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Association between multimorbidity and undiagnosed obstructive sleep apnea severity and their impact on quality of life in men over 40 years old

Published online by Cambridge University Press:  04 June 2018

G. Ruel
Affiliation:
Direction québécoise du cancer, Ministère de la Santé et des Services sociaux, Québec, Canada Centre de recherche du CHUM, Université de Montréal, Montréal, Canada
S. A. Martin
Affiliation:
Discipline of Medicine, University of Adelaide, South Australia, Australia
J.-F. Lévesque
Affiliation:
Centre de recherche du CHUM, Université de Montréal, Montréal, Canada Bureau of Health Information, New South Wales, Australia
G. A. Wittert
Affiliation:
Discipline of Medicine, University of Adelaide, South Australia, Australia
R. J. Adams
Affiliation:
Discipline of Medicine, University of Adelaide, South Australia, Australia Health Observatory, The Queen Elizabeth Hospital, Woodville, South Australia, Australia
S. L. Appleton
Affiliation:
Discipline of Medicine, University of Adelaide, South Australia, Australia Health Observatory, The Queen Elizabeth Hospital, Woodville, South Australia, Australia
Z. Shi
Affiliation:
Discipline of Medicine, University of Adelaide, South Australia, Australia Population Research and Outcome Studies, University of Adelaide, South Australia, Australia
A. W. Taylor*
Affiliation:
Discipline of Medicine, University of Adelaide, South Australia, Australia Population Research and Outcome Studies, University of Adelaide, South Australia, Australia
*
*Address for correspondence: Adjunct Professor A. W. Taylor, Population Research & Outcome Studies, Discipline of Medicine, The University of Adelaide, L7, SAHMRI, Adelaide, South Australia, Australia. (Email: [email protected])
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Abstract

Background.

Multimorbidity is common but little is known about its relationship with obstructive sleep apnea (OSA).

Methods.

Men Androgen Inflammation Lifestyle Environment and Stress Study participants underwent polysomnography. Chronic diseases (CDs) were determined by biomedical measurement (diabetes, dyslipidaemia, hypertension, obesity), or self-report (depression, asthma, cardiovascular disease, arthritis). Associations between CD count, multimorbidity, apnea-hyponea index (AHI) and OSA severity and quality-of-life (QoL; mental & physical component scores), were determined using multinomial regression analyses, after adjustment for age.

Results.

Of the 743 men participating in the study, overall 58% had multimorbidity (2+ CDs), and 52% had OSA (11% severe). About 70% of those with multimorbidity had undiagnosed OSA. Multimorbidity was associated with AHI and undiagnosed OSA. Elevated CD count was associated with higher AHI value and increased OSA severity.

Conclusion.

We demonstrate an independent association between the presence of OSA and multimorbidity in this representative sample of community-based men. This effect was strongest in men with moderate to severe OSA and three or more CDs, and appeared to produce a greater reduction in QoL when both conditions were present together.

Type
Original Research Article
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s) 2018

Introduction

Obstructive sleep apnea (OSA) is defined as the cessation of naso-buccal air flow for more than 10 s [Reference Guilleminault, Tilkian and Dement1] and is diagnosed based on the apnea-hypopnea index (AHI) [Reference Young2]. A systematic review [Reference Moyer3] showed the impaired quality of life (QoL) in OSA patients when compared with population norms. Severe OSA has also been demonstrated to increase all-cause mortality [Reference Punjabi4]. Risk factors for OSA include ageing, elevated Body Mass Index (BMI) and male gender [Reference Punjabi5, Reference Tufik6]. Aside from the well-known relationship with obesity, OSA has been previously reported to be associated with hypertension [Reference Fletcher7], cardiovascular disease (CVD) [Reference Fletcher7, Reference Wolf, Lewicka and Narkiewicz8], diabetes [Reference Strohl9, Reference Reichmuth10], chronic obstructive pulmonary disease [Reference Smith11] and depression [Reference Smith11].

Multimorbidity, or the presence of two or more medical conditions in an individual [Reference van den Akker, Buntinx and Knottnerus12], has a high prevalence in numerous populations [Reference Fortin13Reference Taylor15]. Multimorbidity prevalence increases with age [Reference Fortin14, Reference Salisbury16] and social deprivation [Reference Salisbury16, Reference Barnett17], and is associated with increased medical consultations, prescriptions, emergency hospital utilisation, hospital length of stay and mortality rates [Reference Broemeling, Watson and Prebtani18Reference Fortin20]. The relationship between the presence of OSA and the development of multimorbidity and the subsequent impact on QoL remains unclear [Reference Smith11, Reference Robichaud-Halle, Beaudry and Fortin21]. This is complicated by the fact that OSA remains a severely under-diagnosed condition, particularly in middle-aged to elderly men. Recent estimates suggest approximately 75–80% of OSA cases may be undiagnosed [Reference Kapur22, Reference Young23] thereby limiting any understanding of the true association between OSA and chronic disease burden. High multimorbidity has been previously demonstrated in men with severe but not moderate or mild OSA [Reference Robichaud-Halle, Beaudry and Fortin21] among a primary care population referred to a sleep laboratory for further evaluation. To the best of our knowledge, there is no information on the relationship between multimorbidity and OSA among the general population. Consequently, our aim was to examine whether there is an independent association between the presence and severity of OSA and multimorbidity, and subsequent impacts on QoL, in a community-based cohort of middle-aged to elderly men.

Methods

Study design

The Men Androgen Inflammation Lifestyle Environment and Stress (MAILES) Study comprises randomly selected urban community-dwelling men from South Australia aged 35 years at the time of enrolment [Reference Grant24]. Initial random sample selection was by Electronic White Pages and recruitment by computer-assisted telephone interviews (CATI) occurred in 1999–2005. Biomedical, health, lifestyle and behavioural assessment was conducted in two hospital-based clinics at baseline and follow-up (2008–10), using standardised and reproducible study protocols including anthropometry. Of the 2038 participants at follow-up, 1445 without previously diagnosed OSA were invited to participate in a sleep substudy with 75.2% agreeing. Of these, a random sample of 1000 men was chosen for inclusion and by the end of the study period, 837 successfully underwent polysomnography (PSG). For the current analysis, we excluded men with incomplete information for any CD leading to a total of 743 men (Fig. 1). Previous analyses have demonstrated that the 837 men who participated in the MAILES sleep study were broadly representative of the target population [Reference Grant24]. An additional analysis of these men and the current analytic sample, demonstrated comparability across age group, education, region of birth, marital status, with the current analytic sample have a slightly higher proportion of men from higher income households and retirees (data not shown).

Fig. 1. Flow chart of the sleep substudy of the MAILES cohort. OSA, obstructive sleep apnea; PSG, polysomnography; and AHI, apnea hypopnea index.

The study was approved by Queen Elizabeth and the Royal Adelaide Hospital Human Research Ethics Committees (HREC) and written consent were obtained.

Obstructive sleep apnea

In 2010–2011, subjects without a previous OSA diagnosis underwent 8-channel in-home unattended PSG (Embletta X100, Embla Systems, Colorado) which measured Electroencephalogram (EEG), Electroculogram, Electromyogram, nasal pressure, thoracic and abdominal effort, oximetry, body position, and limb movements. Trained staff visited study participants in their homes to set-up and attach the sleep study equipment, and measure neck circumference. Failed studies were repeated if possible. A single experienced sleep technician performed manual scoring of all home PSGs according to the 2007 American Academy of Sleep Medicine (AASM) (alternate) criteria [Reference Berry25]. An apnea was defined as cessations of nasal flow lasting ⩾10 s, and hypopneas as a >50% decrease in nasal flow (or in both thoracic and abdominal excursions) and associated ⩾3% oxygen desaturation or an EEG arousal. OSA was defined as an AHI ⩾10/h. Prior work suggests an AHI of 5/h used to define sleep-disordered breathing in the Wisconsin study [Reference Young2] is approximately equivalent to an AHI of 10/h using the alternate AASM definition [Reference Ruehland26]. The Epworth Sleepiness Scale [Reference Johns27], Pittsburgh Sleep Quality Index [Reference Buysse28] and the STOP questionnaire [Reference Chung29] were administered at the time of the PSG.

Multi-morbidity and chronic disease assessments

Multimorbidity was defined as per [Reference van den Akker, Buntinx and Knottnerus12] as the concurrent presence of two or more of the following nine conditions assessed at study follow-up clinics (2008–10): asthma, heart disease, diabetes, depression, hyperlipidemia, hypertension, obesity, osteoarthritis and rheumatoid arthritis. Depression, diabetes, hyperlipidemia, hypertension and obesity were determined during the clinic visit (see [Reference Grant30] for an overview). Height was measured to the nearest 0.5 cm using a stadiometer, and weight to the nearest 0.1 kg in light clothing and without shoes using standard digital scales. BMI was calculated as weight (kg)/height (m)2. Obesity was defined as a BMI ⩾30 kg/m2. A fasting blood test was performed to determine total cholesterol and fasting plasma glucose (FPG) levels. Men were deemed to have diabetes if they self-reported having ever been told by a doctor they had the condition, self-reported utilisation of glucose-lowering drugs or by measurement at the clinic (FPG⩾7.0 mmol/L) [31, Reference Chittleborough32]. Hyperlipidemia was defined as total blood cholesterol ⩾5.5 mmol/L or self-report use of cholesterol-lowering drugs [33]. Three blood pressure measurements were taken 5–10 minutes apart using a standard, calibrated blood pressure sphygmomanometer, while the participant was relaxed and seated. The average of the final two measures was used in the analyses. High blood pressure was defined as systolic blood pressure⩾140 mm Hg and/or diastolic blood pressure⩾90 mm Hg or the self-reported use of drugs to lower blood pressure. Depression status was determined using either a score over 15 for the Centre for Epidemiological Studies Depression Scale [Reference Radloff and Rae34] or a score over 13 for the Beck Depression Index [Reference Lasa35]. Participants self-reported if they had ever been told by a doctor they had asthma, any heart condition (including stroke), osteoarthritis or rheumatoid arthritis.

QoL assessment

Health-related QoL was assessed using the Short Form 36 questionnaire (SF-36) at study follow-up. The first general health questions (SF1), as well as the mental and physical component summary (MCS and PCS) domains, scored on Australian normative data, were used in the analysis [Reference Tucker, Adams and Wilson36].

Physical and socio-demographic characteristics

Participants were interviewed by trained health workers using a pre-coded questionnaire at study follow-up. Individual-level variables included age, gender, marital status and education level, household income, receiving government benefits or pension and employment status. Detailed demographic, biographical and risk factor information was collected via a self-completed questionnaire.

Statistical analyses

Initial descriptive analyses were conducted to examine the correlation between the outcome measure (multimorbidity; expressed initially as the total number of CDs) and exposure measure (OSA; expressed as continuous AHI), and selected physical characteristics, socio-demographic factors, CD and QoL status. Spearman correlation coefficients (r s) were calculated to approximate the direction and degree of the monotonic relationship between AHI and CD values, and with the selected covariates. Participants were grouped across the four exposure levels [absent/none (AHI<10), mild (AHI ⩾10 and <20), moderate (AHI⩾20 and <30) and severe (AHI⩾30)] to compare against the number of CDs and QoL (PCS and MCS scores of the SF-36) using the Kruskal–Wallis H test. Multinomial logistic regression models for multimorbidity (2+ CDs vs 0–1 CD & 3+ CDs vs 0–2 CDs) and QoL were then fitted across all exposure levels (Absent, Mild, Moderate and Severe) to determine crude, age-adjusted, and multi-adjusted odds ratios. Finally, to test for any interaction between multimorbidity and OSA on QoL, number of CDs, OSA severity categories and their interaction terms were compared against the PCS and MCS domains of the SF-36. (as measured by the SF-1, MCS and PCS). Unless stated otherwise, standard errors are presented in tables and standard deviation in the text. Crude data are presented in tables and text. All analyses were carried out using SPSS version 20.0 (SPSS, Inc., Chicago, IL, USA) and a p < 0.05 was considered significant.

Results

Table 1 describes the baseline physical and socio-demographic characteristics of the 743 study participants. The mean age of the cohort was 59 ± 11 years (mean age ± s.d.) and the range was between 41 and 87 years. The mean BMI was 28.6 ± 2.6 kg/m2 and 44% of the cohort were obese (BMI⩾30 kg/m2). Fifty-two percent of the cohort had OSA as defined by an AHI value over 10.

Table 1. Baseline physical and socio-demographic characteristics of the 743 participants

AHI was shown to have a comparable, positive correlation coefficient with multimorbidity status and CD count, as with neck circumference and age; both recognised risk factors for OSA. CD count and AHI were both negatively correlated with general QoL and the PCS domain of the SF-36, and to a lesser degree the MCS, with CD count demonstrating a significantly stronger correlation with all measures QoL indices. AHI and number of CDs also showed a positive correlation between work and smoking status and negative correlation with income status (with higher CD count additionally associated with lower education status) (Table 2).

Table 2. Bivariate associations between AHI and chronic disease count and physical, social, quality of life and sleep questionnaire

*Spearman correlation coefficient.

Among those with OSA, 52, 27 and 21% of the population had mild (AHI⩾10 and <20), moderate (AHI⩾20 and <30) and severe (AHI⩾30) OSA, respectively. The mean number of CDs increased progressively for those with mild and moderate OSA severity and plateaued thereafter (Fig. 2, panel A). Overall, men in the severe group had 0.78 more CDs [95% CI (0.42–1.14)] than those without OSA (p ⩽ 0.001 in the fully adjusted model). AHI was 9.4 events per hour higher in those with three or more CDs than those without any CD (p ⩽ 0.001).

Fig. 2. Relationship between obstructive sleep apnea severity and the mean number of chronic disease and PCS and MCS SF-36 score in the 743 men. 1, 2 and 3, significantly different from the absent, mild and moderate severity group, respectively. Data are adjusted for age, sedentary lifestyle, marital, gross income, working and smoking status.

Among the 743 men included, 58% of the population had multimorbidity. The proportion of those with multimorbidity was higher in those with OSA than in those without (67% v. 48%, p ⩽ 0.001). There was no significant difference in multimorbidity proportion between the mild, moderate and severe groups, although the mean number of CDs was significantly higher in the moderate and severe groups when compared with the mild severity group (Fig. 2). However, when the moderate and severe groups were pooled, the proportion of those with three CDs in this group was 12% higher (p ⩽ 0.05) than those in the mild group, suggesting that those with three CDs have a major impact on the relationship between multimorbidity and the severity of OSA. Among individual CDs, the proportions of hypertension, obesity, diabetes and CVD were 22% (p ⩽ 0.05), 28% (p ⩽ 0.05), 8% (p ⩽ 0.05) and 10% (p ⩽ 0.05) higher in those with moderate or severe OSA than in those without OSA. The proportions of those with hypertension and depression were 14% (p ⩽ 0.05) and 7% (p ⩽ 0.05) higher in those with mild OSA than in those without the disease. Obesity was the only CD for which there was a significant difference between the mild and the moderate/severe group (+20%, p ⩽ 0.05). There was also a detrimental impact of OSA on both the PCS (p ⩽ 0.0001) and MCS (p ⩽ 0.05) summary scores of QoL but only at a severe OSA level.

Odds ratios for OSA severity status were examined according to the presence of multimorbidity (Table 3). When compared with those without, those with multimorbidity were more likely to have mild, moderate or severe OSA than not having OSA. More precisely, the unadjusted odds ratios of having mild, moderate or severe OSA were 1.91 (1.34–2.72), 2.92 (1.80–4.73) and 2.52 (1.51–4.21), respectively, when compared with those without OSA. The odds ratios for those with more than three CDs were 3.27 (1.47–7.29), 5.11 (2.17–12.04) and 6.59 (2.78–15.64) for the mild, moderate and severe OSA groups when compared with those without OSA. The odds ratio of having fair or lower health status was also significantly higher in those with severe OSA than in those without the condition [3.20 (1.72–5.93)].

Table 3. Differences in proportions of the participants and estimated odds ratios between OSA severity categories for multimorbidity, quality of life, sleepiness and sleep quality and estimated OSA risk

*Odds ratios are presented from the adjusted model.

a Significantly different from the group without OSA in unadjusted model.

The interaction between multimorbidity and OSA severity status was significant for both the PCS and the MCS QoL measures (Fig. 3). For those with two or less CDs, there were no significant differences between OSA groups in both PCS and MCS mean values. However, in those with three or more CDs, PCS significantly decreased with OSA severity from 0.38 SD for mild to 0.68 SD for moderate/severe groups (p ⩽ 0.05 for moderate/severe v. mild). In contrast, there was a significant 0.50 SD decrease in MCS score in those with OSA, independently of the severity, than in those without. In the MCS model, while the interaction between OSA and multimorbidity was significant (p ⩽ 0.05), the effect of OSA status alone was not (p = ns) in opposition to the effect of multimorbidity (p ⩽ 0.001). A similar relationship as for MCS was found in those with three CDs for general health status (SF1).

Fig. 3. Interaction between obstructive sleep apnea and chronic disease count on physical (panel a) and mental (panel b) components summary of the SF36 quality of life questionnaire in the 743 men. CD, chronic disease; OSA, obstructive sleep apnea; PCS, physical component summary; MCS, mental component summary.

Discussion

The present study contributes to the understanding of the relationship between multimorbidity and OSA severity in previously undiagnosed men. More precisely, this study reports that in men over 40 years old without a prior OSA diagnosis, (1) multimorbidity is associated with OSA; (2) the association between multimorbidity and OSA severity is more important in those with more than three CDs; and (3) a detrimental interaction between multimorbidity and OSA on QoL was found and was associated with OSA severity in PCS.

A previous study investigated the relationship between OSA and multimorbidity, as measured by CD count and the disease burden multimorbidity assessment (DBMA), a composite index taking into account the self-reported presence and burden of different CDs in patients who had undergone PSG following referral by a physician [Reference Robichaud-Halle, Beaudry and Fortin21]. Supportive of the results of the present study, Robichaud-Halle et al. reported an association between multimorbidity (DBMA) and severe OSA only [Reference Robichaud-Halle, Beaudry and Fortin21]. The mean CD count was not significantly different between OSA severity status, which is in contrast to our findings of a progressively significant increase in the number of CDs through OSA severity status. A major difference and a strength of the present study is that it explored previously undiagnosed OSA cases, which represent the majority of those with OSA [Reference Ramachandran and Josephs37]. While the referral/diagnostic bias (OSA suspicion v. undiagnosed) could explain discrepancies, other differences such as the number of CDs and AHI cut-off should be acknowledged. Also, the AHI cut-off used to classify severity status in the Robichaud-Halle study was based on the 3% desaturation criteria to define hyponeas with OSA defined by an AHI ⩾5 while the present study used 3% and AHI ⩾10. Notwithstanding, they are roughly equivalent according to the Rheuland study [Reference Ruehland26] which was adopted by the AASM and has been shown to be associated with worst cardiovascular outcomes [Reference Ruehland26, Reference Redline38, Reference Lee39].

Another important finding of the present study is that while multimorbidity is associated with undiagnosed OSA, those with exactly two CDs are not at an increased risk of OSA. The proportion of those with three or more CDs increased with positive OSA status but also with severity status making the use of three CDs a more interesting cut-off than the two CDs generally used in multimorbidity to investigate OSA status but also severity as previously suggested [Reference Fortin14].

The present results support the detrimental impact of multimorbidity [Reference Fortin40] and OSA [Reference Finn41] on QoL. The potential relationship between OSA and multimorbidity on QoL was previously suggested but not assessed [Reference Robichaud-Halle, Beaudry and Fortin21]. To the best of our knowledge, this study is the first to report a detrimental significant interaction effect between multimorbidity and OSA on QoL as measured by the SF-36 summary component scores. The impact of OSA was limited in those with two or less CDs although it became very important in those with more than three CDs. In this group, the presence of even mild OSA had an important detrimental impact on both the MCS and PCS scores. Interestingly, for PCS, the detrimental impact of OSA increased with its severity but this was not the case for MCS. In those with more than three CDs, the presence of undiagnosed OSA, even with mild severity, has an important impact on their QoL. Therefore OSA may be particularly important to identify in this population as, in clinical trials, continuous positive airway pressure (CPAP) therapy had a beneficial impact on PCS and MCS in most studies [Reference Siccoli42Reference Weaver44] but not all [Reference Montserrat45].

In a recent meta-analysis, an important bias noticed in the majority of analysed studies on OSA is that cohorts are mostly composed of patients tested on clinical suspicion of OSA and that information on undiagnosed cases are lacking [Reference Ramachandran and Josephs37]. The present study directly addresses this knowledge gap by investigating this population. Potential bias from those not participating in the study is possible but most likely accounted for by the relatively high proportion of eligible participants taking part in the PSG testing (59%). This is particularly important when considering that OSA is a condition with high undiagnosed rates and its timely treatment, could improve the management of other CDs [Reference Martinez-Garcia46] and improve health and QoL outcomes [Reference Redline38, Reference Lee39, Reference Chai-Coetzer47].

Strengths of the study include information on OSA severity (AHI), rather than OSA status and our large population (n = 743). This study has some limitations. While data have been adjusted for many risk factors, some potential residual confounders could still not be taken into account. The number of CDs investigated in the present study (9) is relatively small when compared with some other multimorbidity studies [Reference Fortin14] and future studies should include a higher number of CDs. In addition, not including men with incomplete details on their CDs could have introduced bias. However, the diagnosis of most of the CDs used in the study is based on biomedical measurement or validated questionnaires which are more precise than most other data sources since it permits accounting for undiagnosed conditions which have been previously shown to be high for some CDs [Reference Chittleborough48].

In summary, to the best of our knowledge, this study is the first to report an association between multimorbidity and OSA in a population of middle-aged to elderly men with undiagnosed OSA. This study also demonstrated that undiagnosed OSA has a major detrimental impact on the QoL of people with multimorbidity. Our data suggest that primary care physicians who treat men with multiple, chronic conditions should investigate the presence of OSA given its high rate of under diagnosis in the community and additional synergistic QoL burden.

Contributors

AWT, GAW, SA and RJA designed the study and SAM coordinated the study. GR took overall lead in the statistical analysis of the data. All authors contributed to the interpretation of the data, writing of the report and approved the final manuscript.

Declaration of interests

We declare that we have no competing interests.

References

1.Guilleminault, C, Tilkian, A, Dement, WC. The sleep apnea syndromes. Annual Review of Medicine 1976; 27: 465484.Google Scholar
2.Young, T, et al. The occurrence of sleep-disordered breathing among middle-aged adults. New England Journal of Medicine 1993; 328: 12301235.Google Scholar
3.Moyer, CA, et al. Quality of life in obstructive sleep apnea: a systematic review of the literature. Sleep Medicine 2001; 2: 477491.Google Scholar
4.Punjabi, NM, et al. Sleep-disordered breathing and mortality: a prospective cohort study. PLoS Medicine 2009; 6: e1000132.Google Scholar
5.Punjabi, NM. The epidemiology of adult obstructive sleep apnea. Proceedings of the American Thoracic Society 2008; 5: 136143.Google Scholar
6.Tufik, S, et al. Obstructive sleep apnea syndrome in the Sao Paulo epidemiologic sleep study. Sleep Medicine 2010; 11: 441446.CrossRefGoogle ScholarPubMed
7.Fletcher, EC. Cardiovascular consequences of obstructive sleep apnea: experimental hypoxia and sympathetic activity. Sleep 2000; 23 (Suppl. 4): S127S131.Google ScholarPubMed
8.Wolf, J, Lewicka, J, Narkiewicz, K. Obstructive sleep apnea: an update on mechanisms and cardiovascular consequences. Nutrition, Metabolism, and Cardiovascular Diseases 2007; 17: 233240.Google Scholar
9.Strohl, KP. Diabetes and sleep apnea. Sleep 1996; 19 (Suppl. 10): S225S228.Google Scholar
10.Reichmuth, KJ, et al. Association of sleep apnea and type II diabetes: a population-based study. American Journal of Respiratory and Critical Care Medicine 2005; 172: 15901595.Google Scholar
11.Smith, R, et al. What are obstructive sleep apnea patients being treated for prior to this diagnosis? Chest 2002; 121: 164172.CrossRefGoogle ScholarPubMed
12.van den Akker, M, Buntinx, F, Knottnerus, JA. Comorbidity or multimorbidity what's in a name? A review of literature. European Journal of General Practice [Review] 1999; 2: 6570.Google Scholar
13.Fortin, M, et al. Prevalence of multimorbidity among adults seen in family practice. Annals of Family Medicine 2005; 3: 223228.Google Scholar
14.Fortin, M, et al. A systematic review of prevalence studies on multimorbidity: toward a more uniform methodology. Annals of Family Medicine 2012; 10: 142151.Google Scholar
15.Taylor, AW, et al. Multimorbidity – not just an older person's issue. Results from an Australian biomedical study. BMC Public Health 2010; 10: 718.Google Scholar
16.Salisbury, C, et al. Epidemiology and impact of multimorbidity in primary care: a retrospective cohort study. The British Journal of General Practice 2011; 61: e12e21.CrossRefGoogle ScholarPubMed
17.Barnett, K, et al. Epidemiology of multimorbidity and implications for health care, research, and medical education: a cross-sectional study. Lancet 2012; 380: 3743.Google Scholar
18.Broemeling, AM, Watson, DE, Prebtani, F. Population patterns of chronic health conditions, co-morbidity and healthcare use in Canada: implications for policy and practice. Healthcare Quarterly (toronto, Ont ) 2008; 11: 7076.CrossRefGoogle ScholarPubMed
19.Librero, J, Peiro, S, Ordinana, R. Chronic comorbidity and outcomes of hospital care: length of stay, mortality, and readmission at 30 and 365 days. Journal of Clinical Epidemiology 1999; 52: 171179.Google Scholar
20.Fortin, M, et al. Psychological distress and multimorbidity in primary care. Annals of Family Medicine 2006; 4: 417422.Google Scholar
21.Robichaud-Halle, L, Beaudry, M, Fortin, M. Obstructive sleep apnea and multimorbidity. BMC Pulmonary Medicine 2012; 12: 60.Google Scholar
22.Kapur, V, et al. Underdiagnosis of sleep apnea syndrome in U.S. Communities. Sleep & Breathing 2002; 6: 4954.Google Scholar
23.Young, T, et al. Estimation of the clinically diagnosed proportion of sleep apnea syndrome in middle-aged men and women. Sleep 1997; 20: 705706.Google Scholar
24.Grant, JF, et al. Cohort profile: the Men androgen inflammation lifestyle environment and stress (MAILES) study. International Journal of Epidemiology 2013; 43: 10401053.Google Scholar
25.Berry, RB, et al. Rules for scoring respiratory events in sleep: update of the 2007 AASM manual for the scoring of sleep and associated events. Deliberations of the sleep apnea definitions task force of the American academy of sleep medicine. Journal of Clinical Sleep Medicine 2012; 8: 597619.Google Scholar
26.Ruehland, WR, et al. The new AASM criteria for scoring hypopneas: impact on the apnea hypopnea index. Sleep 2009; 32: 150157.Google Scholar
27.Johns, MW. A new method for measuring daytime sleepiness: the Epworth sleepiness scale. Sleep 1991; 14: 540545.Google Scholar
28.Buysse, DJ, et al. The Pittsburgh sleep quality index: a new instrument for psychiatric practice and research. Psychiatry Research 1989; 28: 193213.Google Scholar
29.Chung, F, et al. STOP questionnaire: a tool to screen patients for obstructive sleep apnea. Anesthesiology 2008; 108: 812821.Google Scholar
30.Grant, JF, et al. Cohort profile: the men androgen inflammation lifestyle environment and stress (MAILES) study. International Journal of Epidemiology 2014; 43: 10401053.Google Scholar
31.American Diabetes Association. Diagnosis and classification of diabetes mellitus. Diabetes Care 2004; 27 (Suppl. 1): S5S10.Google Scholar
32.Chittleborough, CR, et al. Health status assessed by the SF-36 along the diabetes continuum in an Australian population. Quality of Life Research 2006; 15: 687694.Google Scholar
33.AIHW. Australia's health 2010. In: AIHW, editor. Canberra: AIHW; 2010.Google Scholar
34.Radloff, LS, Rae, DS. Susceptibility and precipitating factors in depression: sex differences and similarities. Journal of Abnormal Psychology 1979; 88: 174181.Google Scholar
35.Lasa, L, et al. The use of the beck depression inventory to screen for depression in the general population: a preliminary analysis. Journal of Affective Disorders 2000; 57(1–3): 261265.Google Scholar
36.Tucker, G, Adams, R, Wilson, D. New Australian population scoring coefficients for the old version of the SF-36 and SF-12 health status questionnaires. Quality of Life Research 2010; 19: 10691076.Google Scholar
37.Ramachandran, SK, Josephs, LA. A meta-analysis of clinical screening tests for obstructive sleep apnea. Anesthesiology 2009; 110: 928939.Google Scholar
38.Redline, S, et al. Obstructive sleep apnea-hypopnea and incident stroke: the sleep heart health study. American Journal of Respiratory and Critical Care Medicine 2010; 182: 269277.Google Scholar
39.Lee, CH, et al. Severe obstructive sleep apnea and outcomes following myocardial infarction. Journal of Clinical Sleep Medicine 2011; 7: 616621.CrossRefGoogle ScholarPubMed
40.Fortin, M, et al. Multimorbidity and quality of life: a closer look. Health and Quality of Life Outcomes 2007; 5: 52.Google Scholar
41.Finn, L, et al. Sleep-disordered breathing and self-reported general health status in the Wisconsin sleep cohort study. Sleep 1998; 21: 701706.Google Scholar
42.Siccoli, MM, et al. Effects of continuous positive airway pressure on quality of life in patients with moderate to severe obstructive sleep apnea: data from a randomized controlled trial. Sleep 2008; 31: 15511558.Google Scholar
43.Jenkinson, C, et al. Comparison of therapeutic and subtherapeutic nasal continuous positive airway pressure for obstructive sleep apnoea: a randomised prospective parallel trial. Lancet 1999; 353: 21002105.Google Scholar
44.Weaver, TE, et al. Continuous positive airway pressure treatment of sleepy patients with milder obstructive sleep apnea: results of the CPAP apnea trial north American program (CATNAP) randomized clinical trial. American Journal of Respiratory and Critical Care Medicine 2012; 186: 677683.Google Scholar
45.Montserrat, JM, et al. Effectiveness of CPAP treatment in daytime function in sleep apnea syndrome: a randomized controlled study with an optimized placebo. American Journal of Respiratory and Critical Care Medicine 2001; 164: 608613.Google Scholar
46.Martinez-Garcia, MA, et al. Effect of CPAP on blood pressure in patients with obstructive sleep apnea and resistant hypertension: the HIPARCO randomized clinical trial. JAMA 2013; 310: 24072415.CrossRefGoogle ScholarPubMed
47.Chai-Coetzer, CL, et al. Primary care v. specialist sleep center management of obstructive sleep apnea and daytime sleepiness and quality of life: a randomized trial. JAMA 2013; 309: 9971004.Google Scholar
48.Chittleborough, CR, et al. Medicare-related service use and costs among people with diagnosed and undiagnosed diabetes and respiratory conditions. Australian Health Review 2009; 33: 107116.Google Scholar
Figure 0

Fig. 1. Flow chart of the sleep substudy of the MAILES cohort. OSA, obstructive sleep apnea; PSG, polysomnography; and AHI, apnea hypopnea index.

Figure 1

Table 1. Baseline physical and socio-demographic characteristics of the 743 participants

Figure 2

Table 2. Bivariate associations between AHI and chronic disease count and physical, social, quality of life and sleep questionnaire

Figure 3

Fig. 2. Relationship between obstructive sleep apnea severity and the mean number of chronic disease and PCS and MCS SF-36 score in the 743 men. 1, 2 and 3, significantly different from the absent, mild and moderate severity group, respectively. Data are adjusted for age, sedentary lifestyle, marital, gross income, working and smoking status.

Figure 4

Table 3. Differences in proportions of the participants and estimated odds ratios between OSA severity categories for multimorbidity, quality of life, sleepiness and sleep quality and estimated OSA risk

Figure 5

Fig. 3. Interaction between obstructive sleep apnea and chronic disease count on physical (panel a) and mental (panel b) components summary of the SF36 quality of life questionnaire in the 743 men. CD, chronic disease; OSA, obstructive sleep apnea; PCS, physical component summary; MCS, mental component summary.