2201 Disorders of Ventilation CHAPTER 296
TABLE 295-1 The Three Compartments of the Mediastinum
ANTERIOR COMPARTMENT MIDDLE COMPARTMENT POSTERIOR COMPARTMENT
Anatomical boundaries Manubrium and sternum anteriorly,
pericardium, aorta, and brachiocephalic
vessels posteriorly
Anterior mediastinum anteriorly, posterior mediastinum
posteriorly
Pericardium and trachea anteriorly;
vertebral column posteriorly
Contents Thymus gland, anterior mediastinal
lymph nodes, internal mammary
arteries, and veins
Pericardium, heart, ascending and transverse
arch of aorta, superior and inferior vena cavae,
brachiocephalic arteries and veins, phrenic nerves,
trachea, and main bronchi and their contiguous lymph
nodes, pulmonary arteries, and veins
Descending thoracic aorta, esophagus,
thoracic duct, azygos and hemiazygos
veins, sympathetic chains, and the
posterior group of mediastinal lymph
nodes
Common abnormalities Thymoma, lymphomas, teratomatous
neoplasms, thyroid masses, parathyroid
masses, mesenchymal tumors, giant
lymph node hyperplasia, hernia through
foramen of Morgagni
Metastatic lymph node enlargement, granulomatous
lymph node enlargement, pleuropericardial cysts,
bronchogenic cysts, masses of vascular origin
Neurogenic tumors, meningocele,
meningomyelocele, gastroenteric cysts,
esophageal diverticula, hernia through
foramen of Bochdalek, extramedullary
hematopoiesis
esophageal rupture are acutely ill with chest pain and dyspnea due to
the mediastinal infection. The esophageal rupture can occur spontaneously or as a complication of esophagoscopy or the insertion of a
Blakemore tube. Appropriate treatment consists of exploration of the
mediastinum with primary repair of the esophageal tear and drainage
of the pleural space and the mediastinum.
The incidence of mediastinitis after median sternotomy is 0.4–5.0%.
Patients most commonly present with wound drainage. Other presentations include sepsis and a widened mediastinum. The diagnosis
usually is established with mediastinal needle aspiration. Treatment
includes immediate drainage, debridement, and parenteral antibiotic
therapy, but the mortality rate still exceeds 20%.
■ CHRONIC MEDIASTINITIS
The spectrum of chronic mediastinitis ranges from granulomatous
inflammation of the lymph nodes in the mediastinum to fibrosing
mediastinitis. Most cases are due to histoplasmosis or tuberculosis, but
sarcoidosis, silicosis, and other fungal diseases are at times causative.
Patients with granulomatous mediastinitis are usually asymptomatic.
Those with fibrosing mediastinitis usually have signs of compression of
a mediastinal structure such as the superior vena cava or large airways,
phrenic or recurrent laryngeal nerve paralysis, or obstruction of the
pulmonary artery or proximal pulmonary veins. If veins or arteries are
involved, the placement of stents has relieved the symptoms in many
patients.
■ PNEUMOMEDIASTINUM
In this condition, there is gas in the interstices of the mediastinum.
The three main causes are (1) alveolar rupture with dissection of air
into the mediastinum; (2) perforation or rupture of the esophagus,
trachea, or main bronchi; and (3) dissection of air from the neck or
the abdomen into the mediastinum. Typically, there is severe substernal chest pain with or without radiation into the neck and arms. The
physical examination usually reveals subcutaneous emphysema in the
suprasternal notch and Hamman’s sign, which is a crunching or clicking noise synchronous with the heartbeat and is best heard in the left
lateral decubitus position. The diagnosis is confirmed with the chest
radiograph. Usually no treatment is required, but the mediastinal air
will be absorbed faster if the patient inspires high concentrations of
oxygen. If mediastinal structures are compressed, the compression can
be relieved with needle aspiration.
■ FURTHER READING
Carter BW et al: ITMIG classification of mediastinal compartments
and multidisciplinary approach to mediastinal masses. Radiographics
37:413, 2017.
Ponamgi SP et al: Catheter-based intervention for pulmonary vein
stenosis due to fibrosing mediastinitis: The Mayo Clinic experience.
Int J Cardiol Heart Vasc 8:103, 2015.
DEFINITION AND PHYSIOLOGY
In health, the arterial level of carbon dioxide (Paco2
) is maintained
between 37 and 43 mmHg at sea level. All disorders of ventilation result
in abnormal measurements of Paco2
. This chapter reviews chronic
ventilatory disorders.
The continuous production of carbon dioxide (CO2
) by cellular
metabolism necessitates its efficient elimination by the respiratory system. The relationship between CO2
production and Paco2
is described
by the equation: Paco2
= (k) (V.
co2
)/V.
A, where V.
co2
represents the
carbon dioxide production, k is a constant, and V.
A is fresh gas alveolar
ventilation (Chap. 285). V.
A can be calculated as minute ventilation ×
(1 – Vd/Vt), where the dead space fraction Vd/Vt represents the portion of a tidal breath that remains within the conducting airways at
the conclusion of inspiration and so does not contribute to alveolar
ventilation. As such, all disturbances of Paco2
must reflect altered CO2
production, minute ventilation, or dead space fraction.
Diseases that alter (V.
co2
) are often acute (e.g., sepsis, burns, or
pyrexia), and their contribution to ventilatory abnormalities and/or
respiratory failure is reviewed elsewhere. Chronic ventilatory disorders
typically involve inappropriate levels of minute ventilation or increased
dead space fraction. Characterization of these disorders requires a
review of the normal respiratory cycle.
The spontaneous cycle of inspiration and expiration is automatically
generated in the brainstem. Two groups of neurons located within
the medulla are particularly important: the dorsal respiratory group
(DRG) and the ventral respiratory column (VRC). These neurons have
widespread projections including the descending projections into the
contralateral spinal cord where they perform many functions. They
initiate activity in the phrenic nerve/diaphragm, project to the upper
airway muscle groups and spinal respiratory neurons, and innervate
the intercostal and abdominal muscles that participate in normal
respiration. The DRG acts as the initial integration site for many of
the afferent nerves relaying information about Pao2
, Paco2
, pH, and
blood pressure from the carotid and aortic chemoreceptors and baroreceptors to the central nervous system (CNS). In addition, the vagus
nerve relays information from stretch receptors and juxtapulmonarycapillary receptors in the lung parenchyma and chest wall to the DRG.
The respiratory rhythm is generated within the VRC as well as the
more rostrally located parafacial respiratory group (pFRG), which is
particularly important for the generation of active expiration. One particularly important area within the VRC is the so-called pre-Bötzinger
complex. This area is responsible for the generation of various forms
296 Disorders of Ventilation
John F. McConville, Julian Solway,
Babak Mokhlesi
2202 PART 7 Disorders of the Respiratory System
FIGURE 296-1 Examples of balance between respiratory system strength and load.
A. Excess respiratory muscle strength in health. B. Load greater than strength.
C. Increased drive with acceptable strength.
Excess respiratory muscle strength in health
Strength
Chest wall
elastic
loads
Adequate neural
transmission to motor
units
Respiratory
muscle strength Load Lung resistive
loads
Lung elastic
loads
Respiratory
A drive
Load > Strength
Load Strength
Impaired neuromuscular
transmission
Amyotrophic lateral sclerosis
Myasthenia gravis
Phrenic nerve injury
Spinal cord lesion
Muscle
weakness
Myopathy
Malnutrition
Fatigue
Sleep-disordered
breathing
Upper airway
obstruction
Intermittent hypoxemia
Chest wall disease
Kyphoscoliosis
Obesity
Abdominal distention (ascites)
Diminished drive
Sleep-disordered breathing
Narcotic/sedative use
Brainstem stroke
Hypothyroidism
1º Alveolar hypoventilation
Lung disease
Interstitial lung disease
Airflow obstruction
Atelectasis
Pulmonary embolus
B
Increased drive with acceptable strength
Load Strength
Increased drive
Numerous initiating and
sustaining factors (see text)
No chest wall
disease
Normal neural
transmission
No lung disease Normal respiratory
C muscle strength
the strength of the respiratory muscles readily accomplishes this, and
normal respiration continues indefinitely. Reduction in respiratory
drive or neuromuscular competence or substantial increase in respiratory load can diminish minute ventilation, resulting in hypercapnia
(Fig. 296-1B). Alternatively, if normal respiratory muscle strength is
coupled with excessive respiratory drive, then alveolar hyperventilation
ensues and leads to hypocapnia (Fig. 296-1C).
HYPOVENTILATION
■ CLINICAL FEATURES
Diseases that reduce minute ventilation or increase dead space fall
into four major categories: parenchymal lung and chest wall disease,
sleep-disordered breathing, neuromuscular disease, and respiratory
drive disorders (Fig. 296-1B). The clinical manifestations of hypoventilation syndromes are nonspecific (Table 296-1) and vary depending on
the severity of hypoventilation, the rate at which hypercapnia develops,
the degree of compensation for respiratory acidosis, and the underlying
disorder. Patients with parenchymal lung or chest wall disease typically
present with shortness of breath and diminished exercise tolerance.
Episodes of increased dyspnea and sputum production are hallmarks
of obstructive lung diseases such as chronic obstructive pulmonary disease (COPD), whereas progressive dyspnea and cough are common in
interstitial lung diseases. Excessive daytime somnolence, poor-quality
sleep, and snoring are common among patients with sleep-disordered
breathing. Sleep disturbance and orthopnea are also described in
neuromuscular disorders. As neuromuscular weakness progresses, the
respiratory muscles, including the diaphragm, are placed at a mechanical disadvantage in the supine position due to the upward movement
of the abdominal contents. New-onset orthopnea is frequently a sign
of reduced respiratory muscle force generation. More commonly, however, extremity weakness or bulbar symptoms develop prior to sleep
disturbance in neuromuscular diseases such as amyotrophic lateral
sclerosis (ALS) or muscular dystrophy. Patients with respiratory drive
disorders do not have symptoms distinguishable from other causes of
chronic hypoventilation.
The clinical course of patients with chronic hypoventilation from
neuromuscular or chest wall disease follows a characteristic sequence:
an asymptomatic stage where daytime Pao2
and Paco2
are normal
followed by nocturnal hypoventilation, initially during rapid eye movement (REM) sleep and later in non-REM sleep. Finally, if vital capacity
drops further, daytime hypercapnia develops. Symptoms can develop at
any point along this time course and often depend on the pace of respiratory muscle functional decline. Regardless of cause, the hallmark of
all alveolar hypoventilation syndromes is an increase in alveolar Pco2
(PAco2
) and therefore in Paco2
. The resulting respiratory acidosis
eventually leads to a compensatory increase in plasma bicarbonate concentration. The increase in Paco2
results in an obligatory decrease in
PAo2
, often resulting in hypoxemia. If severe, the hypoxemia manifests
clinically as cyanosis and can stimulate erythropoiesis and thus induce
secondary erythrocytosis. The combination of chronic hypoxemia and
hypercapnia may also induce pulmonary vasoconstriction, leading
eventually to pulmonary hypertension, right ventricular hypertrophy,
and right heart failure.
■ DIAGNOSIS
Elevated serum bicarbonate (i.e., total serum CO2
, which equals calculated bicarbonate plus dissolved CO2
) in the absence of volume depletion is suggestive of hypoventilation. However, it is important to point
TABLE 296-1 Signs and Symptoms of Hypoventilation
Dyspnea during activities of daily living
Orthopnea in diseases affecting diaphragm function
Poor-quality sleep
Daytime hypersomnolence
Early morning headaches
Anxiety
Impaired cough in neuromuscular diseases
of inspiratory activity, and lesioning of the pre-Bötzinger complex
leads to the complete cessation of breathing. The neural output of
these medullary respiratory networks can be voluntarily suppressed
or augmented by input from higher brain centers and the autonomic
nervous system. During normal sleep, there is an attenuated response
to hypercapnia and hypoxemia, resulting in mild nocturnal hypoventilation that corrects upon awakening.
Once neural input has been delivered to the respiratory pump
muscles, normal gas exchange requires an adequate amount of respiratory muscle strength to overcome the elastic and resistive loads of
the respiratory system (Fig. 296-1A) (also see Chap. 285). In health,
2203 Disorders of Ventilation CHAPTER 296
out that a serum bicarbonate level <27 mmol/L in the setting of normal
renal function makes the diagnosis of hypoventilation very unlikely.
By contrast, a serum bicarbonate level ≥27 mmol/L should trigger clinicians to measure Paco2
as a confirmatory diagnostic test. Therefore,
serum bicarbonate can be used as a sensitive test to rule out hypercapnia, not to rule it in. An arterial blood gas demonstrating elevated
Paco2
with a normal pH confirms chronic alveolar hypoventilation.
The subsequent evaluation to identify an etiology should initially focus
on whether the patient has lung disease or chest wall abnormalities.
Physical examination, imaging studies (chest x-ray and/or CT scan),
and pulmonary function tests are sufficient to identify most lung/
chest wall disorders leading to hypercapnia. If these evaluations are
unrevealing, the clinician should screen for obesity hypoventilation
syndrome (OHS), the most frequent sleep disorder leading to chronic
hypoventilation, which is typically accompanied by obstructive sleep
apnea (OSA). Several screening tools have been developed to identify
patients at risk for OSA. The Berlin Questionnaire has been validated
in a primary care setting and identifies patients likely to have OSA.
The Epworth Sleepiness Scale (ESS) measures daytime sleepiness, with
a score of ≥10 identifying individuals who warrant additional investigation; however, it is not a useful test to screen for sleep-disordered
breathing. Owing to its ease of use, the STOP-Bang questionnaire has
become a popular tool to screen for OSA and has been validated in
various outpatient settings. The STOP-Bang survey has been used in
preoperative anesthesia clinics to identify patients at risk of having
OSA. In this population, it has 93% sensitivity and 90% negative predictive value. Additionally, the STOP-Bang questionnaire has been
validated as a screening tool for OSA in sleep and surgical clinics. The
probability of moderate and severe OSA steadily increases with higher
STOP-Bang scores.
If the ventilatory apparatus (lung, airways, chest wall) is not responsible for chronic hypercapnia, then the focus should shift to respiratory
drive and neuromuscular disorders. There is an attenuated increase
in minute ventilation in response to elevated CO2
and/or low O2
in
respiratory drive disorders. These diseases are difficult to diagnose
and should be suspected when patients with hypercapnia are found
to have normal respiratory muscle strength, normal pulmonary function, and normal alveolar-arterial Po2
difference. Hypoventilation is
more marked during sleep in patients with respiratory drive defects,
and polysomnography often reveals central apneas, hypopneas, or
hypoventilation. Brain imaging (CT scan or MRI) can sometimes
identify structural abnormalities in the pons or medulla that result in
hypoventilation. Chronic narcotic use or significant hypothyroidism
can depress the central respiratory drive and lead to chronic hypercapnia as well.
Respiratory muscle weakness has to be profound before lung volumes are compromised and hypercapnia develops. Typically, physical
examination reveals decreased strength in major muscle groups prior
to the development of hypercapnia. Measurement of maximum inspiratory and expiratory pressures or forced vital capacity (FVC) can be
used to monitor for respiratory muscle involvement in diseases with
progressive muscle weakness. These patients also have increased risk
for sleep-disordered breathing, including hypopneas, central and
obstructive apneas, and hypoxemia. Nighttime oximetry and capnometry during polysomnography are helpful in better characterizing sleep
disturbances in this patient population.
TREATMENT
Hypoventilation
Nocturnal noninvasive positive-pressure ventilation (NIPPV) has
been used successfully in the treatment of hypoventilation and
apneas, both central and obstructive, in patients with neuromuscular and chest wall disorders. Nocturnal NIPPV has been shown
to improve daytime hypercapnia, prolong survival, and improve
health-related quality of life when daytime hypercapnia is documented. ALS guidelines recommend consideration of nocturnal NIPPV if symptoms of hypoventilation exist and one of the
following criteria is present: Paco2
≥45 mmHg; nocturnal oximetry demonstrates oxygen saturation ≤88% for 5 consecutive min;
maximal inspiratory pressure <60 cmH2
O; or sniff nasal pressure
<40 cmH2
O and FVC <50% predicted. However, at present, there is
inconclusive evidence to support preemptive nocturnal NIPPV use
in all patients with neuromuscular and chest wall disorders who
demonstrate nocturnal but not daytime hypercapnia. Nevertheless,
at some point, the institution of full-time ventilatory support with
either pressure or volume-preset modes is required in progressive
neuromuscular disorders. There is less evidence to direct the timing
of this decision, but ventilatory failure requiring mechanical ventilation and chest infections related to ineffective cough are frequent
triggers for the institution of full-time ventilatory support.
Treatment of chronic hypoventilation from lung or neuromuscular diseases should be directed at the underlying disorder.
Pharmacologic agents that stimulate respiration, such as medroxyprogesterone and acetazolamide, have been poorly studied in
chronic hypoventilation and should not replace treatment of the
underlying disease process. Regardless of the cause, excessive metabolic alkalosis should be corrected, as serum bicarbonate levels
elevated out of proportion for the degree of chronic respiratory
acidosis can result in additional hypoventilation. When indicated,
administration of supplemental oxygen is effective in attenuating
hypoxemia, polycythemia, and pulmonary hypertension. However,
in some patients, supplemental oxygen, even at low concentrations,
can worsen hypercapnia.
Phrenic nerve or diaphragm pacing is a potential therapy for
patients with hypoventilation from high cervical spinal cord lesions
or respiratory drive disorders. Prior to surgical implantation,
patients should have nerve conduction studies to ensure normal
bilateral phrenic nerve function. Small case series suggest that
effective diaphragmatic pacing can improve quality of life in these
patients.
HYPOVENTILATION SYNDROMES
■ OBESITY HYPOVENTILATION SYNDROME
The diagnosis of OHS requires the following: body mass index (BMI)
≥30 kg/m2
; chronic daytime alveolar hypoventilation, defined as Paco2
≥45 mmHg at sea level in the absence of other known causes of hypercapnia; and evidence of sleep-disordered breathing. In almost 90% of
cases, the sleep-disordered breathing is in the form of OSA, with close
to 70% exhibiting severe OSA. Several international studies in different
populations confirm that the overall prevalence of OSA syndrome,
defined by an apnea-hypopnea index ≥5 and daytime sleepiness, is
~14% in men and 5% in women aged 30–70 years in the United States.
Thus, the population at risk for the development of OHS continues to
rise as the worldwide obesity epidemic persists. Although no population-based prevalence studies of OHS have been performed, some
estimates suggest it may be as high as 0.4% of the U.S. adult population
(or 1 in 263 adults).
Some, but not all, studies suggest that severe obesity (BMI >40 kg/
m2
) and severe OSA (AHI >30 events per h) are risk factors for the
development of OHS. The pathogenesis of hypoventilation in these
patients is the result of multiple physiologic variables and conditions
including OSA, increased work of breathing, respiratory muscle
impairment relative to the increased load because of excess adiposity,
ventilation-perfusion mismatching, and depressed central ventilatory
responsiveness to hypoxemia and hypercapnia. These defects in central
respiratory drive often improve with treatment of sleep-disordered
breathing with CPAP or NIPPV without any significant change in body
weight, which suggests that decreased ventilatory responsiveness is a
consequence rather than a primary cause of OHS. The treatment of
OHS is similar to that for OSA: weight reduction and positive airway
pressure therapy during sleep with either continuous positive airway
pressure (CPAP) or NIPPV. There is evidence that substantial weight
loss (i.e., 20–25% of actual body weight) alone normalizes Paco2
in patients with OHS. Unfortunately, achieving and sustaining this
2204 PART 7 Disorders of the Respiratory System
degree of weight loss without bariatric surgery are very challenging for
most patients. Treatment with CPAP or NIPPV should not be delayed
while the patient attempts to lose weight. CPAP improves daytime
hypercapnia and hypoxemia in more than half of patients with OHS
and concomitant severe OSA. Bilevel positive airway pressure without
a backup rate (bilevel PAP spontaneous mode) should be reserved
for patients not able to tolerate high levels of CPAP support or when
obstructive respiratory events persist despite reaching the maximum
CPAP pressure of 20 cmH2
O. NIPPV in the form of bilevel PAP with a
backup rate (bilevel PAP ST or spontaneous timed) or volume-assured
pressure support modes should be strongly considered if hypercapnia
persists after several weeks of CPAP therapy with objectively proven
adherence. Patients with OHS and no evidence of significant OSA are
typically started on bilevel PAP ST or volume-assured pressure support
modes, as are patients presenting with acute decompensated OHS.
Finally, comorbid conditions that impair ventilation, such as COPD,
should be aggressively treated in conjunction with coexisting OHS.
■ CENTRAL HYPOVENTILATION SYNDROME
This syndrome can present later in life or in the neonatal period, when
it is often called Ondine’s curse or congenital central hypoventilation
syndrome (CCHS). Abnormalities in the gene encoding PHOX2b, a
transcription factor with a role in neuronal development, have been
implicated in the pathogenesis of CCHS. Regardless of the age of onset,
these patients have absent respiratory response to hypoxia or hypercapnia, mildly elevated Paco2
while awake, and markedly elevated
Paco2
during non-REM sleep. Interestingly, these patients are able to
augment their ventilation and “normalize” Paco2
during exercise and
during REM sleep. These patients typically require NIPPV or mechanical ventilation as therapy and should be considered for phrenic nerve
or diaphragmatic pacing at centers with experience performing these
procedures.
HYPERVENTILATION
■ CLINICAL FEATURES
Hyperventilation is defined as ventilation in excess of metabolic
requirements (CO2
production) leading to a reduction in Paco2
.
The physiology of patients with chronic hyperventilation is poorly
understood, and there is no typical clinical presentation. Symptoms
can include dyspnea, paresthesias, tetany, headache, dizziness, visual
disturbances, and atypical chest pain. Because symptoms can be so
diverse, patients with chronic hyperventilation present to a variety of
health care providers, including internists, neurologists, psychologists,
psychiatrists, and pulmonologists.
It is helpful to think of hyperventilation as having initiating and sustaining factors. Some investigators believe that an initial event leads to
increased alveolar ventilation and a drop in Paco2
to ~20 mmHg. The
ensuing onset of chest pain, breathlessness, paresthesia, or altered consciousness can be alarming. The resultant increase in minute volume
to relieve these acute symptoms only serves to exacerbate symptoms
that are often misattributed by the patient and health care workers to
cardiopulmonary disorders. An unrevealing evaluation for causes of
these symptoms often results in patients being anxious and fearful of
additional attacks. It is important to note that anxiety disorders and
panic attacks are not synonymous with hyperventilation. Anxiety
disorders can be both an initiating and sustaining factor in the pathogenesis of chronic hyperventilation, but these are not necessary for the
development of chronic hypocapnia.
■ DIAGNOSIS
Respiratory symptoms associated with acute hyperventilation can be
the initial manifestation of systemic illnesses such as diabetic ketoacidosis. Causes of acute hyperventilation need to be excluded before a
diagnosis of chronic hyperventilation is considered. Arterial blood gas
sampling that demonstrates a compensated respiratory alkalosis with a
near normal pH, low Paco2
, and low calculated bicarbonate is necessary to confirm chronic hyperventilation. Other causes of respiratory
alkalosis, such as mild asthma, need to be diagnosed and treated before
chronic hyperventilation can be considered. A high index of suspicion
is required as increased minute ventilation can be difficult to detect on
physical examination. Once chronic hyperventilation is established, a
sustained 10% increase in alveolar ventilation is enough to perpetuate
hypocapnia. This increase can be accomplished with subtle changes in
the respiratory pattern, such as occasional sigh breaths or yawning 2–3
times per min.
TREATMENT
Hyperventilation
There are few well-controlled treatment studies of chronic hyperventilation owing to its diverse features and the lack of a universally
accepted diagnostic process. Clinicians often spend considerable
time identifying initiating factors, excluding alternative diagnoses, and discussing the patient’s concerns and fears. In some
patients, reassurance and frank discussion about hyperventilation
can be liberating. Identifying and eliminating habits that perpetuate
hypocapnia, such as frequent yawning or sigh breathing, can be
helpful. Some evidence suggests that breathing exercises and diaphragmatic retraining may be beneficial for some patients. The evidence for using medications to treat hyperventilation is scant. Beta
blockers may be helpful in patients with sympathetically mediated
symptoms such as palpitations and tremors.
■ FURTHER READING
Anderson PM et al: EFNS guidelines on the clinical management of
amyotrophic lateral sclerosis (MALS)–revised report of the EFNS
task force. Eur J Neurol 19:360, 2012.
Benditt JO: Pathophysiology of neuromuscular respiratory diseases.
Clin Chest Med 39:297, 2018.
Chung F et al: STOP-Bang questionnaire: A practical approach to
screen for obstructive sleep apnea. Chest 149:631, 2016.
Douglas IS: Acute-on-chronic respiratory failure, in Principles of
Critical Care, 4th ed. JB Hall, GS Schmidt, JP Kress (eds). New York,
McGraw-Hill, 2015, pp 482–495.
Gardner WN: The pathophysiology of hyperventilation disorders.
Chest 109:516, 1996.
Masa JF et al: Long-term clinical effectiveness of continuous positive
airway pressure therapy versus non-invasive ventilation therapy
in patients with obesity hypoventilation syndrome: A multicentre,
open-label, randomised controlled trial. Lancet 393:1721, 2019.
Masa JF et al: Obesity hypoventilation syndrome. Eur Respir Rev
28:180097, 2019.
Obstructive sleep apnea (OSA) and central sleep apnea (CSA) are both
classified as sleep-related breathing disorders. OSA and CSA share
some risk factors and physiologic bases but also have unique features.
Each disorder is associated with impaired ventilation during sleep and
disruption of sleep, and each diagnosis requires careful elicitation of
the patient’s history, physical examination, and physiologic testing.
OSA, the more common disorder, causes daytime sleepiness and
impaired daily function. It is a cause of hypertension and is strongly
associated with cardiovascular disease in adults and behavioral problems in children. CSA is less common and may occur alone or in combination with OSA. It can occur as a primary condition, as a response
297 Sleep Apnea
Andrew Wellman, Daniel J. Gottlieb,
Susan Redline
2205 Sleep Apnea CHAPTER 297
Individuals with a small pharyngeal lumen require relatively high
levels of neuromuscular activation to maintain patency during wakefulness and thus are predisposed to airway collapse following the
normal sleep-related reduction in pharyngeal muscle activity during
sleep. The airway lumen may be narrowed by enlargement of soft tissue
structures (tongue, palate, and uvula) due to fat deposition, increased
lymphoid tissue, or genetic variation. Craniofacial factors such as mandibular retroposition or micrognathia, reflecting genetic variation or
developmental influences, also can reduce lumen dimensions. In addition, lung volumes influence the caudal traction on the pharynx and
consequently the stiffness of the pharyngeal wall. Accordingly, low lung
volume in the recumbent position, which is particularly pronounced in
the obese, contributes to collapse (less caudal traction). A high degree
of nasal resistance (e.g., due to nasal septal deviation or polyps) can
contribute to airway collapse by reducing intraluminal pressure downstream in the pharynx. High-level nasal resistance also may trigger
mouth opening during sleep, which breaks the seal between the tongue
and the palate and allows the tongue to fall posteriorly and occlude the
airway.
Pharyngeal muscle activation is integrally linked to ventilatory
drive. Thus, factors related to ventilatory control, particularly ventilatory sensitivity, arousal threshold, and neuromuscular responses to carbon dioxide (CO2
), contribute to the pathogenesis of OSA. A buildup
in CO2
during sleep activates both the diaphragm and the pharyngeal
muscles. Pharyngeal activation stiffens the upper airway and can
counteract inspiratory suction pressure and maintain airway patency
to an extent that depends on the anatomic predisposition to collapse.
However, pharyngeal collapse can occur when the ventilatory control
system is overly sensitive to CO2
, with resultant wide fluctuations in
ventilation, ventilatory drive, and upper airway stiffness. Moreover,
increasing levels of CO2
during sleep result in central nervous system
arousal, causing the individual to move from a deeper to a lighter level
of sleep or to awaken. A low arousal threshold (i.e., awakening to a
low level of CO2
or ventilatory drive) can preempt the CO2
-mediated
process of pharyngeal muscle compensation and prevent airway stabilization. A high arousal threshold, conversely, may prevent appropriate
termination of apneas, prolonging apnea duration and exacerbating
oxyhemoglobin desaturation. Finally, any impairment in the ability
of the muscles to compensate during sleep can contribute to collapse
of the pharynx. The relative contributions of risk factors vary among
individuals. Approaches to the measurement of these factors in clinical
settings, with consequent enhancement of “personalized” therapeutic
interventions, are being actively investigated.
Risk Factors and Prevalence The major risk factors for OSA
are obesity, male sex, and older age. Additional risk factors include
mandibular retrognathia and micrognathia, a positive family history of
OSA, sedentary lifestyle, genetic syndromes that reduce upper airway
patency (e.g., Down syndrome, Treacher-Collins syndrome), adenotonsillar hypertrophy (especially in children), menopause (in women), and
various endocrine syndromes (e.g., acromegaly, hypothyroidism).
Approximately 40–60% of cases of OSA are attributable to excess
weight. Obesity predisposes to OSA through the narrowing effects of
upper airway fat on the pharyngeal lumen. Obesity also reduces chest
wall compliance and decreases lung volumes, resulting in a loss of
caudal traction on upper airway structures. Obese individuals are at
a fourfold or greater risk for OSA than their normal-weight counterparts. A 10% weight gain is associated with a >30% increase in AHI.
Even modest weight loss or weight gain can influence the risk and
severity of OSA. However, the absence of obesity does not exclude this
diagnosis.
The prevalence of OSA is twofold higher among men than among
women. Factors that predispose men to OSA include android pattern
of obesity (resulting in upper-airway and abdominal fat deposition)
and relatively greater pharyngeal length, which increases collapsibility. Premenopausal women are relatively protected from OSA by the
influence of sex hormones on ventilatory drive. The decline in sex
difference in older age reflects an increased OSA prevalence in women
after menopause. The pathogenesis and presentation of OSA also differ
Palate
Tongue
Epiglottis
Lateral
pharyngeal
walls
FIGURE 297-1 The structures causing airway collapse in obstructive sleep apnea
include the palate, the tongue, and/or the epiglottis. In addition, collapse can also
occur due to the lateral pharyngeal walls.
to high altitude, or secondary to a medical condition (such as heart
failure) or medication (such as opioids). Patients with CSA often report
frequent awakenings and daytime fatigue and are at increased risk for
heart failure and atrial fibrillation.
■ OBSTRUCTIVE SLEEP APNEA/HYPOPNEA
SYNDROME
Definition OSA is defined on the basis of nocturnal and daytime
symptoms as well as sleep study findings. Diagnosis requires the patient
to have (1) either symptoms of nocturnal breathing disturbances (snoring, snorting, gasping, or breathing pauses during sleep) or daytime
sleepiness or fatigue that occurs despite sufficient opportunity to sleep
and is unexplained by other medical problems; and (2) five or more
episodes of obstructive apnea or hypopnea per hour of sleep (the
apnea-hypopnea index [AHI], calculated as the number of episodes
divided by the number of hours of sleep) documented during a sleep
study. OSA also may be diagnosed in the absence of symptoms if the
AHI is ≥15 episodes/h. Each episode of apnea or hypopnea represents a
reduction in breathing for at least 10 s and commonly results in a ≥3%
drop in oxygen saturation or a brain cortical arousal. OSA severity can
be characterized by the frequency of breathing disturbances (AHI), the
amount of oxyhemoglobin desaturation with respiratory events, the
duration of apneas and hypopneas, the degree of sleep fragmentation,
and the level of reported daytime sleepiness or functional impairment.
Pathophysiology During inspiration, intraluminal pharyngeal
pressure becomes increasingly negative, creating a “suctioning” force.
Because the pharyngeal airway has no fixed bone or cartilage, airway
patency is dependent on the stabilizing influence of the pharyngeal
dilator muscles. Although these muscles are continuously activated
during wakefulness, neuromuscular output declines with sleep onset.
In patients with a collapsible airway, the reduction in neuromuscular
output results in transient episodes of pharyngeal collapse (manifesting as an “apnea”) or near collapse (manifesting as a “hypopnea”). The
episodes of collapse are typically terminated when ventilatory reflexes
are activated and cause arousal, thus stimulating an increase in neuromuscular activity and opening of the airway. The airway may collapse
at different sites, such as the soft palate (most common), tongue base,
lateral pharyngeal walls, and/or epiglottis (Fig. 297-1). OSA may be
most severe during rapid eye movement (REM) sleep, when neuromuscular output to the skeletal muscles is particularly low, and in the
supine position due to gravitational forces.
2206 PART 7 Disorders of the Respiratory System
in men and women: compared to men, women have a lower arousal
threshold and less neuromuscular collapsibility. Women tend to have
shorter duration of apneas and apneas that occur predominantly in
REM sleep. Failure to recognize these differences can contribute to
underrecognition of OSA in women.
Variations in craniofacial morphology that reduce the size of the
posterior airway space increase OSA risk. The contribution of skeletal
structural features to OSA is most evident in nonobese patients. Identification of features such as retrognathia can influence therapeutic
decision-making.
OSA has a strong genetic basis, as evidenced by its significant familial aggregation and heritability. For a first-degree relative of a patient
with OSA, the odds of having OSA is approximately twofold higher
than that of someone without an affected relative. Several genetic
variants have been associated with prevalence of OSA or with related
traits, such as the frequency of apneas and hypopneas, the duration of
respiratory events, and degree of overnight levels of hypoxemia.
OSA prevalence varies with age, from 5 to 15% among middle-aged
adults to >20% among elderly individuals, although in a majority of
affected adults, the disorder is undiagnosed. There is a peak due to
lymphoid hypertrophy among children between the ages of 3 and
8 years; with airway growth and lymphoid tissue regression during later
childhood, prevalence declines. Then, as obesity prevalence increases
in adolescence and adulthood, OSA prevalence again increases.
The prevalence of OSA is especially high among patients with
certain medical conditions, including diabetes mellitus, hypertension, and atrial fibrillation. Individuals of East Asian ancestry appear
to be at increased risk of OSA at relatively low levels of body mass
index, reflecting the greater influence of craniofacial risk factors. In
the United States, African Americans, especially children and young
adults, are at higher risk for OSA than their white counterparts.
Course of the Disorder The precise onset of OSA is usually hard
to identify. A person may snore for many years, often beginning in
childhood, before OSA is identified. Weight gain may precipitate an
increase in symptoms, which in turn may lead the patient to pursue an
evaluation. OSA may become less severe with weight loss, particularly
after bariatric surgery. In adults, there is a gradual increase in AHI with
age, although marked increases and decreases in the AHI are uncommon unless accompanied by weight change.
APPROACH TO THE PATIENT
Obstructive Sleep Apnea/Hypopnea Syndrome
An evaluation for OSA should be considered in patients with symptoms of OSA and one or more risk factors. Screening also should
be considered in patients who report symptoms consistent with
OSA and who are at high risk for OSA-related morbidities, such as
hypertension, diabetes mellitus, and cardiac and cerebrovascular
diseases.
SYMPTOMS AND HISTORY
When possible, a sleep history should be obtained with assistance
from a bed partner or household member. Snoring is the most
common complaint; however, its absence does not exclude the diagnosis, as pharyngeal collapse may occur without tissue vibration.
Gasping or snorting during sleep may also be reported, reflecting
termination of individual apneas with abrupt airway opening. Dyspnea is unusual, and its absence generally distinguishes OSA from
paroxysmal nocturnal dyspnea, nocturnal asthma, and acid reflux
with laryngospasm. Patients also may describe frequent awakening
or sleep disruption, which is more common among women and
older adults. The most common daytime symptom is excessive
daytime sleepiness, identified by a history of difficulty maintaining
alertness or involuntary periods of dozing. However, many women
preferentially report fatigue rather than sleepiness. Other symptoms
include a dry mouth, nocturnal heartburn, diaphoresis of the chest
and neck, nocturia, morning headaches, trouble concentrating,
irritability, and mood disturbances. Insomnia, which is common in
the general population, may coexist with OSA. Although difficulty
falling sleep is rarely caused by OSA, awakening at apnea termination may cause difficulty maintaining sleep, a symptom more
likely to be reported by women than by men, and often responds
to treatment of OSA. Several questionnaires that evaluate snoring
frequency, self-reported apneas, and daytime sleepiness can facilitate OSA screening. The predictive ability of a questionnaire can be
enhanced by a consideration of whether the patient is male or has
risk factors such as obesity or hypertension.
PHYSICAL FINDINGS
Physical findings often reflect the etiologic factors for the disorder
as well as comorbid conditions, particularly vascular disease. On
examination, patients may exhibit hypertension and regional (central) obesity, as indicated by a large waist and neck circumference.
The oropharynx may reveal a small orifice with crowding due to an
enlarged tongue, a low-lying soft palate with a bulky uvula, large
tonsils, a high-arched palate, or micro-/retrognathia. Since nasal
resistance can increase the propensity to pharyngeal collapse, the
nasal cavity should be inspected for polyps, septal deviation, allergic
rhinitis, and other signs of obstruction. Because patients with heart
failure are at increased risk for both OSA and CSA, a careful cardiac
examination should be conducted to detect possible left- or rightsided cardiac dysfunction. Evidence of cor pulmonale suggests a
comorbid cardiopulmonary condition; OSA alone is not thought
to cause right-heart failure. A neurologic evaluation is needed to
evaluate for conditions such as neuromuscular and cerebrovascular
diseases, which increase OSA risk.
LABORATORY FINDINGS
Diagnostic Findings Since symptoms and signs do not accurately
predict the severity of sleep-related breathing disturbances, specific
diagnosis and categorization of OSA severity requires objective
measurement of breathing during sleep. The gold standard for diagnosis of OSA is an overnight polysomnogram (PSG). A negative
in-laboratory PSG usually rules out OSA. However, false-negative
studies can result from night-to-night variation in OSA severity,
particularly if there was insufficient REM sleep or less supine sleep
during testing than is typical for the patient. Home sleep tests that
record only respiratory and cardiac channels are commonly used
as a cost-effective means for diagnosing OSA. However, a home
study may yield a false-negative result if sleep time is not accurately
estimated or in individuals experiencing hypopneas with arousals
rather than oxyhemoglobin desaturation. Therefore, if there is a
high prior probability of OSA, a negative home study should be
followed by PSG.
The key physiologic information collected during a sleep study
for OSA assessment includes measurement of breathing (changes
in airflow, respiratory excursion), oxygenation (hemoglobin oxygen saturation), body position, and cardiac rhythm. In addition,
PSGs and some home sleep studies measure sleep continuity and
sleep stages (by electroencephalography, chin electromyography,
electro-oculography, and actigraphy), leg movements, and snoring
intensity. This information is used to quantify the frequency and
subtypes of abnormal respiratory events during sleep as well as
associated changes in oxygen hemoglobin saturation, arousals, and
sleep stage distributions. Tables 297-1 and 297-2 define the respiratory events scored and the severity guidelines employed during a
sleep study. Fig. 297-2 shows examples of sleep-related respiratory
events. A typical sleep study report provides quantitative data such
as the AHI (number of apneas plus hypopneas per hour of sleep)
and the profile of oxygen saturation over the night (mean, nadir,
time at low levels). Reports may also include the respiratory disturbance index, which includes the number of respiratory effort–
related arousals in addition to the AHI. In-laboratory PSG also
quantifies sleep latency (time from “lights off ” to first sleep onset),
the frequency of periodic limb movements during sleep, sleep
2207 Sleep Apnea CHAPTER 297
TABLE 297-1 Respiratory Event Definitions
• Apnea: Cessation of airflow for ≥10 s during sleep, accompanied by:
• Persistent respiratory effort (obstructive apneas, Fig. 297-2A), or
• Absence of respiratory effort (central apneas, Fig. 297-2B)
• Hypopnea: A ≥30% reduction in airflow for at least 10 s during sleep that is
accompanied by either a ≥3% desaturation or an arousal (Fig. 297-2C)
• Respiratory effort–related arousal (RERA): Partial obstruction that does not
meet the criteria for hypopnea but provides evidence of increasing inspiratory
effort (usually through pleural pressure monitoring) punctuated by an arousal
(Fig. 297-2D)
• Flow-limited breath: A partially obstructed breath, typically within a hypopnea
or RERA, identified by a flattened or “scooped-out” inspiratory flow shape
(Fig. 297-3)
TABLE 297-2 Obstructive Sleep Apnea/Hypopnea Syndrome
(OSAHS): Quantification and Severity Scale
• Apnea-hypopnea index (AHI)a
: Number of apneas plus hypopneas per hour of
sleep
• Respiratory disturbance index (RDI): Number of apneas plus hypopneas plus
RERAs per hour of sleep
• Mild OSAHS: AHI of 5–14 events/h
• Moderate OSAHS: AHI of 15–29 events/h
• Severe OSAHS: AHI of ≥30 events/h
a
Each level of AHI can be further quantified by level of sleepiness and associated
hypoxemia.
Abbreviation: RERAs, respiratory effort–related arousals.
efficiency (percentage of time asleep relative to time in bed), arousal
index (number of cortical arousals per hour of sleep), and time in
each sleep stage. These metrics can further characterize the severity
of OSA, which is associated with an increased arousal index, low
sleep efficiency, and a reduction of time in deep (stage N3) and
REM sleep and increase in light (stage N1) sleep. The detection of
autonomic responses to apneas and hypopneas, such as surges in
blood pressure, changes in heart rate, and abnormalities in cardiac
rhythm, also provides relevant information on OSA severity.
Other Laboratory Findings Various imaging studies, including
cephalometric radiography, upper airway MRI and CT, and fiberoptic endoscopy, can be used to identify anatomic risk factors for
OSA. While these may be useful for planning surgical interventions,
they are not indicated in the routine evaluation of OSA. Cardiac
testing may yield evidence of impaired systolic or diastolic ventricular function or abnormal cardiac structure. Overnight blood
pressure monitoring often displays a “nondipping” pattern (absence
of the typical 10% fall of blood pressure during sleep compared
to wakefulness). Arterial blood gas measurements made during
wakefulness are usually normal. Waking hypoxemia or hypercarbia
suggests coexisting cardiopulmonary disease or hypoventilation
syndromes. Patients with severe nocturnal hypoxemia may have
elevated hemoglobin values. A multiple sleep latency test or a maintenance of wakefulness test can be useful in quantifying sleepiness
and helping to distinguish OSA from narcolepsy.
EKG
snore
t. flow
chest
abdomen
SaO2
EEG
EOG
chin
n. p. flow
snore
chest
abdomen
SaO2
EEG
EOG
chin
flow
Hypnogram
Stage
snore
flow
position
chest
abdomen
SaO2
EEG
A
C
EKG
snore
t. flow
chest
abdomen
SaO2
EEG
EOG
chin
n. p. flow
Legs
B
D
Ar
FIGURE 297-2 Obstructive apnea. A. There are 30 s of no airflow, as shown in the nasal pressure (n. p. flow) and thermistor-measured flow (t. flow). Note the presence of
chest-abdomen paradox, indicating respiratory effort against an occluded airway. B. Central apnea in a patient with Cheyne-Stokes respiration due to congestive heart
failure. The flat chest-abdomen tracings indicate the absence of inspiratory effort during the central apneas. C. Hypopnea. Partial obstruction of the pharyngeal airway can
limit ventilation, leading to desaturation (a mild decrease in this patient, from 93 to 90%) and arousal. D. Respiratory effort–related arousal (RERA). Minimal flow reduction
terminated by an arousal (Ar) without desaturation constitutes a RERA. EEG, electroencephalogram; EOG, electro-oculogram; EKG, electrocardiogram.
2208 PART 7 Disorders of the Respiratory System
Normal Flow limitation
FIGURE 297-3 Example of flow limitation. The inspiratory flow pattern in a patent
airway is rounded and peaks in the middle. In contrast, a partially obstructed airway
exhibits an early peak followed by mid-inspiratory flattening, yielding a scooped-out
appearance.
Health Consequences and Comorbidities OSA is the most
common medical cause of daytime sleepiness and negatively influences
quality of life. It is also strongly associated with cardiac, cerebrovascular, and metabolic disorders and with premature death. This broad
range of health effects is attributable to the impact of sleep fragmentation, cortical arousal, and intermittent hypoxemia and hypercapnia
on vascular, cardiac, metabolic, and neurologic functions. OSA-related
respiratory events stimulate sympathetic overactivity, leading to acute
blood pressure surges during sleep and nocturnal as well as daytime
hypertension. OSA-related hypoxemia also stimulates release of acutephase proteins and reactive oxygen species that exacerbate insulin
resistance and lipolysis and cause an augmented prothrombotic and
proinflammatory state. Inspiratory effort against an occluded airway
causes large intrathoracic negative pressure swings, altering cardiac
preload and afterload and resulting in cardiac remodeling and reduced
cardiac function. Hypoxemia and sympathetic-parasympathetic imbalance also may cause electrical remodeling of the heart and myocyte
injury.
HYPERTENSION OSA can raise blood pressure to prehypertensive and
hypertensive ranges, increase the prevalence of a nondipping overnight
blood pressure pattern, and increase the risk of uncontrolled and resistant hypertension. Elevations in blood pressure are due to augmented
sympathetic nervous system activation as well as alterations in the
renin-angiotensin-aldosterone system and fluid balance. Treatment of
OSA with nocturnal continuous positive airway pressure (CPAP) has
been shown to reduce 24-h ambulatory blood pressure. Although the
overall impact of CPAP on blood pressure levels is relatively modest
(averaging 2–4 mmHg), larger improvements are observed among
patients who have a high AHI, report daytime sleepiness, or have resistant hypertension.
CARDIOVASCULAR, CEREBROVASCULAR, AND METABOLIC DISEASES
Among the most serious health consequences of OSA may be its impact
on cardiac and metabolic functions. Strong epidemiologic evidence
indicates that OSA significantly increases the risk of coronary artery disease, heart failure with and without reduced ejection fraction, atrial and
ventricular arrhythmias, atherosclerosis and coronary artery disease,
stroke, and diabetes. Treatment of OSA has been shown to reduce several markers of cardiovascular risk and improve insulin resistance and,
in uncontrolled studies, is associated with a decreased recurrence rate of
atrial fibrillation. Recent randomized clinical trials, however, have failed
to demonstrate that OSA treatment with CPAP reduces cardiac event
rates or prolongs survival. These outcomes may reflect exclusion from
these trials of patients with excessive sleepiness, as there is evidence
that sleepy patients may have the greatest OSA-related cardiovascular
risk. Limited adherence to treatment among trial participants or the
widespread use of other effective secondary prevention measures, such
as beta blockade, antiplatelet agents, and lipid-lowering therapy, may
also limit the impact of CPAP on cardiovascular risk.
SLEEPINESS More than 50% of patients with moderate to severe OSA
report daytime sleepiness. Patients with OSA symptoms have a twofold
increased risk of occupational accidents. Individuals with elevated
AHIs are involved in motor vehicle crashes approximately two to
three times as often as persons with normal AHIs. Randomized controlled trials have shown that treatment of OSA with CPAP alleviates
sleepiness as measured by either questionnaire or objective testing in
patients with both mild and more severe disease. However, the degree
of improvement varies widely. Residual sleepiness may be due to several factors, including suboptimal treatment adherence, insufficient
sleep time, other sleep disorders, or prior hypoxic-mediated damage
in brain areas involved in alertness. Moreover, visceral adipose tissue,
which is present in higher amounts in patients with OSA, releases somnogenic cytokines that may contribute to sleepiness. Thus, even after
treatment, it is important to assess and monitor patients for residual
sleepiness and to optimize treatment adherence, improve sleep patterns, and identify other disorders that may contribute to sleepiness.
Careful and supervised use of alerting agents may be appropriate as
adjunctive treatment in patients in whom sleepiness does not respond
to CPAP alone.
QUALITY OF LIFE AND MOOD Reductions in health-related quality
of life are common in patients with OSA, with the largest decrements
observed in scales that measure physical functioning and energy levels.
Work-related productivity also has been shown to improve in patients
with moderate to severe OSA treated with CPAP. Numerous studies,
including a large-scale trial of minimally symptomatic patients, have
shown that treatment with CPAP can improve these patient-reported
outcomes. Depressive symptoms, in particular somatic symptoms
(irritability, fatigue, lack of energy), are commonly reported in OSA
and improve with CPAP.
TREATMENT
Obstructive Sleep Apnea
A comprehensive approach to the management of OSA is needed
to reduce risk factors and comorbidities. The clinician should
seek to identify and address lifestyle and behavioral factors as well
as comorbidities that may be exacerbating OSA. As appropriate,
treatment should aim to reduce weight; optimize sleep duration
(7–9 h); regulate sleep schedules (with similar bedtimes and wake
times across the week); encourage the patient to avoid sleeping in
the supine position; treat nasal allergies; increase physical activity; eliminate alcohol ingestion (which impairs pharyngeal muscle
activity) within 3 h of bedtime; and minimize use of opiate medications. Sedative hypnotic medications have inconsistent effects
on OSA but should be avoided in most patients with moderate to
severe OSA. Patients should be counseled to avoid drowsy driving.
CPAP is the standard medical therapy with the highest level
of evidence for efficacy. Delivered through a nasal or nasal-oral
mask, CPAP works as a mechanical splint to hold the airway open,
thus maintaining airway patency during sleep. An overnight CPAP
titration study can determine the optimal pressure setting that
reduces the number of apneas/hypopneas during sleep, improves
gas exchange, and reduces arousals; however, the use of “autotitrating” CPAP devices used in home settings has eliminated the
need for titration sleep studies in many patients. Rates of adherence
to CPAP treatment are highly variable (average, 50–80%) and may
be improved with support by a skilled health care team who can
address side effects, help the patient “problem solve,” and provide
motivational education (Table 297-3). Despite the limitations of
TABLE 297-3 Side Effects of Continuous Positive Airway Pressure
(CPAP) and Their Treatments
SIDE EFFECT TREATMENT
Nasal congestion Provide heated humidification, administer
saline/steroid nasal sprays
Claustrophobia Change mask interface (e.g., to nasal prongs),
promote habituation (i.e., practice breathing on
CPAP while awake)
Difficulty exhaling Temporarily reduce pressure, provide bilevel
positive airway pressure
Bruised nasal ridge Change mask interface, provide protective
padding
Aerophagia Administer antacids
2209 Lung Transplantation CHAPTER 298
CPAP, controlled studies have demonstrated its beneficial effect on
alertness, mood, quality of life, work-related productivity, blood
pressure, and insulin sensitivity. Uncontrolled studies also indicate
a favorable effect on cardiovascular outcomes, cardiac ejection fraction, atrial fibrillation recurrence, and mortality risk.
Oral appliances for OSA work by advancing the mandible, thus
opening the airway by repositioning the lower jaw and pulling the
tongue forward. These devices generally work better when customized for patient use; maximal adaptation can take several weeks.
Efficacy studies show that these devices can reduce the AHI by
≥50% in two-thirds of individuals, although these data are based
largely on patients with mild OSA. Some patients with moderate
or severe OSA respond to oral appliances as well, although no consistent predictors of success have been identified in these groups,
and thus, follow-up sleep testing is recommended. Side effects of
oral appliances include temporomandibular joint pain and tooth
movement; thus, they require that the patient have adequate dental
and periodontal structures. Oral appliances are most often used for
treating patients with mild/moderate OSA or patients who do not
tolerate CPAP. However, as some patients are more adherent to oral
appliances than to CPAP, these devices are under investigation for
treatment of more severe disease.
Upper airway surgery for OSA is less efficacious than CPAP and
is mostly reserved for the treatment of patients who snore, have
mild OSA, or cannot tolerate CPAP. Uvulopalatopharyngoplasty
(removal of the uvula and the margin of the soft palate) is the most
commonly performed surgery for OSA and, although results vary
greatly, is generally less successful than treatment with oral appliances. Upper airway surgery is less effective in severe OSA and in
obese patients. Success rates may be higher for multilevel surgery
(involving more than one site/structure) performed by an experienced surgeon, but the selection of patients is an important factor
and relies on careful targeting of culprit areas for surgical resection.
Bariatric surgery is an option for obese patients with OSA and can
improve not only OSA but also other obesity-associated health
conditions. Other procedures that can decrease snoring but have
minimal effects on OSA include injection of a hardening agent to
the soft palate (resulting in stiffening), radiofrequency ablation,
laser-assisted uvulopalatoplasty, and palatal implants.
Upper airway neurostimulation is a recently tested alternative
treatment for OSA. Unilateral stimulation of the hypoglossal nerve
through a surgically implanted device was shown to significantly
decrease the AHI and improve a number of patient-reported outcomes, such as sleepiness and quality of life, for a duration of at least
5 years after treatment in carefully selected patients. This therapy
is reserved for patients who cannot tolerate or fail CPAP therapy.
Current inclusion criteria are moderate to severe OSA (AHI 15–65),
BMI <32 kg/m2
, and absence of complete concentric collapse at the
level of the velum documented by awake and drug-induced endoscopy (a predictor of response to surgery). Additional research is
underway to further evaluate longer-term effectiveness and potential utility of this treatment in other patient groups.
Supplemental oxygen can improve oxygen saturation, but there is
little evidence that it improves OSA symptoms or the AHI in unselected patients. There is conflicting evidence regarding the effect of
supplemental oxygen on blood pressure in patients with OSA.
CENTRAL SLEEP APNEA
CSA, which is less common than OSA, may occur in isolation or,
more often, in combination with obstructive events in the form of
“mixed” apneas. CSA is often caused by an increased sensitivity to
Pco2
, which leads to an unstable breathing pattern that manifests
as hyperventilation alternating with apnea. A prolonged circulation
delay between the pulmonary capillaries and carotid chemoreceptors is also a contributing cause; thus, individuals with congestive heart failure are at risk for CSA. With prolonged circulation
delay, there is a crescendo-decrescendo breathing pattern known as
Cheyne-Stokes breathing (Fig. 297–2B). Other risk factors for CSA
include opioid medications (which appear to have a dose-dependent
effect on CSA) and hypoxia (e.g., breathing at high altitude). In
some individuals, CPAP—particularly at high pressures—seems to
induce central apnea; this condition is referred to as complex sleep
apnea or treatment-emergent central sleep apnea. Rarely, CSA may
be caused by blunted chemosensitivity due to congenital disorders
(congenital central hypoventilation syndrome) or acquired factors.
CSA is an independent risk factor for the development of both
heart failure and atrial fibrillation, possibly related to elevations in
sympathetic nervous system activity that accompany this disorder;
alternatively, CSA may be an early marker of subclinical myocardial
dysfunction. Patients with CSA may report symptoms of frequent
awakenings as well as daytime fatigue. Treatment of CSA is difficult
and depends on the underlying cause. Limited data suggest that
supplemental oxygen can reduce the frequency of central apneas,
particularly in patients with hypoxemia, and ongoing clinical trials are further evaluating supplemental oxygen for use in patients
with heart failure and CSA. Cheyne-Stokes breathing is treated by
optimizing therapy for heart failure. At this time, there is no good
evidence that CPAP, including adaptive servoventilation (a form
of ventilatory support that attempts to regularize the breathing
pattern), improves health outcomes in patients with Cheyne-Stokes
breathing without OSA, and in fact, it may be detrimental in those
with heart failure associated with reduced ejection fraction.
■ FURTHER READING
Berry R, Wagner M: Sleep Medicine Pearls, 3rd ed. Philadelphia,
Elsevier, 2015.
Gottlieb DJ, Punjabi NM: Diagnosis and management of obstructive
sleep apnea. A review. JAMA 323:1389, 2020.
Javaheri S et al: Sleep apnea: Types, mechanisms, and clinical cardiovascular consequences. J Am Coll Cardiol 769:841, 2017.
Kapur VK et al: Clinical Practice Guideline for Diagnostic Testing
for Adult Obstructive Sleep Apnea: An American Academy of Sleep
Medicine clinical practice guideline. J Clin Sleep Med 13:479, 2017.
Marklund M et al: Update on oral appliance therapy. Eur Respir Rev
28:190083, 2019.
■ END-STAGE LUNG DISEASE AND INDICATIONS
FOR LUNG TRANSPLANTATION
For the purpose of lung allocation score (LAS) prioritization for organ
allocation, the United Network for Organ Sharing (UNOS) divides
advanced lung disease diagnoses into four categories: (A) obstructive
lung disease (including non-cystic fibrosis-related bronchiectasis and
obliterative bronchiolitis), (B) pulmonary vascular disease, (C) cystic
fibrosis, and (D) restrictive lung disease. Historically, obstructive lung
disease was the most common indication for transplantation, but since
the implementation of the LAS system, idiopathic pulmonary fibrosis (IPF), the most common restrictive lung disease, has become an
increasingly frequent indication for transplantation. Prior to the era of
antifibrotic therapy, the average life expectancy from the time of diagnosis of IPF was 3–5 years, making patients with this disease the cohort
to experience most clearly a survival benefit from lung transplantation.
As a result, the LAS system prioritizes patients with IPF. Similarly,
patients who experience secondary effects of their lung disease, including pulmonary hypertension, right heart dysfunction, and hypercarbia,
are prioritized for allocation and should be considered for referral for
transplant evaluation irrespective of other markers of disease severity.
298 Lung Transplantation
Hilary J. Goldberg, Hari R. Mallidi
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