Impact of CPAP on asthmatic patients with obstructive sleep apnoea

The prevalence of asthma varies widely depending on the country studied 1. In Canada, the 1998/1999 National Population Health Survey reported a prevalence of physician-diagnosed asthma in 8.4% of the overall population 2. The estimated prevalence of sleep nocturnal breathing disorder, defined as an apnoea/hypopnoea score ≥15·h^-1, is 4% in females and 9% in males 3.

Asthma and obstructive sleep apnoea (OSA) syndrome are two prevalent diseases that may coexist 4 and adversely affect health-related quality of life 5. A high body mass index (BMI) may be an impediment in both conditions 6. Furthermore, nasal symptoms and gastro-oesophageal reflux that are often reported in OSA 7, 8 may exacerbate asthma 9, 10. In patients suffering from both conditions, nocturnal breathing disorder may be related to asthma, OSA or both 11, 12.

It is well known that continuous positive airway pressure (CPAP) is the most effective treatment for OSA 13. It has also been reported to be effective in reducing nocturnal asthma attacks in asthmatic and apnoeic patients 14–16. Two studies reported an improvement of airway responsiveness with CPAP treatment in four out of 20 apnoeic nonasthmatic patients 17 and in nine stable asthmatic nonapnoeic patients 18, respectively. However, a deleterious effect of CPAP on airway responsiveness was reported in six out of 31 OSA patients 19. To the best of the present authors’ knowledge, no study has specifically evaluated the effects of CPAP treatment on airway responsiveness of asthmatic OSA patients.

The primary aim of the present prospective study was to observe the changes in airway responsiveness in stable asthmatic OSA patients before and 6 weeks after CPAP treatment. The secondary aim was to study the impact of CPAP on quality of life specific to asthma (QOLAs) and OSA (QOLAp).

MATERIAL AND METHODS

RESULTS

In total, 33 patients were invited to participate in the study. Six were excluded due to the high variability of their PC₂₀ results during the screening visits. Seven were withdrawn during the study due to CPAP use <4 h·night^-1 (n = 3), an upper respiratory tract infection (n = 2), resumed smoking (n = 1) or elective orthopaedic surgery (n = 1). A total of 20 patients completed the study. The baseline characteristics of these patients are summarised in table 1⇓. No differences were observed in the baseline characteristics between patients who completed the study and those who did not.

Following 6 weeks of nocturnal CPAP used on an average of 6.7±0.9 h at a mean pressure of 9.3±2.8 cmH₂O, the AHI significantly dropped from 48.1±23.6·h^-1 at the baseline to 2.6±2.5·h^-1 on control PSG (p<0.001). All patients except one used CPAP with a nasal interface. The clinical and functional characteristics related to OSA and asthma before and 6 weeks after the CPAP treatment are summarised in table 2⇓.

No significant change in airway responsiveness before (PC₂₀ (95% CI) 2.2 mg·mL^-1 (1.3–3.5)) and after 6 weeks of CPAP (PC₂₀ 2.5 mg·mL^-1 (1.4–4.5); p = 0.3; fig. 1a⇓) was found. In three patients, a reduction of airway responsiveness was noticed after 6 weeks of CPAP, as reflected by a two-fold increase in PC₂₀. Compared with the other patients, no differences were found in their age, effective CPAP pressure, CPAP compliance, BMI, AHI, gastric reflux, atopy or quality-of-life scores. However, their baseline PC₂₀ was higher (7.3 mg·mL^-1) than the subjects who did not have any change in airway responsiveness (1.7 mg·mL^-1; p = 0.02). There were no significant changes in the mean FEV₁ before (82.2±13.6% predicted) and after 6 weeks of CPAP (80.4±13.6% pred). The QOLAp statistically and clinically improved from 4.1±1.4 at baseline to 6.0±1.0 at the end of the study (p<0.001). The QOLAs also improved statistically and clinically from 5.0±1.2 at baseline to 5.8±0.9 at the end of the study (p = 0.001; fig. 1b⇓). Clinical improvement for each QOL questionnaire is established by a score increase ≥0.5. The QOLAs at baseline were inversely correlated with the patient’s BMI (rho = -0.5, p = 0.02). Following the CPAP treatment, an improvement in QOLAs was positively correlated with the BMI (rho = 0.5, p = 0.03) and the AHI at baseline (rho = 0.5, p = 0.03).

There was no correlation between the BMI and the baseline AHI, or between BMI and baseline PC₂₀. Furthermore, following the CPAP therapy, no relationship was observed between the changes in QOLAs and QOLAp as well as between the changes in QOLAs and PC₂₀. Following CPAP use, the BMI was correlated with the improvement of the emotional (rho = 0.5, p = 0.02) and the environmental (rho = 0.5, p = 0.01) domains of QOLAs. The AHI at baseline was correlated with the improvement of the symptomatic (rho = 0.6, p = 0.01), the emotional (rho = 0.6, p = 0.01) and the environmental (rho = 0.5, p = 0.05) domains of QOLAs.

DISCUSSION

It was found that nocturnal CPAP treatment used with a heated humidifier in patients with stable asthma and newly diagnosed OSA did not modify the respiratory functional parameters, such as PC₂₀ or FEV₁. Nevertheless, the CPAP treatment improved the QOLAs. This improvement was greater in obese patients and in patients with a high AHI at baseline.

The present authors decided to enrol only stable asthmatic subjects in order to avoid potential variations in airway responsiveness related to poorly controlled asthma. Indeed, it must be remembered that the primary aim of the present study was to assess the effect of CPAP on airway responsiveness and not the control of asthma.

A total of 20 subjects may appear to be quite a small sample size, but the present authors feel that it was enough to allow detection of a clinically significant change in PC₂₀ with greater than two-fold dilutions after CPAP use to a 99% power, with an α-error of 5%. Therefore, it is believed that should a major effect of CPAP on airway responsiveness occur, the present study would have been able to detect it.

The number of patients excluded due to insufficient use of nocturnal CPAP (three out of 23) is less than the CPAP drop-out rate reported among OSA patients, since the acceptance rate of CPAP treatment among OSA patients, at large, is considered to be ∼70–80% 26. It is important to notice that patients had a heated humidifier integrated into their CPAP unit, thus preventing the effects of nasopharyngeal congestion in all but one subject.

An important variability in PC₂₀ (more than two methacholine dilutions) was found in six patients at baseline in spite of a clinically adequate control of asthma. These patients were excluded from the study. This exclusion criterion may explain the discrepancy between the present results and those from other studies, which found an improvement in PC₂₀ after CPAP treatment 17, 18. In those studies, PC₂₀ was measured on one occasion before and one after CPAP treatment. Therefore, a spontaneous PC₂₀ variability may have occurred, which could be unrelated to CPAP treatment.

The lack of a control group comprising stable asthmatic patients without OSA prevents the present authors from concluding with certainty that the improvement of QOLAs following CPAP utilisation is specifically related to CPAP treatment. Indeed, this improvement may be due to other factors, such as a placebo effect of CPAP or improvement of adherence to asthma treatment during the study. The lack of correlation between the changes in QOLAs and QOLAp suggests that the improvement in QOLAs cannot be explained by an overall feeling of well-being consecutive to sleep normalisation following OSA treatment with CPAP. The interdependence of the questionnaires should not be completely excluded and should be addressed by experts in a future study. In a future larger study, additional analysis could possibly and more accurately determine whether BMI and AHI are independent contributors to QOLAs and its improvement with CPAP treatment.

Further randomised controlled studies including moderate-to-severe asthmatic patients with and without obstructive sleep apnoea need to be conducted in order to assess the impact of continuous positive airway pressure on asthma quality of life and its control.