Humidified nasal continuous positive airway pressure in obstructive sleep apnoea

Subjects

Adult patients were recruited from a sleep clinic population with newly diagnosed OSAS of sufficient severity to warrant treatment with nCPAP 17. All patients were evaluated clinically to identify and treat surgically/medically correctable upper airway pathology including allergic rhinitis and polyposis. Patients were excluded if they had significant nasal obstruction (unable to breathe via a nasal route) or were unable to tolerate nCPAP during the titration study, required treatment for respiratory tract infection in the previous month, were mentally or legally incapacitated or suffered significant comorbidity, including psychiatric or cerebrovascular disease and respiratory or cardiac failure. Patients requiring supplemental oxygen were excluded. Study patients provided written consent and were informed that the study was designed to assess the effect of “two different levels of humidity” during nCPAP therapy. Patients were not told that CPAP use would be objectively monitored. At the completion of the study, each patient was debriefed with regard to compliance monitoring. Ethical approval was obtained from the WellingtonEthics Committee.

Questionnaires

At enrolment, patients completed questionnaires to document medical history, upper airway symptoms, atopy, medications, previous surgery to the nose or throat and sleepiness by Epworth Sleepiness Score (ESS) 18. Specific chronic upper airway symptoms were recorded: dry nose; discharging or runny nose; congested or blocked nose; bleeding nose; reduced sense of smell; sinus infections; sinus pain or headaches; dry throat; sore throat; hoarse voice or cough.

At the end of each treatment arm patients repeated the questionnaire to assess specific upper airway symptoms and problems related to the use of the nCPAP device. A 10-cm Likert scale was employed to measure satisfaction with the therapy, refreshment on waking, memory and ability to concentrate. Patients were asked to place a mark on the line to reflect the change in symptom. The midpoint represented no change, the far left worst ever and the far right best ever.

Polysomnography and nasal continuous positive airway pressure titration

Diagnostic polysomnography and nCPAP titration were undertaken at a tertiary level sleep laboratory (Wellington School of Medicine Sleep Investigation Centre, Bowen Hospital, New Zealand). All physiological signals were recorded on computer using an S‐Series Sleep System (Compumedics P/L, Melbourne, Australia). Measurements included electroencephalogram (EEG) C₄A₁ and C₃A₂, electro-oculogram (EOG), and submental electromyogram (EMG) by surface electrodes, leg movements, sound (integrating sound level meter; Rion Co. Ltd, Tokyo, Japan), electrocardiogram (ECG), nasal pressure, ribcage and abdominal wall motion (piezo-electric sensors) and body position (mercury switch transducer). Oxyhaemaglobin saturation was measured by pulse oximetry (Satlite trans; Datex Engstrom, Helsinki, Finland).

nCPAP was manually titrated without added humidity by an experienced polysomnography technician. Titration protocols consisted of a 2‐cm increase in pressure for obstructive apnoea and a 1‐cm increase for hypopnoea, snoring or desaturation. The final level of therapeutic CPAP was determined by a sleep physician. Patients underwent either a full-night diagnostic CPAP followed by full-night nCPAP titration study or a split-night study (severe OSAS confirmed during first sleep cycle followed by nCPAP titration). Studies were manually scored for sleep stage 19 and arousals 20. Definitions used for respiratory events included the following. Obstructive apnoea: cessation of airflow for ≥10 s accompanied by an ongoing respiratory effort. Central apnoea: cessation of airflow and respiratory effort for ≥10 s. Mixed apnoea: combination of an obstructive and central apnoea lasting ≥10 s. Hypopnoea: >50% decrease in two of the three respiratory channel amplitudes (nasal pressure, chest or abdominal effort) for ≥10 s. OSAS severity was expressed in terms of a respiratory disturbance index (RDI) (RDI=number apnoea+hypopnoea/hour of sleep).

Study design

A randomised crossover design was employed with the two 3‐week treatment arms separated by a 3‐day washout on no therapy. A treatment arm duration of 3 weeks was used as this has been shown to predict subsequent long-term CPAP use 5. The patients were randomly assigned to nCPAP treatment (Sullivan Elite; ResMed Ltd, Sydney, Australia) with either heated humidity (CPAP-humid) or placebo humidity (nCPAP pl-humid). A nasal mask (Mirage or Bubble Cushion; ResMed Ltd) was fitted by an experienced sleep technician and used for the duration of the study. Standard equipment instructions and an educational video regarding the use of nCPAP were provided. nCPAP-humid was achieved by passing air from the CPAP machine through a heated water chamber (HC100; Fisher and Paykel HealthCare Ltd, Auckland, New Zealand). A setting of 2 was used as the authors previously found that higher settings resulted in significant precipitation into the mask or tubing. Patients were instructed not to change the setting unless water was collecting in the mask or tubing which would prompt reduction by 0.5. The authors attempted to create a placebo humidification arm in which the HC100 unit was used without the heating unit turned on and the chamber was used without added water connected via tubing to the CPAP machine. During the 12- month study the mean monthly relative humidity readings at 06:00 h were 85±3% (range 79–89%) and the mean monthly temperature was 13±1°C (range 9.1–19.3°C).

Patients were contacted by an experienced sleep technician after the first, seventh and fourteenth night of each treatment arm for support in accordance with the usual protocol for initiating CPAP. An investigator blinded to research treatment interviewed the patients at the end of each treatment arm (questionnaire, subjective and objective compliance (Scan Software; ResMed Ltd) and at the end of the washout period (questionnaire).

Statistical analysis

A power calculation based on a parallel design assumed a sd for the primary outcome variable (compliance) of 1.97 h 5. A sample size per treatment arm of 42 has an 80% power to detect a difference of 1.22 h at a type-one error rate of 5%. This represents 25% of the mean compliance of 4.88 h from another study 5. As this trial had a crossover design this sample size estimate was conservative.

Data was entered into a computer database and statistical analysis was performed. A per protocol analysis was performed rather than an intention-to-treat analysis. For the primary outcome variable, “Proc Mixed” was used to fit a mixed linear model treating subjects as random effects and taking into account the repeated measurements of this variable 22. Period, treatment, time of measurement and treatment by time of measurement effects were fitted in the first model and the treatment by time of measurement effect was omitted in the second model. Normality assumptions, based on analysis of residuals, were met.

The nasal symptoms were analysed in two ways. First, by treating the total count of symptoms as an outcome variable. This was analysed using a log-linear model that took into account the repeated measurements and the single baseline measurement using the SAS procedure “Proc Genmod”. Secondly, each individual symptom was treated as a categorical variable and a method of conditional logistic regression was performed using the SAS procedure “Proc Logistic” for analysis of matched pairs 24. The visual analogue scale scores were analysed using the “Proc Mixed” procedure after logistic transformation to meet normality assumptions.

Subjective effect of treatment and patient preference

nCPAP in both arms of the study reduced sleepiness measured by ESS from baseline 12.1±5.1 to 4.1±2.1 with nCPAP-humid (p<0.01) and to 4.5±3.1 with CPAP with placebo humidity (nCPAP pl-humid) (p<0.01). There was no significant difference between the two arms (p=0.37). The effect of CPAP treatment on memory, ability to concentrate, feeling refreshed on waking and overall treatment satisfaction were not different between the two arms of the study (table 2⇓). nCPAP with heated humidification was preferred by 51% of patients; no humidification was preferred by 35% of patients; 14% were undecided (p=0.24).

Effect of treatment on upper airway symptoms

Upper airway symptoms were common, with 34 (92%) patients reporting at least one symptom (table 3⇓). The frequency of upper airway symptoms was reduced by nCPAP-humid compared to nCPAP pl-humid by 1.4 symptoms (95% confidence interval (CI) 1.07–1.83, p<0.02). The point differences in eight of 11 upper airway symptoms (table 3⇓) favoured a positive treatment benefit for humidification but this did not reach statistical significance.

Nasal continuous positive airway pressure use

Objectively measured nCPAP use was greater with nCPAP-humid (5.7±1.5 h·24 h⁻¹) compared to nCPAP pl-humid (5.3±1.7 h·24 h⁻¹) (95% CI for difference was 0.05–0.76 h·night⁻¹, p=0.03) when averaged over the 3 weeks. The treatment time by measurement time interaction did not reach statistical significance for objectively measured compliance at weekly time intervals (table 4⇓). Patients subjectively overestimated their nCPAP pl-humid use by 1.48±1.65 h·night⁻¹ (p<0.01) and nCPAP-humid use by 1.12±1.39 h·night⁻¹ (p<0.01). Subjective CPAP use was not statistically different between therapies (p=0.57).

The presence of specific upper airway symptoms and the frequency of upper airway symptoms at baseline were not related to objectively measured compliance (p=0.23) or final treatment preference (p=0.62).