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J Sleep Med > Volume 18(1); 2021 > Article
Yoon, Jeon, Hwang, Lee, and Jeon: Improved Adherence to Positive Airway Pressure Treatment after Covering National Health Insurance in Patient with Obstructive Sleep Apnea: A Tertiary Sleep Center Review

초록

Objectives

Obstructive sleep apnea (OSA) is a common clinical disease which has been associated with cardiovascular disease and sudden death. Positive airway pressure (PAP) is the most effective treatment for OSA; however, most patients experience difficulties in tolerating machines, masks, or economic burdens. In Korea, National Health Insurance (NHI) application for PAP started in July 2018. Therefore, this study aimed to evaluate the PAP adherence and factors contributing to good adherence after NHI coverage in Korea.

Methods

A retrospective study was performed to examine 89 patients with OSA who were treated with PAP in 2019. All medical records were analyzed to obtain demographic and clinical data, including personal history, polysomnographic data, and PAP results.

Results

A total of 66 participants were included, of which 56 (84.8%) were maintained on PAP therapy after 3 months, and 32 of 42 (76.1%) were maintained on PAP therapy after 6 months; prolonged rapid eye movement (REM) sleep latency, increased non-REM (NREM) apnea-hypopnea index (AHI), and supine AHI significantly contributed to good PAP adherence for 3 months. At 6 months, prolonged REM sleep latency, increased NREM AHI, supine AHI, and increased arousal index significantly contributed to good PAP adherence. However, comorbid hypertension contributed to poor PAP compliance.

Conclusions

PAP adherence in patients with OSA was 84.8% after 3 months, and 76.1% after 6 months after NHI coverage in a regional tertiary sleep center in Korea. Prolonged REM sleep latency and increased supine AHI and NREM AHI significantly contributed to good adherence, whereas comorbid hypertension was a factor for poor PAP compliance.

Introduction

Obstructive sleep apnea (OSA) is a common clinical disease, and the prevalence of OSA among middle-aged individuals is 2% in women and 4% in men [1]. OSA is characterized by the cessation and reduction of nasal airflow during sleep, associated with blood oxygen desaturation. Clinical symptoms include snoring, frequent awakening, daytime fatigue, excessive daytime sleepiness, diminished intellectual ability, and changes in personality. During sleep apnea, blood oxygen levels decrease due to airway obstruction during sleep, and frequent awakening in response to reduced oxygen levels can activate the sympathetic nervous system, which is known to have adverse effects that contribute to the development of cardiovascular diseases. Overall, previous studies have shown that individuals with OSA have a 1.37-fold higher risk of developing hypertension than normal individuals [2]. Individuals with apnea-hypopnea index (AHI) values greater than 5.3 per hour are 23 times as likely to develop myocardial infarction than those with lower AHI values [3]. Individuals with severe OSA are 2.4 times more likely to develop congestive heart failure than those without apnea [4]. The Wisconsin sleep cohort study found that mortality among sleep apnea patients increased significantly according to apnea severity, based on the results of an 18-year followup study. A 5.2-fold increase in cardiovascular mortality has also been reported for severe sleep apnea patients [5].
Positive airway pressure (PAP) treatment is the first-choice treatment for most OSA patients, and in general, OSA treatments consist of lifestyle modifications, such as weight reduction and reducing the use of alcohol, sedatives, and sleep medications. PAP has been shown to reduce daytime sleepiness, oxygen desaturation, heart rate, and pulmonary pressure, improve cognitive performance, and increase quality of life [6]. Despite improvements made in PAP technology, most patients continue to experience difficulties tolerating the machine, the mask or economic burden, and adherence to PAP treatment remains a clinically significant problem [7]. PAP adherence is generally determined by a number of factors, such as the medical, social and economic characteristics of the patient and the patient’s understanding of the disease, in addition to side effects of the PAP.
Meantime, the cost of PAP therapy in Korea was about 2,000 dollars for the purchase of a machine, and if patients rent it, the monthly rental fee was around 250 dollars. Therefore, even though patient recognized the need for PAP, they often stopped treatment or missed the opportunity for treatment due to economic burden.
In Korea, there is a single universal health insurance system called National Health Insurance (NHI), which provides insurance for over 99% of the total population [8]. Finally, NHI started to cover the costs of PAP treatment from July 2018. As a result, the rental fee of PAP has been dramatically reduced to 13–15 dollars monthly, which is about one-twentieth less than before. No place in the world has a public health insurance system that guarantees the whole nation and treated PAP as cheaply as Korea. Also studies focusing on economic burden in adherence of PAP treatment have rarely been conducted. Therefore, this study aimed to evaluate the PAP adherence and factors that affect adherence in patients with OSA since PAP treatment was included to NHI policy in Korea.

Methods

Participants

Participants with a history of snoring and/or apneas, who visited a sleep center at the Kyungpook National University Chilgok Hospital in Daegu, South Korea, between January 2019 and December 2019, were screened for this study, retrospectively. The participants in this study included aged between 20 and 85 years old. Those who were <20 years old and those who had previously used PAP within 6 weeks of enrollment were excluded. A total of 89 patients were examined using night polysomnography (PSG); however, 23 participants did not have sleep apnea and they were excluded from the study. Finally, 66 participants were prescribed PAP treatment. A total of 42 participants were treated with PAP for 6 months, and 66 participants were treated with PAP for 3 months, which was the minimum criteria to receive health insurance in Korea. We defined “good adherence” to PAP treatment as those patients who used PAP more than 70% of the monitoring periods, and average time of PAP usage per one night was more than 4 hours. This study was approved by the Institutional Review Board of Kyungpook National University (approval number: 2020-02-018).

Polysomnography and PAP treatment

Standard, full-night PSG techniques were recorded with Neuvo digital recording equipment (Compumedics, Australia), and the time required for inspection was at least 6 hours 30 minutes. Sleep stages were detailed according to standard electroencephalography, electrooculography, and electromyography (EMG) criteria by American Academy of Sleep Medicine scoring manuals. Apnea and hypopnea were recorded by an oronasal flow cannula, attached to a pneumotachograph. Arterial oxygen saturation was measured by pulse oximetry, using a finger probe. Thoracic and abdominal movements were recorded by using piezoelectric belts, to document the respiratory effort. Periodic limb movements were recorded using surface EMG electrodes on the tibialis anterior muscle of the lower extremity.
Obstructive apnea was defined by a decrease of more than approximately 90% of the baseline amplitude airflow for at least 10 seconds, in the presence of thoracoabdominal effort. Central apnea was determined if both airflow and respiratory efforts were absent for at least 10 seconds in duration, and mixed sleep apnea was diagnosed by the combination of both obstructive and central sleep apnea patterns. Hypopnea was scored if the magnitude of the ventilation signal decreased by more than approximately 30% of the baseline amplitude for at least 10 seconds and was associated with at least a 3% drop in oxygen saturation, as measured by finger pulse oximetry, or accompanied arousals [9]. OSA was diagnosed when AHI was 5 or more and there were weekly symptoms related to sleep apnea. The severity of OSA was classified as mild when AHI is 5 or more and less than 15, moderate when it is 15 or more and less than 30, and severe when it is 30 or more. PAP treatment was started to patient who was diagnosed with moderate OSA or more. Sixty of 66 patients were prescribed automatic PAP, and 6 out of 66 patients who agreed to re-examination of polysomnography for PAP titration were prescribed continuous PAP, and their average pressure was 8.3 cm H2O.

Data analysis

Continuous variables were presented as the frequency, mean, and standard deviation. We also conducted a series of internal subgroup comparisons, using the Mann-Whitney U test. To determine the contributing factors associated with PAP adherence, data analysis was performed for score derivations, based on univariate and multivariate logistic regressions. A p-value <0.05 was considered significant. Statistical analyses were performed using IBM SPSS statistics version 21.0 (IBM Corp., Armonk, NY, USA).

Results

Demographic characteristics

For the total study period, 66 participants with sleep apnea were recruited (Table 1). The mean age of the participants was 55.7±13.5 years. Fifty (75.7%) were males and 16 (24.2 %) were females. The mean height was 166.8±9.4 cm, the mean weight was 75.2±17.4 kg, and the mean body mass index (BMI) was 26.9±5.4 kg/m2. The mean snoring index value, defined as the number of detected snoring events per hour, estimated at 30-second intervals, was 336.4±188.6. The mean AHI value was 35.2±20.3. The average peripheral oxygen saturation was 92.4±4.5%.

Adherence based on 6 months

At the time of the survey, 66 patients were using PAP treatment. 24 (36.3%) patients were excluded because the duration of PAP treatment did not exceed 6 months during the study period. Finally, 42 participants were analyzed for 6-month PAP adherence. Over 6 months, 32 patients showed good adherence, and 10 showed poor adherence, resulting in total PAP adherence of 76.1% after 6 months (Table 2). The mean residual AHI of good adherence group was 4.5.
No significant correlation with good adherence was found for age, sex, diabetes mellitus (DM), heart disease, height, weight, BMI, systolic blood pressure (SBP), or diastolic blood pressure (DBP). But hypertension (HTN) was significantly correlated with poor PAP adherence.
Additionally, we analyzed the predictors of PAP adherence, based on PSG data (Table 2). Rapid eye movement (REM) sleep latency, the AHI of non-REM (NREM) sleep, the AHI of supine position, the total arousal index, and the respiratory arousal index were significantly correlated with good PAP treatment adherence. However, total sleep time, NREM sleep time, REM sleep time, sleep latency, sleep efficiency, wake after sleep onset (WASO), AHI of REM sleep, and AHI of non-supine position were not significantly correlated with good adherence to PAP treatment.

Adherence based on 3 months

During 2019, 66 participants were prescribed PAP treatment, of which 56 participants has maintained PAP treatment for more than 3 months (Table 3). Therefore, the 3-month adherence rate was found to be 84.8%, their mean residual AHI was 2.9.
Poor adherence of PAP treatment for 3 months was significantly correlated with hypertension, which was similar with the findings for 6 months results. However, no significant correlations were found with age, sex, DM, heart disease, height, weight, BMI, SBP, and DBP.
Table 3 also shows the results of examining factors associated with PAP adherence based on the PSG data. Similar to the 6-month results, REM sleep latency, AHI of NREM sleep, and AHI of supine position showed significant correlations with good adherence. In contrast with the 6-month results, respiratory arousal index and total arousal index were not correlated with 3-month PAP adherence. No significant differences were observed between the two groups for total sleep time, NREM sleep time, REM sleep time, sleep latency, sleep efficiency, WASO, AHI of REM sleep and AHI of non-supine position.

Discussion

The present study showed a 6-month PAP adherence of 76.1% and 3-month PAP adherence of 84.8% at a regional, tertiary sleep center in Korea. This is the first study reporting the adherence of PAP treatment in patients with OSA since PAP was included to NHI service in Korea.
These results are much higher than those reported by previous studies in Korea. Kim et al. reported a 35.7% adherence rate after 6 months, in 2015, and another study group reported a 59.4% adherence rate for PAP treatment after 3 months [10-12]. Similar to the findings of previous studies in Korea, many studies have explored PAP adherence among OSA patients in worldwide, and the results have varied. Up to 30% of patients fail to initiate therapy after diagnosis, and among those who start therapy, approximately 25% stop within the first year, and fewer than 50% remain adherent in the long term [13,14].
In Korea, a single universal health insurance system provides insurance for over 99% of the population [8]. Starting in July 2018, patients with OSA have begun to receive benefits from the National Health Insurance Service (NHIS). Because PAP treatment requires comparatively expensive equipment, the financial burden is closely related to compliance, and national policies, such as the health insurance system, can affect PAP treatment compliance [15]. Therefore, authors assessed that the high compliance of PAP treatment in this study compared to previous may be due to the benefits provided by the NHIS from 2018 in Korea. In addition to economic variables, adherence to PAP treatment is affected by various device-related factors and side effects, psychological factors, family, and spouse-related factors, socioeconomic factors, and physician-related factors. Device-related factors include discomfort caused by high pressure, vague discomfort of the device user, social and personal prejudices against device users, social and personal prejudices against the machine itself, which can lead patients to avoid the use of a troublesome system. Additional research focused on these factors should be included in a future study.
Patients with OSA often have one or more comorbidities, including obesity, dyslipidemia, glucose intolerance, and HTN [16,17]. With obesity, periods of obstructed breathing can result in profound intermittent hypoxia, with hypercapnia, negative intrathoracic pressure swings, and arousals [18]. Physiological changes that occur in response to obstructed breathing can include sympathetic activation, inflammation, oxidative stress, and endothelial dysfunction [19]. As a result, this series of diseases can result in increased blood pressure and HTN [16]. In studies examining the prevalence of sleep apnea amongst HTN populations, 20–40% of individuals have been diagnosed with comorbid sleep apnea, in our study, 40% of participants with OSA also had HTN, and patients with comorbid HTN showed a significant correlation with poor adherence. Future trials should explore how HTN comorbidity affects poor adherence to PAP treatment.
We demonstrated that PSG features significantly contributed to good PAP adherence, including prolonged REM latency, higher NREM AHI, higher supine AHI, and frequent arousal. These factors imply poor sleep quality. Although no significant difference in AHI was observed between the two groups, higher adherence may be correlated with the subjective discomfort caused by poor sleep quality, resulting in patients attempting to improve compliance. Additional research focused on these subjective factors should be included in a future study.
Most obstructive sleep apnea is worse during REM sleep than during NREM. However, several studies showed increased NREM AHI compared with REM AHI with OSA, which is similar to ours that NREM AHI was higher than REM AHI (35.5 events/hr vs. 32.6 events/hr, respectively, n=66) [20]. We assessed that lower AHI during REM sleep may be due to the deprivation of REM sleep opportunities, as a result of frequent awakening [20,21].
This study has several limitations. This study was a retrospective and single-center study, with a small sample. However, no studies have yet examined effect on adherence PAP treatment when the cost of treatment is covered by NHI in Korea. Therefore, this study demonstrated that health care services that relieve the economic burden of PAP machines may have a positive effect on compliance. We believe that these results will represent a useful reference for increasing adherence in other countries where public health services are well guaranteed. Another limitation is the lack of subjective symptom evaluations, such as the use of a sleep questionnaire. A self-reported questionnaire can provide information about the participant’s complaints regarding poor sleep quality. Further study remains necessary to evaluate the daytime sleepiness scale and additional data that may affect PAP adherence.
In conclusion, we demonstrated a 6-month PAP adherence was 76.1% and 3-month PAP adherence was 84.8% in patients with OSA in Korea, which showed increased adherence compared to that of previous studies conducted when PAP treatment was not insured. And authors also determined that prolonged REM latency, higher NREM AHI, and higher supine AHI are significant contributors to good PAP adherence, whereas comorbid hypertension is a factor for poor PAP compliance.

Acknowledgments

This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.

Notes

Conflicts of Interest
The authors have no potential conflicts of interest to disclose.
Author Contributions
Conceptualization: Hyo-Eun Yoon, Ji-Ye Jeon. Data curation: Hyo-Eun Yoon, Chang-Jin Jeon. Formal analysis: Hyo-Eun Yoon, Ji-Ye Jeon. Investigations: Jaechun Hwang, Ho-Won Lee. Methodology: Ji-Ye Jeon. Supervision: Chang-Jin Jeon, Ho-Won Lee. Writing—original draft: Hyo-Eun Yoon. Writing—review & editing: Jaechun Hwang, Ji-Ye Jeon.

Table 1.
Demographic characteristics of the study population
Characteristics Values (n=66)
Age, year 55.7±13.5
Sex, n (%)
 Male 50 (75.7)
 Female 16 (24.2)
Height, cm 166.8±9.4
Weight, kg 75.2±17.4
BMI, kg/m2 26.9±5.4
Polysomnography data
 Snoring index (events/hour) 336.4±188.6
 AHI (events/hour) 35.2±20.3
 Minimum O2 saturation, % 78.3±12.6
 Average O2 saturation, % 92.4±4.5

Data are presented as mean±standard deviation unless otherwise indicated. AHI: apnea-hypopnea index, BMI: body mass index

Table 2.
Comparison of the characteristics between the good and poor adherence groups for 6 months
Variables Good adherence (n=32) Poor adherence (n=10) p
Age, year 54.3±12.8 61.0±11.2 0.209
Sex, n (%) 0.105
 Male 27 (84.4) 6 (60)
 Female 5 (15.6) 4 (40.0)
Hypertension, n (%) 12 (37.5) 8 (80.0) 0.031*
DM, n (%) 4 (12.5) 3 (30.0) 0.236
Heart disease, n (%) 2 (6.3) 0 (0.0) 0.408
Height, cm 169.4±9.1 163.5±7.9 0.087
Weight, kg 76.9±17.6 71.2±23.6 0.160
BMI, kg/m2 26.6±4.6 26.5±7.8 0.658
SBP, mm Hg 134.0±16.1 136.2±18.1 0.701
DBP, mm Hg 84.9±8.9 81.8±9.7 0.296
Polysomnography data
 Total sleep time, min 330.7±60.5 343.7±57.7 0.679
  NREM sleep time 286.0±52.6 289.5±62.0 0.779
  REM sleep time 44.7±24.4 54.2±25.1 0.184
 Sleep latency, min 22.0±21.6 18.5±13.8 0.976
  REM sleep latency, min 141.6±85.8 84.2±57.8 0.022*
 Sleep efficiency, % 77.3±13.8 80.6±8.7 0.690
 WASO, min 75.3±61.2 63.9±34.0 0.988
 AHI (event/hr) 36.4±18.1 25.4±20.3 0.059
  NREM AHI 36.5±18.7 23.7±22.4 0.022*
  REM AHI 33.8±21.4 28.7±18.3 0.555
  Non-supine AHI 19.2±23.8 16.7±33.9 0.413
  Supine AHI 40.2±19.5 27.2±11.3 0.030*
 Total arousal index (arousal/hr) 35.2±22.3 23.4±19.3 0.024*
 Respiratory arousal index 26.5±18.3 16.5±20.7 0.036*
 Sleep stage
  N1 (min) 117.9 99.3 0.072
  N2 (min) 154.4 170.4 0.294
  N3 (min) 13.6 19.8 0.199
  REM (min) 44.7 54.2 0.184

Data are presented as mean±standard deviation unless otherwise indicated.

* statistically significant (p<0.05).

DM: diabetes mellitus, BMI: body mass index, SBP: systolic blood pressure, DBP: diastolic blood pressure, REM: rapid eye movement, WASO: wake after sleep onset, NREM: non-rapid eye movement, AHI: apnea-hypopnea index

Table 3.
Comparison of the characteristics between the good and poor adherence groups for 3 months
Variables Good adherence (n=56) Poor adherence (n=10) p
Age, year 54.9±13.9 61.0±11.2 0.260
Sex, n (%) 0.210
 Male 44 (78.6) 6 (60.0)
 Female 12 (21.4) 4 (40.0)
Hypertension, n (%) 19 (33.9) 8 (80) 0.010*
DM, n (%) 8 (14.3) 3 (30) 0.259
Heart disease, n (%) 4 (7.1) 0 (0) 0.373
Height, cm 167.5±9.7 163.5±8.0 0.184
Weight, kg 76.0±16.3 71.2±23.7 0.170
BMI, kg/m2 27.1±5.0 26.5±7.8 0.507
SBP, mm Hg 133.0±16.1 136.3±18.2 0.523
DBP, mm Hg 83.9±8.3 81.8±9.7 0.444
Polysomnography data
 Total sleep time, min 326.5±61.2 343.7±57.8 0.707
  NREM sleep time 279.5±53.0 289.5±62.0 0.986
  REM sleep time 47.2±24.2 54.2±25.2 0.304
 Sleep latency, min 21.3±21.0 18.5±13.9 0.830
  REM sleep latency 133.0±81.0 84.2±57.8 0.022*
 Sleep efficiency, % 77.1±14.1 80.6±8.7 0.674
 WASO, min 77.1±57.8 63.9±34.1 0.809
 AHI (event/hr) 37.0±20.0 25.4±20.3 0.060
  NREM AHI 37.7±20.5 23.8±22.4 0.024*
  REM AHI 33.4±23.7 28.8±18.4 0.707
  Non-supine AHI 20.1±24.7 16.8±34.0 0.415
  Supine AHI 41.3±22.0 27.2±11.4 0.036*
 Total arousal index (arousal/hr) 32.0±20.4 23.4±19.4 0.052
 Respiratory arousal index 24.3±18.2 16.5±20.7 0.059
 Sleep stage
  N1 (min) 102.5 99.3 0.283
  N2 (min) 161.4 170.4 0.491
  N3 (min) 15.3 19.8 0.249
  REM (min) 47.2 54.2 0.304

Data are presented as mean±standard deviation unless otherwise indicated.

* statistically significant (p<0.05).

DM: diabetes mellitus, BMI: body mass index, SBP: systolic blood pressure, DBP: diastolic blood pressure, REM: rapid eye movement, WASO: wake after sleep onset, NREM: non-rapid eye movement, AHI: apnea-hypopnea index

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