For the patient at the chronic bronchitis end of the spectrum, obstruction to airflow occurs with both inspiration and expiration. Widespread bronchial narrowing and mucous plugging produce hypoxemia because of mismatching of ventilation and perfusion. Hypercarbia results from impeded ventilation. Chronic hypoxia and hypercarbia increase pulmonary arterial resistance and may lead to the development of pulmonary hypertension and, eventually, cor pulmonale (altered structure and/or function of the right ventricle from the underlying lung disease). Sudden worsening may precipitate acute right-sided heart failure in severe chronic bronchitis. The patient may appear plethoric and cyanotic. Secondary polycythemia is common.

For the patient on the emphysema end of the spectrum, the clinical picture is dominated by dyspnea, particularly on exertion. Cough is only a minor complaint, and sputum production is scant. The patient with advanced disease is thin and tachypneic, often using accessory muscles of respiration and pursed-lip breathing. The latter helps to keep noncartilaginous airways from collapsing during expiration. Cyanosis is uncommon because the oxygen tension (PO₂) is only minimally reduced. The neck veins may seem distended, but only during expiration. The anterior-posterior diameter of the chest is increased, the percussion note is hyperresonant, and the breath sounds are distant. Usually, no signs of cor pulmonale are present, although the right ventricular impulse may be prominent because of displacement by hyperinflated lungs. As noted, hypoxemia is minimal, and little, if any, carbon dioxide retention occurs until the end stages of the disease. Chest radiography demonstrates hyperinflation and hyperlucency, especially at the apices, except in patients with antitrypsin deficiency, whose radiographic changes are greatest at the bases.

As disease severity progresses, COPD exacerbations develop and become more frequent, characterized by an acute worsening of symptoms, typically but, as noted, not always triggered by infection; heart failure, pulmonary embolization, and acute ischemia have also been associated with exacerbations. The best predictor of an exacerbation is a history of a prior exacerbation. Recurrent exacerbations can have serious long-term consequences, including hastened declines in FEV₁, functional capacity, and quality of life and increased risk of death. Although persons with severe disease are at greatest risk for exacerbations, these may also occur in those with more moderate disease severity (FEV₁ >50% predicted).

It remains difficult to predict survival in individual patients. Although the prognosis for patients with COPD is not very good, therapy does prolong survival—cessation of smoking is critical (see later discussion). The onset of recurrent COPD exacerbations, resting tachycardia, or cor pulmonale indicates a poor prognosis. By the time the FEV₁ declines to less than 1 L/s, the mean annual mortality approaches 10%.

Spirometry is essential to confirm the diagnosis in patients with symptoms suggestive of COPD, including those with chronic cough and sputum production as well as those who present with dyspnea. The most helpful measurement is the ratio of FEV₁ to VC. As noted, a reduction in this ratio to less than 70% is an indication of significant airflow limitation.

Disease severity in COPD can then be assessed by the progressive decline in the postbronchodilator FEV₁, with results compared with predicted values (Table 47-1). Crude estimates of obstruction can be provided by the FEV₁ alone. Should spirometry be unavailable, prolongation of the forced expiratory time beyond 6 seconds suggests an FEV₁/FVC ratio of less than 50%. Patients with a 50% reduction in FEV₁ are often dyspneic and hypoxemic on exertion; by the time the FEV₁ falls to 25% of the predicted value, they may note shortness of breath at rest.

Chest radiography is helpful, principally to rule out complications of COPD (e.g., pneumonia, pneumothorax) and other forms of chest disease that may present as dyspnea (e.g., heart failure, interstitial lung disease; see Chapter 40). Of the various forms of COPD, only severe emphysema is diagnosed radiologically; the criteria for radiologic diagnosis are the presence of two or more of the following findings: flattening of the diaphragm and blunting of the costophrenic angle on posterior-anterior view, irregularity of lung field lucency, enlargement of the retrosternal space, and flattening or concavity of the diaphragmatic contour on lateral view. High-resolution chest computed tomography (CT) has been shown to detect emphysema in heavy smokers who are asymptomatic and have normal chest x-rays, but evidence for clinical benefit for the use of CT in this situation is lacking, although proponents of low-dose CT scanning for lung cancer raise the question of an added benefit from such screening (sensitivity 63%, specificity 88%). The degree and pattern of emphysema within the lungs can also be assessed more precisely with chest CT than chest x-ray. However, with the exception of assessment for lung volume reduction surgery and perhaps encouraging persons to stop smoking, these findings have little effect on management decisions.

Measurement of arterial oxygen saturation and blood gases is worth considering in patients with an FEV₁ of less than 50% of the predicted value, a point at which hypoxemia is a possibility, especially in persons with chronic bronchitis. Pulse oximetry can be used as a screening test; it provides a measure of arterial oxygen saturation (SaO₂). If the SaO₂ is less than 92%, then measurement of the arterial blood gases is indicated to assess oxygenation and ventilation. Hypoxemia and hypercarbia are indications of severe chronic bronchitis. Blood gas measurement is particularly useful for documenting acute decompensation. In patients with severe chronic bronchitis (stages 3 and 4),
baseline and serial studies of blood gases should be performed so that measurements of gases obtained at times of marked subjective worsening can be compared with baseline determinations.

Hematocrit and hemoglobin concentration provide a rough indication of the severity and chronicity of hypoxemia and the possible need for phlebotomy. Measurement should be undertaken in persons with arterial oxygen pressure (PaO₂) of less than 50 mm Hg.

Electrocardiogram should be studied for sinus tachycardia, multifocal atrial tachycardia, peaked P waves (P pulmonale), and signs of right ventricular hypertrophy (e.g., tall R wave in lead V1 and deep S wave in lead V6). The electrocardiographic abnormalities that appear in COPD generally reflect the severity of lung disease and the presence of cor pulmonale.

Given that serious prognostic significance of COPD exacerbations, early identification of persons at increased risk would be helpful. As noted, the best predictor remains a prior history of an exacerbation, which should be sought. Risk also appears to correlate roughly with stage of disease, suggesting a possible benefit from repeated spirometry, but only if it will result in a change in management. Measures of inflammation such as the erythrocyte sedimentation rate, C-reactive protein, and serum fibrinogen level were found predictive in one study, a finding that needs confirmation (interestingly, the strongest predictive value in the study was for the absence of elevations in these markers, associated with the least risk of a COPD flare). Evidence that pulmonary artery enlargement (ratio of pulmonary artery diameter to aorta diameter >1.0) is an independent determinant of exacerbation risk has raised the question of CT scanning for early detection of exacerbation risk, since enlargement may predate exacerbations; evidence of benefit will be needed before such CT scanning can be recommended.

Testing for this condition remains the subject of debate, because there is no definitive evidence that diagnosis results in improved outcomes, but consensus recommendations continue to recommend its consideration, especially with occurrence of early-onset COPD or COPD in families. Testing methods include measurement of the serum or plasma concentrations of the protein, serum or plasma protein phenotyping, and genotyping. The first step is determining concentration. Reduced serum levels are suggestive of the diagnosis, but levels can be difficult to interpret because the protein is an acute-phase reactant, which may increase in the setting of inflammation. A low level is an indication for further testing, which entails protein phenotyping and genetic testing; these should be carried out with the help of expert consultation.