Introduction

Obstructive sleep apnea (OSA) is characterised by repetitive upper airway collapse during sleep, which induces frequent arousal and oxygen desaturation1. It is a common disease worldwide, affecting over 4% of men and 2% of women, and its prevalence increases with the prevalence of obesity2. OSA is associated with various symptoms such as fatigue, daytime somnolence, and headaches1. OSA causes serious cardiovascular complications and increases mortality1. Recently, various neurodegenerative disorders have also been suspected to be associated with OSA3.

Parkinson's disease (PD) is a typical neurodegenerative disorder that mainly affects the motor system4. It is characterised by tremors, rigidity, and slowness of movement at the beginning of the disease, making walking difficult4. As the disease progresses, dementia, depression, and anxiety occur more commonly. The characteristic pathologic findings are deposition of Lewy bodies and loss of dopaminergic neurons in the substantia nigra of the midbrain4. Once PD develops, it is fundamentally untreatable; attempts can only be made to improve symptoms through medication, rehabilitation, and electrical stimulation of the deep brain4. The prevalence of PD increases rapidly with age. The prevalence of PD in the elderly population over 60 years is about 1%, and the incidence is about 100 persons per 100,000 person-years5.

The relationship between PD and OSA has been steadily proposed in the literature for approximately 30 years6. Most studies have shown that the prevalence of OSA is high in patients with PD, probably because the upper airways of patients with PD collapse easily and their lung functions are reduced7. Several studies have reported that the occurrence of PD is also increased in patients with OSA8,9,10. One recent meta-analysis reported that OSA exacerbates cognitive function and motor symptoms in patients with PD, and another meta-analysis reported that OSA is an independent risk factor for PD11,12. Although the exact mechanism is unknown, it is presumed that the oxidative stress caused by intermittent hypoxia and sleep fragmentation in patients with OSA accelerates degenerative changes in the brain to induce the development of PD13. However, all these studies were based on a relatively small number of subjects, and the results differed slightly from study to study8,9,10. In addition, effects of the surgical treatment of OSA on PD incidence have not been evaluated.

Uvulopalatopharyngoplasty (UPPP) is the most commonly performed surgery for OSA14,15. Its success rate, based on the apnea-hypopnoea index (AHI) reduction, is not high14. However, UPPP can be a therapeutic option in patients who refuse or are intolerant of continuous positive airway pressure (CPAP)14. Therefore, it is meaningful to evaluate UPPP in terms of clinical impact, such as reduction in the incidence of PD. To demonstrate this clinical impact, long-term observational studies of large populations are required, but such studies are difficult to perform. The Korea National Health Insurance Service (KNHIS) database has recently become available for research purposes in Korea16. The KNHIS is a national insurer managed by the Korean government covering nearly the entire population; therefore, it can provide credible, long-term follow-up data on more than 50 million people16. Consequently, a retrospective cohort could be constructed by collecting data on patients with OSA as well as those who underwent UPPP.

The purpose of this study was to investigate, by using the KNHIS data, whether the incidence of PD increases among patients with OSA and whether UPPP can decrease such an increase.

Materials and methods

This retrospective cohort study was conducted according to the STROBE guidelines17.

Data source

The KNHIS is a national insurer managed by the Korean government covering nearly 100% of the Korean population and reviews both outpatient and inpatient claims, which include data on the diagnosis, procedures, prescription records, demographic information, and direct medical costs16. It manages the claims using a modified version of the International Classification of Diseases, 10th edition (ICD-10). Any researcher can use the KNHIS data if the study protocol is approved by the official review committee.

Study population and design

The OSA group included subjects who were newly diagnosed with OSA (G47.30) between 2007 and 2014. Patients younger than 20 years, or those who were already diagnosed with PD, were excluded. The control group was selected from those who did not have a diagnosis of OSA, using propensity score matching by age and gender. The control group was five times larger than the OSA group. The OSA group was further divided into two subgroups: (1) the surgery group, comprising OSA patients who underwent UPPP (Q2196 or Q2197), and (2) the conservative group, comprising OSA patients who did not undergo UPPP. The patients were tracked until 31st December 2015. The primary endpoint of this study was a new diagnosis of PD, which was identified from the insurance claims data (Table 1). The flowchart shows the enrolment process for this study (Fig. 1).

Table 1 Working definitions derived from the insurance claims data.
Figure 1
figure 1

Patient enrolment flowchart.

Data collection

We collected the following data from the KNHIS database: age (years), sex, income level (lowest quintile), and comorbidities (diabetes, hypertension, dyslipidemia, chronic obstructive pulmonary disease, myocardial infarction, and cancer). Comorbidity was defined based on the ICD code, prescription, or hospitalisation record in the claims data (Table 1).

Statistical analysis

Comparisons between groups were made using the ANOVA or chi-square test. The cumulative incidence plot was used to identify and roughly compare the difference in PD incidence between the OSA and control groups or between the conservative and surgery groups. The incidence of PD was calculated by dividing the number of events by the person-year at risk. To determine the hazard ratio (HR) of OSA on PD, the Cox proportional hazards model was used. Three different models were applied: Model 1 was not adjusted, Model 2 was adjusted for age and sex, and Model 3 was based on Model 1, with adjustment for income level, diabetes, hypertension, and dyslipidemia18,19,20. The results are presented as HR and 95% confidence intervals (95% CIs). Statistical calculations were performed using R version 3.2.3 (The R Foundation for Statistical Computing, Vienna, Austria) and SAS version 9.4 (SAS Institute, Cary, NC, USA).

Ethical approval

The study was exempted from approval by the Institutional Review Board of Konkuk University Hospital due to the use of publicly available data (KUH1110066). In addition, informed consent for study participants was not required because this study corresponds to secondary analysis using claim data.

Results

Between 2007 and 2014, there were 202,726 patients newly diagnosed with OSA (OSA group). Of these, 22,742 underwent UPPP (surgery group). A total of 1,013,630 subjects were selected as the control group (Fig. 1). The mean follow-up duration was 4.8 ± 2.3 years.

Demographic characteristics of the surgery, conservative, and control groups

In a comparison of the three groups, the surgery group had the highest male percentage (87.28%) and the lowest average age (41.8 ± 11.5 years). The lower quintile ratio of income was highest in the control group (22.43%) and lowest in the surgery group (15.44%). The prevalence of comorbidities was higher in the conservative group than in the control group. The surgery group had a lower prevalence of comorbidities than the conservative group, but the prevalence was generally higher than in the control group. The demographic data is summarised in Table 2.

Table 2 Demographic characteristics of patients with OSA and controls.

Hazard ratio for Parkinson’s disease in patients with OSA

The cumulative incidence plot showed that PD occurred more frequently in the conservative group compared to the control group and less frequently in the surgery group (Fig. 2). The HR was higher in the conservative group than in the control group (2.84 for Model 1/2.71 for Model 2/2.57 for Model 3), and this finding was statistically significant in all three models. A comparison of the surgery group with the control group showed that the HR of a new PD diagnosis in the surgery group was lower than that in the control group in Model 1 (0.81, 95% CI 0.50–1.24), but higher than that in the control group in Model 2 (1.52, 95% CI 0.93–2.32) and Model 3 (1.45, 95% CI 0.89–2.22). However, the 95% CI included 1 for all three models, which means there was no significant difference between the surgery and control groups. These results are summarised in Table 3.

Figure 2
figure 2

Cumulative incidence plot for Parkinson’s disease in patients with OSA. Compared to the Control group, Parkinson’s disease occurs more frequently in the Conservative group and less frequently in the Surgery group.

Table 3 Hazard ratio for Parkinson’s disease in patients with OSA.

Discussion

In this study, we found that the HR of a new PD diagnosis among patients with OSA (OSA group) was significantly higher than that in the control group. However, in patients who underwent UPPP (surgery group), the HR of PD was similar to that in the control group. Based on these results, we estimated that the incidence of PD was increased in patients with OSA and that UPPP could prevent this increase. The greatest strength of this study is that it followed up more than 1.2 million people over 4 years on average. Moreover, this is the first report on the clinical possibility of using UPPP to reduce comorbidities among patients with OSA.

Three studies have investigated the occurrence of PD in patients with OSA using the Taiwan Health Insurance data8,9,10. The initial study was conducted by Chen, and it compared 5864 patients with OSA with 23,269 controls8. The risk of PD in the patient group increased by 1.84 times (95% CI 1.40–2.43) after adjustment for various factors. The risk was highest in women aged 50–69 years. In a study conducted by Yeh, 16,730 patients were compared with the same number of controls, and the mean follow-up period was 5.6 years9. Overall, the risk of PD in the patient group increased by 1.37 times (95% CI 1.12–1.68) after adjustment. The risk was significantly increased in elderly patients over 65 years of age (30.60 times compared to those under 50 years), and there was no difference between men and women. Another study conducted by Chou compared 1944 patients with OSA with 9720 controls, and the mean observation period was 3 years10. The risk of PD in the patient group increased by 1.85 times (95% CI 1.02–3.35) after adjustment. When the results were further analysed by sex and age, the risk of PD was increased in men only, and it increased rapidly in elderly people over 60 years. Using the same health insurance data, all three studies showed that the incidence of PD was increased in patients with OSA, which is consistent with our findings. Therefore, we believe that our results are credible.

As mentioned in the introduction, it is presumed that intermittent hypoxia and sleep fragmentation, the major pathophysiology of OSA, induce brain degeneration and increase the occurrence of PD13. Although UPPP does not completely normalise the AHI in OSA patients, we believe that it might mitigate OSA and reduce the progression of PD. The incidence of PD in the surgery group was lower than that in the control group (Fig. 2). There are two main reasons for this. First, UPPP improved OSA, and second, because the average age of the surgery group was younger than that of the control group. Since the incidence of PD increases with age, it is considered that the simple incidence of PD may have decreased further in the surgery group5. However, when age and sex were adjusted for (Table 3), the HR for the surgery group increased to 1.52 compared to that for the control group, but the 95% CI was 0.93–2.32, which means that the risk of PD occurrence in the surgery group was not different from that of the control group.

There are no studies on the effect of CPAP or mandibular advancing devices (MAD) on the occurrence of PD in OSA patients. However, several studies have shown that when CPAP is worn in patients with PD and OSA, sleep quality, motor function, and cognition are improved, and daytime sleepiness is reduced21,22,23. In addition, MAD also improved the sleep quality of patients with PD24. These findings are consistent with the findings of this study that OSA treatment can partially prevent the progression of PD.

The most significant limitation of this study is the potential selection bias for the surgery group. Generally, surgery for OSA is more likely to be performed in younger, healthier, and more affluent patients due to the risks associated with anaesthesia, complications, and the cost of surgery25. In this study, the surgery group was younger by approximately 4 years, had a slightly higher income level, and had a lower prevalence of various comorbidities than the conservative group. Moreover, compared with the control group, the surgery group was younger and had a higher income level. Therefore, the reason for the low incidence of PD in the surgery group could be that the patients in the group were younger and healthier than those in the comparison groups, rather than the surgical effect. However, even after adjusting for various factors, the incidence of PD in the surgery group was still lower than that in the conservative group, reaching the same level as that in the control group. Thus, we can conclude this finding was not due to the measured confounding factors.

Another limitation of this study is the inability to determine the validity of the diagnosis and severity of the disease. We were unable to obtain data on AHI values ​​and symptoms from medical records. Therefore, we only defined the OSA group based on the ICD code in the claims record. In addition, since polysomnography was not performed to exclude subjects with OSA, a significant number of subjects with OSA may have been included in the control group. A further issue to be noted is that we could not determine how many patients in the conservative group were offered alternative treatments, such as CPAP or MAD. Approximately 3000 patients are prescribed CPAP annually; however, the rate of adherence to it is believed to be very low26. Moreover, fewer patients are prescribed MAD16. Considering that the number of patients in the OSA group was about 200,000, it is reasonable to assume that most patients in the conservative group did not undergo active treatment for OSA, and their condition progressed naturally.

Furthermore, the short follow-up period should be considered a limitation. The average age of the subjects ranged from 41 to 45 years. The average follow-up period was 4.8 years. Considering that PD occurs mainly in elderly individuals, the follow-up period was not sufficient. A longer follow-up period (for example, more than 10 years) would provide more definitive results. Finally, another limitation is that the analysis of various factors that can affect the occurrence of PD, such as body mass index, smoking, alcohol, occupation, and drugs were not conducted.

Conclusion

The incidence of PD was significantly higher among patients with OSA than among controls, whereas in patients with OSA who underwent UPPP the incidence of PD was similar to that among controls. This study provides new insight indicating that UPPP may have a preventive effect on PD in patients with OSA.