in table 3⇑. Although it is usual practice to allow for this in the analysis, by performing adjustments of the α value or using 99% CIs only, unadjusted p-values were presented in the current paper as the study is a pilot (see online supplementary data for results of analysis adjusted for multiple comparisons). The aim has been to identify associations that would need to be examined in future studies.

In conclusion, the current pilot study demonstrates improvements in both lung function and asthma control from the addition of low-dose theophylline to inhaled corticosteroids in a group of smokers with mild-to-moderate asthma. Important questions that need to be addressed in the future include the relative performance of the combination of low-dose theophylline and low-dose inhaled corticosteroids to high-dose inhaled corticosteroids, the effect of lower doses of theophylline and hence the lowest effective dose and the relative performance of the combination of low-dose theophylline and inhaled corticosteroids to the combination of long-acting β2-agonists and inhaled corticosteroids. Larger trials examining these important management issues should be performed to allow confirmation and extension of the present findings.

Support statement

The current study was funded by the Chief Scientists Office (Edinburgh, Scotland) and Chest, Heart and Stroke (Edinburgh, Scotland). GlaxoSmithKline acted as sponsor for the trial.CLINICAL TRIALThe present study is a registered clinical trial on ClinicalTrials.gov (identifier No. NCT00119496) .

Clinical Trial

The present study is a registered clinical trial on ClinicalTrials.gov (identifier No. NCT00119496) .

Statement of interest

Statements of interest for I.M. Adcock and P.J. Barnes, and the study itself can be found at www.erj.ersjournals.com/misc/statements.dtl

Acknowledgments

The present study is dedicated to the memory of S. Wood who died suddenly shortly after the commencement of recruitment. An employee of GlaxoSmithKline blinded to the allocation of the individual patients performed the lung function statistical analysis. The current authors would like to express gratitude to B. Rae (Glasgow, UK) from the Greater Glasgow and Clyde Health Board (Primary Care R&D) for help and support with this project. The present authors would also like to thank GPs from Greater Glasgow and North and South Lanarkshire (UK) and the volunteers who participated in the study.

Footnotes

  • This article has supplementary material accessible from www.erj.ersjournals.com

  • Received October 20, 2008.
  • Accepted January 7, 2009.
  • © ERS Journals Ltd

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Vol 33 Issue 5 Table of Contents
European Respiratory Journal: 33 (5)
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Effect of low-dose theophylline plus beclometasone on lung function in smokers with asthma: a pilot study
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Effect of low-dose theophylline plus beclometasone on lung function in smokers with asthma: a pilot study
M. Spears, I. Donnelly, L. Jolly, M. Brannigan, K. Ito, C. McSharry, J. Lafferty, R. Chaudhuri, G. Braganza, I. M. Adcock, P. J. Barnes, S. Wood, N. C. Thomson
European Respiratory Journal May 2009, 33 (5) 1010-1017; DOI: 10.1183/09031936.00158208

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Effect of low-dose theophylline plus beclometasone on lung function in smokers with asthma: a pilot study
M. Spears, I. Donnelly, L. Jolly, M. Brannigan, K. Ito, C. McSharry, J. Lafferty, R. Chaudhuri, G. Braganza, I. M. Adcock, P. J. Barnes, S. Wood, N. C. Thomson
European Respiratory Journal May 2009, 33 (5) 1010-1017; DOI: 10.1183/09031936.00158208
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