Obstructive sleep apnea (OSA) is likely underdiagnosed in Canada; however, lack of appropriate treatment puts many at risk of poor quality of life, comorbidity, motor vehicle crashes and increased health care utilization.
Obstructive sleep apnea should be considered in symptomatic patients with suggestive craniofacial features or comorbidities, even in the absence of classic risk factors such as older age, male sex or obesity.
Polysomnography is the gold standard for diagnosis; however, home sleep apnea testing may be used to confirm the diagnosis in symptomatic patients with a high pretest probability of OSA and without clinically important cardiopulmonary comorbidity.
Good evidence supports treatment of OSA with targeted therapies including continuous positive airway pressure or oral appliances, as well as promotion of weight loss and moderate exercise for those who are overweight (alternative treatments may be tried for those who do not tolerate usual therapies).
Obstructive sleep apnea (OSA) is characterized by recurring episodes of cessation (apnea) or reduction (hypopnea) in airflow during sleep caused by obstruction of the upper airway. In recent population-based studies, the estimated prevalence of moderate to severe sleep-disordered breathing ranges from 3% to nearly 50% depending on age group and sex.1,2 A survey conducted by the Public Health Agency of Canada in 2009 found that 26% of Canadian adults reported symptoms and risk factors that are associated with a high risk of OSA;3 however, prevalence data in Canada are limited by the absence of studies using objective sleep testing. Obstructive sleep apnea may be underdiagnosed; only 3% of Canadians aged 18 years or older reported a formal diagnosis despite high rates of symptom reporting;3 yet, high-quality prospective studies have shown clear benefit of treatment for patients with sleepiness, cognitive or psychological dysfunction, or poor quality of life owing to obstructive sleep apnea.4–6 Large population-based studies have shown that untreated moderate or severe OSA is associated with serious complications.7–9
We review signs, symptoms and morbidity associated with OSA, along with diagnostic options, treatments and considerations for long-term follow-up, based on evidence and recommendations from clinical guidelines, systematic reviews and primary studies (Box 1).
Evidence used in this review
We conducted a structured literature search of MEDLINE and the Cochrane Database of Systematic Reviews for “obstructive sleep apnea” or “sleep apnea,” in addition to targeted searches on PubMed. We excluded other forms of sleep disordered breathing. We limited our search to human studies that involved adults and that were published in the previous five years and written in English; however, we included several key papers that were published more than five years ago that substantially contributed to the field. We found 2921 articles, which were screened for relevance based on a review of titles and abstracts. Studies were selected for inclusion based upon the quality of evidence and relevance to the clinical questions discussed in this review.
What signs, symptoms and risk factors should prompt consideration of obstructive sleep apnea?
About 25% of patients with OSA report daytime sleepiness; a greater proportion report unrefreshing sleep or fatigue.10 Other symptoms include frequent nocturnal waking due to choking or gasping, nocturia, morning headaches, poor concentration, irritability and erectile dysfunction.11–13 Bed partners may report snoring or witnessed apneas. Atypical symptoms, which are more frequently reported by women, include insomnia, impaired memory, mood disturbance, reflux and nocturnal enuresis.14 However, the correlation of symptoms with disease severity is poor,15 which is why it is important for physicians to be alert to milder symptoms. There are many underlying risk factors, predisposing conditions and associated comorbidities for OSA; they are summarized in Appendix 1, available at www.cmaj.ca/lookup/suppl/doi:10.1503/cmaj.170296/-/DC1.
Features on physical examination that are associated with OSA include signs of central obesity (e.g., increased waist circumference, increased neck circumference), nasal septal deviation or turbinate hypertrophy, crowding of the posterior oropharynx as estimated by the Mallampati or Friedman score, or retrognathia.16–18 Oropharyngeal crowding may be caused by tonsillar enlargement, soft palate elongation, macroglossia or changes in dental occlusion.18 The pathophysiologic mechanisms predisposing to OSA are complex and overlapping;19 thus, neither history nor physical examination is sufficiently accurate to exclude the diagnosis of OSA. However, the features discussed above increase the pretest probability for OSA.
Various clinical prediction rules can assist in identifying patients with a high pretest probability for OSA;20 these include the Sleep Apnea Clinical Score,21 Berlin Questionnaire, 22 cricomental distance,23 OSA50,24 STOP-Bang,25 elbow sign questionnaire26 and American Society of Anesthesiologists checklist.27 These tools have typically been validated in high-prevalence populations, which is an important consideration when implementing them in routine practice. Although the Epworth Sleepiness Scale28 may not accurately identify patients with OSA,20 it is a useful tool for evaluating subjective sleepiness and treatment response.
Why is making a diagnosis of obstructive sleep apnea important?
There is limited evidence to support adverse health consequences of mild OSA, but associations between untreated moderate or severe OSA and several complications have been shown in several large population studies (definitions available in Box 2). Severe OSA confers a 2.6 times increased risk of incident myocardial infarction, coronary revascularization, congestive heart failure or cardiovascular death after controlling for confounders such as body mass index.30 Risk of ischemic stroke is increased in patients with untreated OSA, particularly in men with an apnea–hypopnea index (AHI) of more than 19 events per hour or women with an AHI of more than 25 events per hour.31 Other important cardiometabolic associations include atrial fibrillation, resistant hypertension and insulin resistance.32,33 Although recurrent, intermittent hypoxemia may be a better predictor of cardiovascular risk than AHI,34,35 lack of improvement in hypertension with nocturnal oxygen therapy suggests that the underlying mechanism is more complex than hypoxemia alone.36
Diagnosing obstructive sleep apnea
A and B, or C satisfy the criteria for a diagnosis of obstructive sleep apnea (OSA).29
A. The presence of one or more of the following:
The patient reports sleepiness, nonrestorative sleep, fatigue or insomnia symptoms.
The patient wakes with breath holding, gasping or choking.
The bed partner or other observer reports habitual snoring, breathing interruptions or both during the patient’s sleep.
A diagnosis of hypertension, a mood disorder, cognitive dysfunction, coronary artery disease, stroke, congestive heart failure, atrial fibrillation or type 2 diabetes mellitus in the patient.
B. Polysomnography or home sleep apnea testing shows:
Five or more predominantly obstructive respiratory events per hour of sleep during polysomnography or per hour of monitoring during home sleep apnea testing.
C. Polysomnography or home sleep apnea testing shows:
Fifteen or more predominantly obstructive respiratory events per hour of sleep during polysomnography or per hour of monitoring during home sleep apnea testing.
Severity of OSA:20
Mild OSA: AHI ≥ five events per hour
Moderate OSA: AHI ≥ 15 events per hour
Severe OSA: AHI ≥ 30 events per hour
Definitions of terms quantifying OSA8
Apnoea–hypopnea index (AHI): no. of apneas and hypopneas per hour of total sleep time
Respiratory disturbance index (RDI): AHI with the addition of respiratory effort–related arousals per hour of sleep during polysomnography
Respiratory event index (REI): no. of apneas and hypopneas per hour of total recording time on home monitoring devices for sleep apnea
Some retrospective cohort studies have shown other diseases that are associated with OSA. Patients with concomitant OSA and chronic obstructive pulmonary disease have an increased risk of a severe exacerbation, leading to admission to hospital and increased mortality.37,38 Patients with OSA have two- to three times the risk of postoperative cardiopulmonary complications compared with patients without OSA.39,40 Maternal and fetal complications are increased in the presence of OSA (e.g., preeclampsia, gestational hypertension, preterm delivery, low birth weight).41,42 Obstructive sleep apnea is also associated with a two times increased risk of a motor vehicle crash,43 a complication with a high financial and health cost.4 Furthermore, untreated OSA is associated with reduced work productivity and an increased risk of occupational injury.44,45 Treatment of OSA may mitigate many of these risks and is cost-effective.4,46,47
How should obstructive sleep apnea be diagnosed?
By consensus, the International Classification of Sleep Disorders defines OSA as the presence of symptoms or certain comorbidities associated with five or more predominantly obstructive respiratory events per hour or by 15 or more predominantly obstructive respiratory events per hour in asymptomatic patients (Box 2).29 The number of obstructive respiratory events is quantified by the AHI, respiratory disturbance index or respiratory event index as outlined in Box 2.
According to recent US Preventive Services Task Force guidance on screening for OSA, there is no clear evidence to support population screening of asymptomatic individuals at low risk of OSA using sleep diagnostic testing.48
Polysomnography
The gold standard for diagnosis of OSA is attended polysomnography (level I study), which involves collection of seven or more data channels, including electroencephalogram and electrooculogram for sleep staging, electromyogram, electrocardiogram and respiratory channels.49 Home-based polysomnography (level II study) is not used commonly except for research. Sleep specialist assessment and polysomnography is particularly important when patients are at risk of central sleep apnea or hypoventilation; these conditions are suggested by the presence of neurologic disease, neuromuscular disease, congestive heart failure, severe lung disease, opioid use or obesity with a serum bicarbonate level of more than 27 mmol/L.50
Polysomnography is also indicated for the evaluation of suspected sleep disorders other than OSA or after nondiagnostic home sleep apnea testing among patients with a high pretest probability of OSA.20
Home sleep apnea testing
Several types of home sleep apnea testing are in clinical use. Level III sleep studies record a minimum of three channels of data while the patient sleeps at home. Level III studies usually monitor airflow, snoring, respiratory excursion, body position, heart rate and oxygen saturation, but some validated devices use surrogate measurements for these variables, such as tonometry or actigraphy, and the technology is constantly evolving.51 Level III studies do not record sleep; therefore, severity of OSA is estimated using the respiratory event index, which is the number of desaturation events per hour of total recording time.
The respiratory event index underestimates AHI because it measures time when the patient is not actually asleep52 and does not detect arousals from sleep.20 In symptomatic patients with a moderate-to-high pretest probability of OSA and no substantial cardiopulmonary comorbidity, level III studies are adequate for the diagnosis of OSA (Table 1).53,54 As many as 17% of home sleep apnea tests are false negatives55 and up to 18% have technical failures.56 Therefore, if results for home sleep apnea testing are negative in a patient for whom there is a high index of suspicion, physicians should seek testing using polysomnography. Level III studies may also be useful when immobility, safety or illness preclude attendance for polysomnography and for confirmation of treatment efficacy.20
Level IV studies record one to two channels of data. One channel is oximetry, whereas the second channel may record snoring, airflow or heart rate. A recent randomized controlled trial (RCT) showed that clinicians diagnosed OSA with lower confidence when oximetry was used compared with level III testing or polysomnography.57
What are the benefits of different treatment options?
Table 2 summarizes the effectiveness of three different treatments for patients with OSA: continuous positive airway pressure, oral appliance and maxillomandibular advancement.
Continuous positive airway pressure
Symptomatic patients with OSA should undergo a trial of treatment with continuous positive airway pressure.4,9 Continuous positive airway pressure reduces AHI and sleepiness.4 Although previous meta-analyses have not been definitive, the findings of some recent well-designed RCTs support that the use of continuous positive airway pressure improves quality of life.4–6 There is ongoing research to establish the benefits of OSA treatment on associated morbidity. Randomized controlled trials have shown reductions in blood pressure (−4.39 to −1.41 mm Hg).4
Other health benefits of treatment using continuous positive airway pressure for OSA are less clear. For example, there is conflicting evidence on the effects of continuous positive airway pressure on glycemic control in patients with diabetes.4,58 It is currently unclear if treatment can prevent some of the fetal and maternal complications (e.g., preeclampsia) associated with OSA.59–61 A systematic review and meta-analysis showed that therapy using continuous positive airway pressure reduced the risk of motor vehicle crashes in patients with moderate to severe OSA.62
Although observational studies have suggested a decreased risk of cardiovascular events in patients with severe OSA who are adherent to treatment,63 two recent RCTs (Sleep Apnea Cardiovascular Endpoints [SAVE] and Randomized Intervention with CPAP in Coronary Artery Disease and Sleep Apnea [RICCADSA]) reported that there was no cardiovascular benefit of treatment using continuous positive airway pressure in patients with OSA who had preexisting cardiovascular disease and minimal sleepiness.6,64 An important limitation of both studies was that adherence to the use of continuous positive airway pressure was below accepted guidelines for adequate use (mean adherence of less than 4 hours per night).65 Analysis of the outcomes in patients who were adherent to continuous positive airway pressure identified a lower risk of the composite outcome of repeat coronary artery revascularization, myocardial infarction, stroke or cardiovascular mortality in the RICCADSA study and a lower risk of cerebral events or stroke in the SAVE study. The SAVE study excluded patients with substantial nocturnal hypoxemia (oxygen saturation of less than 80% for more than 10% of recording time) in whom continuous positive airway pressure therapy may have more potential for reducing cardiovascular events. Furthermore, patients were followed only for an average of 3.7 years, which may not have been long enough to see cardiovascular benefits of therapy. These studies have generated controversy regarding the benefit of treatment for cardiovascular disease prevention. In our view, patients with moderate to severe OSA (regardless of symptoms) should be offered therapy in light of health, quality of life and workplace productivity benefits shown in adherent patients consistent with the findings in RCTs.6,66 However, we do not suggest using continuous positive airway pressure primarily for secondary prevention of cardiovascular events in asymptomatic patients.
Oral appliances
Oral appliances are recommended9,67 for patients with mild to moderate OSA who are intolerant of continuous positive airway pressure or prefer not to use it. These are either mandibular advancement or tongue-retaining devices. Oral appliances improve sleepiness, although a systematic review also identified that oral appliances decrease AHI to a lesser extent than continuous positive airway pressure.4 Further research is needed to determine if use of oral appliances improves quality of life.4 Lower efficacy may be balanced by greater adherence to this form of treatment compared with continuous positive airway pressure (80%–90% v. 50%–70%); thus, in mild to moderate disease, overall treatment effectiveness may be similar to continuous positive airway pressure.4,6,67–69 Like continuous positive airway pressure, oral appliances can improve blood pressure modestly.4 However, other cardiovascular benefits of therapy using oral appliances have not been established.70
The 2015 update of the American Academy of Sleep Medicine and American Academy of Dental Sleep Medicine clinical practice guideline recommended that, for best effect, appliances should be custom fitted by a dentist with extensive experience or additional training in dental sleep medicine.67 After the oral appliance has been custom fitted and jaw protrusion has been optimized, a sleep test should be ordered to evaluate treatment efficacy.71
Alternative treatments
Alternative treatment options include nasal expiratory positive airway pressure valves, exercises to strengthen oropharyngeal muscles (myofunctional therapy) and hypoglossal nerve stimulation (not approved in Canada).72 Tonsillectomy and adenoidectomy may help when tonsillar enlargement encroaches on the upper airway, particularly in younger patients.73 Tracheostomy is highly effective,74 yet rarely necessary unless there is substantial comorbidity and other treatments are ineffective.75
Patients frequently ask about surgery for treatment of OSA. Maxillomandibular advancement, with or without genial tubercle advancement, is an invasive surgical procedure that may be an option for highly selected patients who are intolerant of other therapies.76 However, a retrospective case–control study found that 13.9% of patients had a major complication that required repeat admission or unplanned surgery after maxillomandibular advancement, and numerous minor complications can occur.77 Regular follow-up to assess for recurrence of OSA is recommended.75 Laser-assisted uvuloplasty or uvulopalatopharyngoplasty are unreliable for reducing the AHI or improving patient outcomes, and are not recommended.75,78 Decision aids for patients are under development and may help match treatments to patient preferences.79
What are the principles of ongoing management and follow-up?
The Canadian Thoracic Society guideline for the diagnosis and treatment of sleep disordered breathing in adults recommended that patients with sleep disordered breathing should be counselled to avoid excessive alcohol and sedative use.9 A meta-analysis of the effects of exercise training on sleep apnea80 and a longitudinal prospective cohort study81 reported, respectively, that exercise of moderate intensity and weight loss of 10% of baseline weight in patients who are overweight or obese resulted in modest reductions in AHI. For patients with supine-predominant OSA, a systematic review and meta-analysis found that positional therapy may reduce AHI by up to 10 events per hour but may be limited by poor adherence; in addition, there was no clear evidence of improvements in sleepiness, total sleep time or functional outcomes of sleep.82 When appropriate, patients who are obese may be referred for bariatric surgery; after sustained weight loss, repeat testing may be indicated to determine if OSA persists.83
A consensus position paper on driving safety recommends that all patients with OSA should be counselled about driving safety.84 The criteria for when to notify provincial and territorial ministries of transportation about a patient with OSA varies and is typically based on the physician’s assessment of risk. The American Thoracic Society clinical practice guideline for noncommercial drivers classifies patients as being at high risk if there is a history of unintentional or inappropriate sleep during daily activities, with either a recent motor vehicle crash or near miss owing to sleepiness, fatigue or inattention.85 The Canadian Council of Motor Transport Administrators publishes medical standards for commercial drivers with OSA;86 these standards specify that individuals without excessive sleepiness and an AHI of less than 20 events per hour are eligible to hold a commercial licence without receiving treatment for OSA, whereas those who have had a motor vehicle crash associated with falling asleep or have reported excessive sleepiness while driving must be treated. The physician’s recommendations regarding treatment of those with an AHI of more than 20 events per hour are considered when determining licensure eligibility. The Canadian Medical Association’s driver’s guide provides criteria for mandatory reporting of patients in safety-critical occupations, such as commercial drivers, or those with key navigation roles in aviation, the railway or at sea.87
Supporting adherence to treatment
Initiation and maintenance of therapy using continuous positive airway pressure requires technical support. Important concerns are discussed in Appendix 2, available at www.cmaj.ca/lookup/suppl/doi:10.1503/cmaj.170296/-/DC1. Adherence to this therapy within the first few days is a strong predictor of long-term adherence.88
Adherence to treatment with oral appliances can be assessed by patient report. Although some devices have built-in technology to objectively measure adherence,89,90 this type of device is not encountered frequently outside of clinical trials. Compliance in the use of oral appliances is increased if there is a reduction in snoring.90 Important adverse effects of oral appliances include aggravation of temporomandibular joint dysfunction, teeth shift, pain, gingival problems, excessive salivation or dry mouth.67,71 Regular dental follow-up is important for all patients who are prescribed oral appliances.
Addressing persistent symptoms after successful treatment for obstructive sleep apnea
Residual daytime sleepiness despite effective treatment of OSA may occur. Causes include chronic sleep restriction, central sleep apnea that comes to light with therapy using continuous positive airway pressure, another sleep disorder (e.g., narcolepsy), chronic medical or psychiatric conditions (e.g., depression) or adverse effects owing to medications (e.g., sedatives, antihistamines, β-blockers). About 5% of patients have persistent sleepiness despite exclusion of these causes and may benefit from drugs to promote wakefulness.91
Future perspectives and unanswered questions
There is emerging interest in personalized approaches to the diagnosis and management of OSA. Individualized treatment approaches acknowledge the complex biological mechanisms underlying OSA and aim to tailor treatments to the patient’s physiology. Pathophysiologic mechanisms of OSA under investigation include an anatomic predisposition to upper airway collapse; increased ventilatory control instability (loop gain); reduced arousal threshold; ineffective upper airway dilator muscles or hypoglossal nerve function; decreased lung tethering; and nocturnal rostral fluid shift. Furthermore, research is underway to identify biomarkers and genetic factors that might predict adverse outcomes associated with OSA.92,93
In parallel with the development of targeted therapies for OSA, it is important that attention be paid to the wide variations in the diagnosis and treatment of OSA within Canada.94 Research into the models of service delivery for OSA, including strategies to improve timely access to care, funding for OSA treatment and patient preference, will be important to improve the care of Canadians with sleep disordered breathing.
Footnotes
CMAJ Podcasts: author interview at https://soundcloud.com/cmajpodcasts/170296-view
Competing interests: Najib Ayas has received support from Bresotec outside of the submitted work. Sachin Pendharkar receives renumeration from VitalAire Canada for the interpretation of home sleep apnea tests and honoraria from RHS Canada for the provision of continuing education on obstructive sleep apnea. No other competing interests were declared.
Contributors: All of the authors contributed subtantially to the conception and design of the work, revised it critically for important intellectual content, gave final approval of the version to be published and agreed to be accountable for all aspects of the work.
Funding: The authors received no external funding for this review.
This article has been peer reviewed.
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