Chronic Obstructive Pulmonary Disease (COPD) - Pulmonary Disorders - Merck Manual Professional Edition (2024)

1. 1. Centers for Disease Control and Prevention: Chronic Obstructive Pulmonary Disease (COPD). Updated June 30,2023.

2. 2. Centers for Disease Control and Prevention: National Center for Health Statistics: Leading Causes of Death. Updated January 22, 2022.

3. 3. Meza D, Khuder B, Bailey JI, et al: Mortality from COVID-19 in patients with COPD: A US study in the N3C Data Enclave. Int J Chron Obstruct Pulmon Dis 16:2323–2326, 2021. doi: 10.2147/COPD.S318000

Of all inhalational exposures, cigarette smoking is the primary risk factor in most countries, although only approximately 15% of people who smoke develop clinically apparent COPD (1). The risk for COPD increases with both duration (years of smoking) and cumulative dose (pack-years) (2asthma, are at greater risk of developing COPD than are those without.

Smoke from indoor cooking and heating is an important causative factor in countries where indoor fires are commonly used for cooking or heating (3).

Exposure to passive cigarette smoke, air pollution, and occupational dust (eg, mineral dust, cotton dust) or inhaled chemicals (eg, cadmium) contribute to the risk of COPD but are of less importance compared to cigarette smoking. Low body weight and childhood respiratory disorders also contribute to the risk of COPD.

The best-defined causative genetic disorder is alpha-1 antitrypsin deficiency, which is an important cause of emphysema in people who do not smoke and markedly increases susceptibility to disease in people who do.

More than 30 genetic alleles have been found to be associated with COPD or decline in lung function in selected populations, but none has been shown to be as consequential as alpha-1 antitrypsin.

1. 1. Wheaton AG, Liu Y, Croft JB, et al: Chronic Obstructive Pulmonary Disease and Smoking Status - United States, 2017.MMWR Morb Mortal Wkly Rep 68(24):533–538, 2019. doi:10.15585/mmwr.mm6824a1

2. 2. Bhatt SP, Kim YI, Harrington KF, et al. Smoking duration alone provides stronger risk estimates of chronic obstructive pulmonary disease than pack-years.Thorax 2018;73(5):414-421. doi:10.1136/thoraxjnl-2017-210722

3. 3. Ortiz-Quintero B, Martínez-Espinosa I, Pérez-Padilla R: Mechanisms of Lung Damage and Development of COPD Due to Household Biomass-Smoke Exposure: Inflammation, Oxidative Stress, MicroRNAs, and Gene Polymorphisms.Cells 12(1):67, 2022. doi:10.3390/cells12010067

Inhalational exposures can trigger an inflammatory response in airways and alveoli that leads to disease in genetically susceptible people. The process is thought to be mediated by an increase in protease activity and a decrease in antiprotease activity. Lung proteases, such as neutrophil elastase, matrix metalloproteinases, and cathepsins, break down elastin and connective tissue in the normal process of tissue repair. Their activity is normally balanced by antiproteases, such as alpha-1 antitrypsin, airway epithelium–derived secretory leukoproteinase inhibitor, elafin, and matrix metalloproteinase tissue inhibitor. In patients with COPD, activated neutrophils and other inflammatory cells release proteases as part of the inflammatory process; protease activity exceeds antiprotease activity, and tissue destruction and mucus hypersecretion result.

Activation of neutrophils and macrophages also leads to accumulation of free radicals, superoxide anions, and hydrogen peroxide, which inhibit antiproteases and cause bronchoconstriction, mucosal edema, and mucous hypersecretion. Neutrophil-induced oxidative damage, release of profibrotic neuropeptides (eg, bombesin), and reduced levels of vascular endothelial growth factor (VEGF) may contribute to apoptotic destruction of lung parenchyma.

The inflammation in COPD increases as disease severity increases, and, in severe (advanced) disease, inflammation does not resolve completely despite smoking cessation. This chronic inflammation does not seem to respond to corticosteroids, particularly in patients who continue to smoke cigarettes (1).

Mechanical stress on alveoli from over-distension may make them susceptible to proteases, leading to alveolar septal destruction and progressive emphysema. This is particularly notable in the upper lobes of the lung (2).

Respiratory infection (to which patients with COPD are prone) may amplify progression of lung destruction.

Bacteria, especially Haemophilus influenzae, colonize the lower airways of approximately 30% of patients with COPD (3). In more severely affected patients (eg, those with previous hospitalizations), colonization with Pseudomonas aeruginosa or other gram-negative bacteria is common. Smoking and airflow obstruction may lead to impaired mucus clearance in lower airways, which predisposes to infection. Repeated bouts of infection increase the inflammatory burden that hastens disease progression. There is no evidence, however, that long-term use of antibiotics slows the progression of COPD.

The cardinal pathophysiologic feature of COPD is airflow limitation caused by airway narrowing and/or obstruction, loss of elastic recoil, or both.

Airway narrowing and obstruction are caused by inflammation-mediated mucus hypersecretion, mucus plugging, mucosal edema, bronchospasm, peribronchial fibrosis, and remodelling of small airways or a combination of these mechanisms. Alveolar septa are destroyed, reducing parenchymal attachments to the airways and thereby facilitating airway closure during expiration.

Enlarged alveolar spaces sometimes consolidate into bullae, defined as airspaces ≥ 1 cm in diameter. Bullae may be entirely empty or have strands of lung tissue traversing them in areas of locally severe emphysema; they occasionally occupy an entire hemithorax. These changes lead to loss of elastic recoil and lung hyperinflation.

Increased airway resistance increases the work of breathing. Lung hyperinflation, although it decreases airway resistance, also increases the work of breathing. Increased work of breathing may lead to alveolar hypoventilation with hypoxia and hypercapnia, although hypoxia and hypercarbia can also be caused by ventilation/perfusion (V/Q) mismatch.

In addition to airflow limitation and sometimes respiratory insufficiency, complications include

• Pulmonary hypertension

• Respiratory infection

• Weight loss and other comorbidities

Chronic alveolar hypoxia increases pulmonary vascular tone, which, if diffuse, causes pulmonary hypertension and cor pulmonale. The increase in pulmonary vascular pressure may be augmented by the destruction of the pulmonary capillary bed due to destruction of alveolar septa.

Viral or bacterial respiratory infections are common among patients with COPD and cause a large percentage of acute exacerbations. It is currently thought that acute bacterial infections are due to acquisition of new strains of bacteria rather than overgrowth of chronic colonizing bacteria.

Weight loss may occur, perhaps in response to insufficient caloric intake and increased levels of circulating tumor necrosis factor (TNF)-alpha. This weight loss may be due to a mismatch between caloric expenditure and nutritional intake because caloric expenditure can be high in the presence of heightened inflammatory cytokines and hypoxemia.

Other coexisting or complicating disorders that adversely affect quality of life and/or survival include osteoporosis, depression, anxiety, coronary artery disease, arrhythmias, lung cancer and other cancers, muscle atrophy, and gastroesophageal reflux. The extent to which these disorders are consequences of COPD, smoking, and the accompanying systemic inflammation is unclear.

1. 1. Adco*ck IM, Bhatt SP, Balkissoon R, Wise RA: The Use of Inhaled Corticosteroids for Patients with COPD Who Continue to Smoke Cigarettes: An Evaluation of Current Practice.Am J Med 135(3):302–312, 2022. doi:10.1016/j.amjmed.2021.09.006

2. 2. Suki B, Sato S, Parameswaran H, Szabari MV, Takahashi A, Bartolák-Suki E: Emphysema and mechanical stress-induced lung remodeling.Physiology (Bethesda) 28(6):404–413, 2013. doi:10.1152/physiol.00041.2013

3. 3. Short B, Carson S, Devlin AC, et al: Non-typeableHaemophilus influenzaechronic colonization in chronic obstructive pulmonary disease (COPD).Crit Rev Microbiol47(2):192–205, 2021. https://doi.org/10.1080/1040841X.2020.1863330

Patients suspected of having COPD should undergo pulmonary function testing to confirm airflow limitation, to quantify its severity and reversibility, and to distinguish COPD from other disorders. (Some experts recommend screening pulmonary function testing for all patients with a history of smoking.) Pulmonary function testing is also useful for following disease progression and monitoring response to treatment. The primary diagnostic tests are

• FEV1: The volume of air forcefully expired during the first second after taking a full breath

• Forced vital capacity (FVC): The total volume of air expired with maximal force

• Flow-volume loops: Simultaneous spirometric recordings of airflow and volume during forced maximal expiration and inspiration

Reductions of FEV1, FVC, and the ratio of FEV1/FVC are the hallmark of airflow limitation. Flow-volume loops show a concave pattern in the expiratory tracing.

There are 2 basic pathways by which COPD can develop and manifest with symptoms in later life:

• In the first pathway, patients may have normal lung function in early adulthood, which is followed by a more rapid decline in FEV1 (≥ 60 mL/year).

• With the second pathway, patients have impaired lung function in early adulthood, often associated with asthma or other childhood respiratory disease. In these patients, COPD may present with a normal age-related decline in FEV1 (approximately 30 mL/year).

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Although this second pathway model is conceptually helpful, a wide range of individual trajectories is possible (1). When the FEV1 falls below approximately 1 L, patients develop dyspnea during activities of daily living (although dyspnea is more closely related to the degree of dynamic hyperinflation [progressive hyperinflation due to incomplete exhalation] than to the degree of airflow limitation). When the FEV1 falls below approximately 0.8 L, patients are at risk of hypoxemia, hypercapnia, and cor pulmonale.

FEV1 and FVC are easily measured with office spirometry. Normal reference values are determined by patient age, sex, and height. It is recommended that race not be used for calculating predicted reference values (2). Airflow limitation severity in patients with COPD and FEV1/FVC < 0.70 can be classified based on post-bronchodilator FEV1 (3):

• Mild: ≥ 80% of predicted

• Moderate: 50% to 79% of predicted

• Severe: 30% to 49% of predicted

• Very severe: < 30% of predicted

Additional pulmonary function testing is necessary only in specific circ*mstances, such as before lung volume reduction procedures. Other test abnormalities may include

• Increased total lung capacity

• Increased functional residual capacity

• Increased residual volume

• Decreased vital capacity

• Decreased single-breath diffusing capacity for carbon monoxide (DLCO)

Findings of increased total lung capacity, functional residual capacity, and residual volume can help distinguish COPD from restrictive pulmonary disease, in which these measures are diminished.

Decreased DLCO is nonspecific and is reduced in other disorders that affect the pulmonary vascular bed, such as interstitial lung disease, but can help distinguish emphysema from asthma, in which DLCO is normal or elevated.

Chest radiograph may have characteristic findings. In patients with emphysema, changes can include lung hyperinflation manifested as a flat diaphragm (ie, increase in the angle formed by the sternum and anterior diaphragm on a lateral film from the normal value of 45° to > 90°), rapid tapering of hilar vessels, and bullae (ie, radiolucencies > 1 cm surrounded by arcuate, hairline shadows). Other typical findings include enlargement of the retrosternal airspace and a narrow cardiac shadow. Emphysematous changes occurring predominantly in the lung bases suggest alpha-1 antitrypsin deficiency. The lungs may look normal or have increased lucency secondary to loss of parenchyma. Among patients with chronic obstructive bronchitis, chest radiographs may be normal or may show a bibasilar increase in bronchovascular markings as a result of bronchial wall thickening.

Prominent hila suggest large central pulmonary arteries that may signify pulmonary hypertension. Right ventricular enlargement that occurs in cor pulmonale may be masked by lung hyperinflation or may manifest as encroachment of the heart shadow on the retrosternal space or by widening of the transverse cardiac shadow in comparison with previous chest radiographs.

Chest CT may reveal abnormalities that are not apparent on the chest radiograph and may also suggest coexisting or complicating disorders, such as pneumonia, pneumoconiosis, or lung cancer. CT helps assess the extent and distribution of emphysema, estimated either by visual scoring or with analysis of the distribution of lung density. Indications for obtaining CT in patients with COPD include evaluation for lung volume reduction procedures, suspicion of coexisting or complicating disorders that are not clearly evident or excluded by chest radiograph, suspicion of lung cancer, and screening for lung cancer. Enlargement of the pulmonary artery diameter greater than the ascending aorta diameter suggests pulmonary hypertension (4).

Alpha-1 antitrypsin levels should be measured in patients < 50 years with symptomatic COPD and in patients of any age with COPD who do not smoke to detect alpha-1 antitrypsin deficiency. Other indications of possible alpha-1 antitrypsin deficiency include a family history of premature COPD or unexplained liver disease, lower-lobe distribution of emphysema, and COPD associated with antineutrophil cytoplasmic antibody (ANCA)-positive vasculitis. If levels of alpha-1 antitrypsin are low, the diagnosis should be confirmed by genetic testing to establish the alpha-1 antitrypsin phenotype.

ECG, often done to exclude cardiac causes of dyspnea, typically shows diffusely low QRS voltage with a vertical heart axis caused by lung hyperinflation and increased P-wave voltage or rightward shifts of the P-wave vector caused by right atrial enlargement in patients with advanced emphysema. Findings of right ventricular hypertrophy include an R or R′ wave as tall as or taller than the S wave in lead V1; an R wave smaller than the S wave in lead V6; right-axis deviation > 110° without right bundle branch block; or some combination of these findings. Multifocal atrial tachycardia, an arrhythmia that can accompany COPD, manifests as a tachyarrhythmia with polymorphic P waves and variable PR intervals.

Echocardiography is occasionally useful for assessing right ventricular function and pulmonary hypertension, although air trapping makes it technically difficult in patients with COPD. Echocardiography is most often indicated when coexistent left ventricular or valvular heart disease is suspected.

Hemoglobin and hematocrit are of little diagnostic value in the evaluation of COPD but may show erythrocythemia (hematocrit > 48%) if the patient has chronic hypoxemia. Patients with anemia (for reasons other than COPD) have disproportionately severe dyspnea. The differential white blood cell count may be helpful. A growing body of evidence indicates that eosinophilia predicts response to inhaled corticosteroids.

Serum electrolytes are of little value but may show an elevated bicarbonate level if patients have chronic hypercapnia. Venous blood gases are useful for diagnosis of acute or chronic hypercapnia.

Patients with acute exacerbations usually have combinations of increased cough, sputum, dyspnea, and work of breathing, as well as low oxygen saturation determined with pulse oximetry, diaphoresis, tachycardia, anxiety, and cyanosis. Patients with exacerbations accompanied by retention of carbon dioxide may be lethargic or somnolent, a very different appearance.

All patients requiring hospitalization for an acute exacerbation should undergo testing to quantify hypoxemia and hypercapnia. Hypercapnia may exist without hypoxemia.

Findings of partial pressure of arterial oxygen (PaO2) < 50 mm Hg, or partial pressure of carbon dioxide in arterial blood (PaCO2) > 50 mm Hg, or partial pressure of carbon dioxide in venous blood (PvCO2) > 55 mm Hg in patients with respiratory acidemia (pH < 7.35) define acute respiratory failure. Some patients chronically manifest such levels of PaO2 and PaCO2 in the absence of acute respiratory failure.

A chest radiograph is often done to check for pneumonia or pneumothorax. Point of care ultrasound (POCUS) may prove to be a useful adjunctive procedure for rapid diagnosis of pneumonia or pneumothorax. In patients with acute onset of symptoms, chest CT angiogram is done to check for pulmonary embolism. Very rarely, among patients receiving chronic systemic corticosteroids, infiltrates may represent Aspergillus pneumonia.

Yellow or green sputum is a reliable indicator of neutrophils in the sputum and suggests bacterial colonization or infection.

Sputum culture is usually done in hospitalized patients but is not usually necessary in outpatients. In samples from outpatients, Gram stain usually shows neutrophils with a mixture of organisms, often gram-positive diplococci (Streptococcus pneumoniae), gram-negative bacilli (H. influenzae), or both. However, culture and microscopic examination of sputum is usually not necessary for outpatients. Other oropharyngeal commensal organisms, such as Moraxella catarrhalis (formerly known as Branhamella catarrhalis), occasionally cause exacerbations. In hospitalized patients, resistant gram-negative organisms (eg, Pseudomonas) or, rarely, Staphylococcus may be identified in culture specimens.

During influenza season, a rapid influenza test will guide treatment with anti-influenza agents, and a respiratory viral panel for respiratory syncytial virus (RSV), rhinovirus, and metapneumovirus may allow tailoring of antimicrobial therapy. Testing for COVID-19 and consideration of COVID-19–specific therapies is also indicated.

Serum C-reactive protein (CRP) is helpful in guiding the use of antibiotics during exacerbations. In clinical trials, use of antibiotics can be decreased in patients with low CRP without evidence of harm (5, 6).

1. 1. Lange P, Celli B, Agusti A, et al: Lung-function trajectories leading to chronic obstructive pulmonary disease. N Engl J Med 373(2):111–122, 2015.

2. 2. Bhakta NR, Bime C, Kaminsky DA, et al: Race and ethnicity in pulmonary function test interpretation: An Official American Thoracic Society Statement.Am J Respir Crit Care Med 207(8):978–995, 2023. doi:10.1164/rccm.202302-0310ST

3. 3. Global Initiative for Chronic Obstructive Lung Disease (GOLD): Diagnosis and assessment. Global Strategy for the Prevention, Diagnosis, and Management of COPD: 2024 report.

4. 4. Iyer AS, Wells JM, Vishin S, et al: CT scan-measured pulmonary artery to aorta ratio and echocardiography for detecting pulmonary hypertension in severe COPD. Chest 145(4):824–832, 2014.

5. 5. Butler CC, Gillespie D, White P, et al: C-Reactive protein testing to guide antibiotic prescribing for COPD exacerbations. N Engl J Med 381(2):111–120, 2019. doi: 10.1056/NEJMoa1803185

6. 6. Prins HJ, Duijkers R, van der Valk P, et al: CRP-guided antibiotic treatment in acute exacerbations of COPD in hospital admissions. Eur Respir J 53(5):1802014, 2019. doi: 10.1183/13993003.02014-2018

1. 1. Almagro P, Martinez-Camblor P, Soriano JB, et al: Finding the best thresholds of FEV1 and dyspnea to predict 5-year survival in COPD patients: the COCOMICS study. PLoS One 9(2):e89866, 2014.doi: 10.1371/journal.pone.0089866