Interpretative strategies for lung function tests

BACKGROUND

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This section is written to provide guidance in interpreting pulmonary function tests (PFTs) to medical directors of hospital-based laboratories that perform PFTs, and physicians who are responsible for interpreting the results of PFTs most commonly ordered for clinical purposes. Specifically, this section addresses the interpretation of spirometry, bronchodilator response, carbon monoxide diffusing capacity (D_L,CO) and lung volumes.

The sources of variation in lung function testing and technical aspects of spirometry, lung volume measurements and D_L,CO measurement have been considered in other documents published in this series of Task Force reports 1–4 and in the American Thoracic Society (ATS) interpretative strategies document 5.

An interpretation begins with a review and comment on test quality. Tests that are less than optimal may still contain useful information, but interpreters should identify the problems and the direction and magnitude of the potential errors. Omitting the quality review and relying only on numerical results for clinical decision making is a common mistake, which is more easily made by those who are dependent upon computer interpretations.

Once quality has been assured, the next steps involve a series of comparisons 6 that include comparisons of test results with reference values based on healthy subjects 5, comparisons with known disease or abnormal physiological patterns (i.e. obstruction and restriction), and comparisons with self, a rather formal term for evaluating change in an individual patient. A final step in the lung function report is to answer the clinical question that prompted the test.

Poor choices made during these preparatory steps increase the risk of misclassification, i.e. a falsely negative or falsely positive interpretation for a lung function abnormality or a change in lung function. Patients whose results are near the thresholds of abnormality are at a greatest risk of misclassification.

REFERENCE EQUATIONS

TYPES OF VENTILATORY DEFECTS

COMMENTS ON INTERPRETATION AND PATTERNS OF DYSFUNCTION

The definition of an obstructive pulmonary defect given in the present document is consistent with the 1991 ATS statement on interpretation 5, but contrasts with the definitions suggested by both Global Initiative for Chronic Obstructive Lung Disease (GOLD) 59 and ATS/ERS guidelines on COPD 60, in that FEV₁ is referred to VC rather than just FVC and the cut-off value of this ratio is set at the 5th percentile of the normal distribution rather than at a fixed value of 0.7. This committee feels that the advantage of using VC in place of FVC is that the ratio of FEV₁ to VC is capable of accurately identifying more obstructive patterns than its ratio to FVC, because FVC is more dependent on flow and volume histories 61. In contrast with a fixed value of 0.7, the use of the 5th percentile does not lead to an overestimation of the ventilatory defect in older people with no history of exposure to noxious particles or gases 62.

The assumption that a decrease in major spirometric parameters, such as FEV₁, VC, FEV₁/VC and TLC, below their relevant 5th percentiles is consistent with a pulmonary defect is a useful simple approach in clinical practice. Problems arise, however, when some or all of these variables lie near their upper limits of normal or LLN. In these cases, a literal interpretation of the functional pattern is too simplistic and could fail to properly describe the functional status.

The current authors suggest that additional studies should be done in these circumstances if they are indicated by the clinical problem being addressed. Such tests could include bronchodilator response, D_L,CO, gas-exchange evaluation, measurement of respiratory muscle strength or exercise testing.

Caution is also recommended when TLC is at the LLN and coexists with a disease expected to lead to lung restriction. A typical example is lung resection. The expected restrictive defect would be difficult to prove on the simple basis of TLC as per cent of predicted if the latter remains above the 5th percentile of predicted as a result of subsequent lung growth or of a large TLC before surgery. Similar care must be taken in cases where diseases with opposing effects on TLC coexist, such as interstitial lung disease (ILD) and emphysema.

While patterns of physiological abnormalities can be recognised, they are seldom pathognomonic for a specific disease entity. The types of clinical illness most likely to produce an observed set of physiological disturbances can be pointed out. Regardless of the extent of testing, it is important to be conservative in suggesting a specific diagnosis for an underlying disease process based only on pulmonary function abnormalities.

The VC, FEV₁, FEV₁/VC ratio and TLC are the basic parameters used to properly interpret lung function (fig. 2⇓). Although FVC is often used in place of VC, it is preferable to use the largest available VC, whether obtained on inspiration (IVC), slow expiration (SVC) or forced expiration (i.e. FVC). The FVC is usually reduced more than IVC or SVC in airflow obstruction 61. The FEV₆ may be substituted for VC if the appropriate LLN for the FEV₁/FEV6 is used (from the NHANES III equations) 12, 63. Limiting primary interpretation of spirograms to VC, FEV₁ and FEV₁/VC avoids the problem of simultaneously examining a multitude of measurements to see if any abnormalities are present, a procedure leading to an inordinate number of “abnormal” tests, even among the healthiest groups in a population 64, 65. When the rate of abnormality for any single test is only 5%, the frequency of at least one abnormal test was shown to be 10% in 251 healthy subjects when the FEV₁, FVC and FEV₁/FVC ratio were examined and increased to 24% when a battery of 14 different spirometric measurements were analysed 23. It should be noted, however, that additional parameters, such as the peak expiratory flow (PEF) and maximum inspiratory flows, may assist in diagnosing extrathoracic airway obstruction.

The most important parameter for identifying an obstructive impairment in patients is the FEV₁/VC ratio. In patients with respiratory diseases, a low FEV₁/VC, even when FEV₁ is within the normal range, predicts morbidity and mortality 66. For healthy subjects, the meaning of a low FEV₁/FVC ratio accompanied by an FEV₁ within the normal range is unclear. This pattern is probably due to “dysanaptic” or unequal growth of the airways and lung parenchyma 67 (referred to in a previous ATS document as a possible physiological variant when FEV₁ was ≥100% pred 5). Whether this pattern represents airflow obstruction will depend on the prior probability of obstructive disease and possibly on the results of additional tests, such as bronchodilator response, D_L,CO, gas-exchange evaluation, and measurement of muscle strength or exercise testing. Expiratory flow measurements other than the FEV₁ and FEV₁/VC should be considered only after determining the presence and clinical severity of obstructive impairment using the basic values mentioned previously. When the FEV₁ and FEV₁/VC are within the expected range, the clinical significance of abnormalities in flow occurring late in the maximal expiratory flow–volume curve is limited. In the presence of a borderline value of FEV₁/VC, however, these tests may suggest the presence of airway obstruction. The same is true for average flows, such as mid-expiratory flow (MEF_25–75%), especially in children with cystic fibrosis 68, 69. Even with this limited use, the wide variability of these tests in healthy subjects must be taken into account in their interpretation.

The maximal voluntary ventilation (MVV) is not generally included in the set of lung function parameters necessary for diagnosis or follow-up of the pulmonary abnormalities because of its good correlation with FEV₁ 70. However, it may be of some help in clinical practice. For example, a disproportionate decrease in MVV relative to FEV₁ has been reported in neuromuscular disorders 71, 72 and UAO 73. In addition, it is also used in estimating breathing reserve during maximal exercise 74, although its application may be of limited value in mild-to-moderate COPD 75, 76. For these purposes, the current authors suggest that MVV should be measured rather than estimated by multiplying FEV₁ by a constant value, as is often done in practice.

SEVERITY CLASSIFICATION

A method of categorising the severity of lung function impairment based on the FEV₁ % pred is given in table 6⇓. It is similar to several previous documents, including GOLD 59, ATS 1986 77, ATS 1991 5, and the American Medical Association (AMA) 78. The number of categories and the exact cut-off points are arbitrary.

Severity scores are most appropriately derived from studies that relate pulmonary function test values to independent indices of performance, such as ability to work and function in daily life, morbidity and prognosis 79–82. In general, the ability to work and function in daily life is related to pulmonary function, and pulmonary function is used to rate impairment in several published systems 77–79, 83. Pulmonary function level is also associated with morbidity, and the patients with lower function have more respiratory complaints 82.

Lung function level is also associated with prognosis, including a fatal outcome from heart as well as lung disease 84, 85, even in patients who have never smoked 86. In the Framingham study, VC was a major independent predictor of cardiovascular morbidity and mortality 84, 85. In several occupational cohorts, FEV₁ and FEV₁/FVC were independent predictors of all-cause or respiratory disease mortality 87–89. In addition, a meta-analysis of mortality in six surveys in various UK working populations showed that the risk of dying from COPD was related to the FEV₁ level. In comparison to those whose FEV₁ at an initial examination was within 1 sd of average, those whose FEV₁ was >2 sd below average were 12 times more likely to die of COPD, more than 10 times as likely to die of non-neoplastic respiratory disease, and more than twice as likely to die of vascular disease over a 20-yr follow-up period 90. Although there is good evidence that FEV₁ correlates with the severity of symptoms and prognosis in many circumstances 79, 82, 90, the correlations do not allow one to accurately predict symptoms or prognosis for individual patients.

The D_L,CO is also an important predictor of mortality both in the general population 91 and in patients after pulmonary resection 92.

Though the FEV₁ % pred is generally used to grade severity in patients with obstructive, restrictive and mixed pulmonary defects, it has little applicability to patients with UAO, such as tracheal stenosis, where obstruction could be life-threatening and yet be classified as mildly reduced by this scheme. In addition, there is little data documenting the performance of other functional indexes, such as FRC in airflow obstruction or TLC in lung restriction as indices to categorise severity of impairment.

VC is reduced in relation to the extent of loss of functioning lung parenchyma in many nonobstructive lung disorders. It is also of some use in assessing respiratory muscle involvement in certain neuromuscular diseases. VC may be only slightly impaired in diffuse interstitial diseases of sufficient severity to lead to marked loss of diffusing capacity and severe blood gas abnormalities 63. The onset of a severe respiratory problem in patients with a rapidly progressive neuromuscular disease may be associated with only a small decrement in VC 47, 93.

FEV₁ and FVC may sometimes fail to properly identify the severity of ventilatory defects, especially at the very severe stage for multiple reasons. Among them are the volume history effects of the deep breath preceding the forced expiratory manoeuvre on the bronchial tone and, thus, calibre 94–98, and the inability of these parameters to detect whether tidal breathing is flow limited or not 99–102. The FEV₁/VC ratio should not be used to determine the severity of an obstructive disorder, until new research data are available. Both the FEV₁ and VC may decline with the progression of disease, and an FEV₁/VC of 0.5/1.0 indicates more impairment than one of 2.0/4.0, although the ratio of both is 50%. While the FEV₁/VC ratio should not routinely be used to determine the severity of an obstructive disorder, it may be of value when persons having genetically large lungs develop obstructive disease. In these cases, the FEV₁/VC ratio may be very low (60%), when the FEV₁ alone is within the mild category of obstruction (i.e. >70% pred).

Recent studies have stressed the importance of additional measurements in assessing the severity of the disease. For example, when airflow obstruction becomes severe, FRC, RV, TLC and RV/TLC tend to increase as a result of decreased lung elastic recoil and/or dynamic mechanisms 47, 103, 104. The degree of hyperinflation parallels the severity of airway obstruction 58. On one hand, lung hyperinflation is of benefit because it modulates airflow obstruction, but, on the other hand, it causes dyspnoea because of the increased elastic load on inspiratory muscles 47. In a recent investigation, resting lung hyperinflation, measured as inspiratory capacity (IC)/TLC, was an independent predictor of respiratory and all-cause mortality in COPD patients 105. In addition, in either severe obstructive or restrictive diseases, tidal expiratory flow often impinges on maximum flow 98, 99, 102. This condition, denoted as expiratory flow limitation during tidal breathing (EFL), is relatively easy to measure in practice by comparing tidal and forced expiratory flow–volume loops. Its clinical importance is that it contributes to increased dyspnoea 100, puts the inspiratory muscles at a mechanical disadvantage 43 and causes cardiovascular side-effects 106. Although there currently isn't sufficient evidence to recommend the routine use of measurements of hyperinflation or EFL to score the severity of lung function impairment, they may be helpful in patients with disproportionate differences between spirometric impairment and dyspnoea.

Finally, the reported increase in RV in obstruction is deemed to be a marker of airway closure 47, 103. Although its clinical relevance remains uncertain, especially with regard to assessment of severity, RV may be useful in special conditions, including predicting the likelihood of lung function improvement after lung volume-reduction surgery 104.

Table 7⇓ shows the summary of the considerations for severity classification.

BRONCHODILATOR RESPONSE

Bronchial responsiveness to bronchodilator medications is an integrated physiological response involving airway epithelium, nerves, mediators and bronchial smooth muscle. Since the within-individual difference in response to a bronchodilator is variable, the assumption that a single test of bronchodilator response is adequate to assess both the underlying airway responsiveness and the potential for therapeutic benefits of bronchodilator therapy is overly simplistic 107. Therefore, the current authors feel that the response to a bronchodilator agent can be tested either after a single dose of a bronchodilator agent in the PFT laboratory or after a clinical trial conducted over 2–8 weeks.

The correlation between bronchoconstriction and bronchodilator response is imperfect, and it is not possible to infer with certainty the presence of one from the other.

There is no consensus about the drug, dose or mode of administering a bronchodilator in the laboratory. However, when a metered dose inhaler is used, the following procedures are suggested in order to minimise differences within and between laboratories. Short-acting β₂-agonists, such as salbutamol, are recommended. Four separate doses of 100 µg should be used when given by metered dose inhaler using a spacer. Tests should be repeated after a 15-min delay. If a bronchodilator test is performed to assess the potential therapeutic benefits of a specific drug, it should be administered in the same dose and by the same route as used in clinical practice, and the delay between administration and repeated spirometric measurements should reflect the reported time of onset for that drug.

The first step in interpreting any bronchodilator test is to determine if any change greater than random variation has occurred. The per cent change in FVC and FEV₁ after bronchodilator administration in general population studies 108–110 and patient populations 101, 111–113 are summarised in table 8⇓. Studies show a tendency for the calculated bronchodilator response to increase with decreasing baseline VC or FEV₁, regardless of whether the response was considered as an absolute change or as a per cent of the initial value. Bronchodilator responses in patient-based studies are, therefore somewhat higher than those in general population studies.

There is no clear consensus about what constitutes reversibility in subjects with airflow obstruction 111, 114. In part, this is because there is no consensus on how a bronchodilator response should be expressed, the variables to be used, and, finally, the kind, dose and inhalation mode of bronchodilator agent. The three most common methods of expressing bronchodilator response are per cent of the initial spirometric value, per cent of the predicted value, and absolute change.

Expressing the change in FEV₁ and/or FVC as a per cent of predicted values has been reported to have advantages over per cent change from baseline 115. When using per cent change from baseline as the criterion, most authorities require a 12–15% increase in FEV₁ and/or FVC as necessary to define a meaningful response. Increments of <8% (or <150 mL) are likely to be within measurement variability 107, 115. The current authors recommend using the per cent change from baseline and absolute changes in FEV₁ and/or FVC in an individual subject to identify a positive bronchodilator response. Values >12% and 200 mL compared with baseline during a single testing session suggest a “significant” bronchodilatation. If the change in FEV₁ is not significant, a decrease in lung hyperinflation may indicate a significant response 101. The lack of a response to bronchodilator testing in a laboratory does not preclude a clinical response to bronchodilator therapy.

The MEF_25–75% is a highly variable spirometric test, in part because it depends on FVC, which increases with expiratory time in obstructed subjects. If FVC changes, post-bronchodilator MEF_25–75% is not comparable with that measured before the bronchodilator. Volume adjustment of MEF_25–75% has been proposed to solve this problem 116, 117. At least two studies have assessed the utility of MEF_25–75%. The results were disappointing; only 8% of asthmatics 117 and 7% of patients with COPD were identified as outside the expected range by MEF_25–75% criteria alone. Tests such as the FEV₁/VC ratio and instantaneous flows measured at some fraction of the VC may also be misleading in assessing bronchodilator response if expiratory time changes are not considered and if flows are not measured at the same volume below TLC.

If the change is above the threshold of natural variability, then the next step is to determine if this change is clinically important. This aspect of the interpretation is harder to define and depends on the reasons for undertaking the test. For instance, even if asthmatics tend to show a larger increase in flow and volume after inhaling a dilator agent than COPD patients, the response to a bronchodilator has never been shown to be capable of clearly separating the two classes of patients 101, 109, 111, 114. In addition, it must be also acknowledged that responses well below the significant thresholds may be associated with symptom improvement and patient performance 118. The possible reasons are discussed as follows.

Quite often, responses to bronchodilator therapy are unpredictably underestimated by FEV₁ and/or FVC in comparison to airway resistance or flow measured during forced expiratory manoeuvres initiated from a volume below TLC (partial expiratory flow–volume manoeuvres) in both healthy subjects and patients with chronic airflow obstruction 8, 101, 102, 119–122. These findings are probably due to the fact that deep inhalations tend to reduce airway calibre, especially after a bronchodilator 101, 120. In patients with airflow obstruction, the increase in expiratory flow after bronchodilation is often associated with a decrease in FRC or an increase in IC of similar extent at rest and during exercise 101, 123. The improvement of the lung function parameters in the tidal breathing range and not following a deep breath may explain the decrease in shortness of breath after inhaling a bronchodilator, despite no or minimal changes in FEV₁ and/or FVC. Short-term intra-individual variabilities for partial flows and IC have been reported 101. Therefore, the lack of increase of FEV₁ and/or FVC after a bronchodilator is not a good reason to avoid 1–8-week clinical trial with bronchoactive medication.

An isolated increase in FVC (>12% of control and >200 mL) not due to increased expiratory time after salbutamol is a sign of bronchodilation 124. This may, in part, be related to the fact that deep inhalations tend to reduce airway calibre and/or airway wall stiffness, especially after a bronchodilator 101, 120.

Table 9⇓ shows a summary of the suggested procedures for laboratories relating to bronchodilator response.

CENTRAL AND UPPER AIRWAY OBSTRUCTION

Central airway obstruction and UAO may occur in the extrathoracic (pharynx, larynx, and extrathoracic portion of the trachea) and intrathoracic airways (intrathoracic trachea and main bronchi). This condition does not usually lead to a decrease in FEV₁ and/or VC, but PEF can be severely affected. Therefore, an increased ratio of FEV₁ divided by PEF (mL·L⁻¹·min⁻¹) can alert the clinician to the need for an inspiratory and expiratory flow–volume loop 125. A value >8 suggests central or upper airway obstruction may be present 126. Poor initial effort can also affect this ratio.

At least three maximal and repeatable forced inspiratory and forced expiratory flow–volume curves are necessary to evaluate for central or upper airway obstruction. It is critical that the patient's inspiratory and expiratory efforts are near maximal and the technician should confirm this in the quality notes. When patient effort is good, the pattern of a repeatable plateau of forced inspiratory flow, with or without a forced expiratory plateau, suggests a variable extrathoracic central or upper airway obstruction (fig. 3⇓). Conversely, the pattern of a repeatable plateau of forced expiratory flow, along with the lack of a forced inspiratory plateau suggests a variable, intrathoracic central or upper airway obstruction. The pattern of a repeatable plateau at a similar flow in both forced inspiratory and expiratory flows suggests a fixed central or upper airway obstruction (fig. 3⇓).

In general, maximum inspiratory flow is largely decreased with an extrathoracic airway obstruction, because the pressure surrounding the airways (which is almost equal to atmospheric) cannot oppose the negative intraluminal pressure generated with the inspiratory effort. In contrast, it is little affected by an intrathoracic airway obstruction, for the pressure surrounding the intrathoracic airways (which is close to pleural pressure) strongly opposes the negative intraluminal pressure on inspiration, thus limiting the effects of the obstruction on flow. With unilateral main bronchus obstruction, a rare event, maximum inspiratory flow tends to be higher at the beginning than towards the end of the forced inspiration because of a delay in gas filling (fig. 4⇓).

Maximum expiratory flow at high lung volume (especially peak flow) is generally decreased in both intrathoracic and extrathoracic lesions 126–129. In contrast, maximum flows may be normal in the presence of a variable lesion, such as vocal cord paralysis. Flow oscillations (saw-tooth pattern) may be occasionally observed on the either inspiratory or expiratory phase, and probably represent a mechanical instability of the airway wall.

The effects of anatomical or functional lesions on maximum flows depend on the site of the obstruction, kind of lesion (variable or fixed) and the extent of anatomical obstruction 61, 127, 130. Typical cases of extra- and intrathoracic central or upper airway obstruction are reported in figures 3⇓ and 4⇓. The absence of classic spirometric patterns for central airway obstruction does not accurately predict the absence of pathology. As a result, clinicians need to maintain a high degree of suspicion for this problem, and refer suspected cases for visual inspection of the airways. The authors feel that, although maximum inspiratory and expiratory flow–volume loops are of great help to alert clinicians to the possibility of central or upper airway obstruction, endoscopic and radiological techniques are the next step to confirm the dysfunction.

The parameters presented in table 10⇓ may help to distinguish intrathoracic from extrathoracic airway obstructions.

Table 11⇓ gives a summary of the relevant issues concerning UAO.

INTERPRETATION OF CHANGE IN LUNG FUNCTION

Evaluation of an individual's change in lung function following an intervention or over time is often more clinically valuable than a single comparison with external reference (predicted) values. It is not easy to determine whether a measured change reflects a true change in pulmonary status or is only a result of test variability. All lung function measurements tend to be more variable when made weeks to months apart than when repeated at the same test session or even daily 25, 131. The short-term repeatability of tracked parameters should be measured using biological controls. This is especially important for the D_L,CO 132, 133, since small errors in measurements of inspiratory flows or exhaled gas concentrations translate into large D_L,CO errors. The variability of lung volume measurements has recently been reviewed 134.

The optimal method of expressing the short-term variability (measurement noise) is to calculate the coefficient of repeatability (CR) instead of the more popular coefficient of variation 135. Change measured for an individual patient that falls outside the CR for a given parameter may be considered significant. The CR may be expressed as an absolute value (such as 0.33 L for FEV₁ or 5 units for D_L,CO) 136 or as a percentage of the mean value (such as 11% for FEV₁) 137.

It is more likely that a real change has occurred when more than two measurements are performed over time. As shown in table 12⇓, significant changes, whether statistical or biological, vary by parameter, time period and the type of patient. When there are only two tests available to evaluate change, the large variability necessitates relatively large changes to be confident that a significant change has in fact occurred. Thus, in subjects with relatively “normal” lung function, year-to-year changes in FEV₁ over 1 yr should exceed 15% before confidence can be given to the opinion that a clinically meaningful change has occurred 5.

For tracking change, FEV₁ has the advantage of being the most repeatable lung function parameter and one that measures changes in both obstructive and restrictive types of lung disease. Two-point, short-term changes of >12% and >0.2 L in the FEV₁ are usually statistically significant and may be clinically important. Changes slightly less than these may, perhaps, be equally significant, depending on the reproducibility of the pre- and post-bronchodilator results. Other parameters such as VC, IC, TLC and D_L,CO may also be tracked in patients with ILD or severe COPD 138, 140–142. Tests like VC and FVC may be relevant to COPD because they may increase when FEV₁ does not, and changes in D_L,CO, in the absence of change in spirometry variables, may be clinically important. Again, when too many indices of lung function are tracked simultaneously, the risk of false-positive indications of change increases.

The clinician seeing the patient can often interpret results of serial tests in a useful manner, which is not reproducible by any simple algorithm. Depending on the clinical situation, statistically insignificant trends in lung function may be meaningful to the clinician. For example, seemingly stable test results may provide reassurance in a patient receiving therapy for a disease that is otherwise rapidly progressive. The same test may be very disappointing if one is treating a disorder that is expected to improve dramatically with the therapy prescribed. Conversely, a statistically significant change may be of no clinical importance to the patient. The largest errors occur in attempting to interpret serial changes in subjects without disease, because test variability will usually far exceed the true annual decline, and reliable rates of change for an individual subject cannot be calculated without prolonged follow-up 143.

Test variability can be reduced when lung function standards and guidelines are followed strictly. Simple plots (i.e. trending) of lung function with time can provide additional information to help differentiate true change in lung function from noise. Measuring decline in lung function as a means of identifying individuals (such as smokers) who are losing function at excessive rates has been proposed. However, establishing an accelerated rate of loss in an individual is very difficult, and requires many measurements over several years with meticulous quality control of the measurements.

Table 13⇓ shows a summary of the considerations involved in interpreting lung function changes.

D_L,CO INTERPRETATION

The lower 5th percentile of the reference population should be used as LLN for D_L,CO and K_CO (if the latter is used). Table 14⇓ presents a scheme to grade the severity of reductions in D_L,CO.

The pathophysiological importance of this test has been recently reviewed 144, 145.

Interpreting the D_L,CO, in conjunction with spirometry and lung volumes assessment, may assist in diagnosing the underlying disease (fig. 2⇓). For instance, normal spirometry and lung volumes associated with decreased D_L,CO may suggest anaemia, pulmonary vascular disorders, early ILD or early emphysema. In the presence of restriction, a normal D_L,CO may be consistent with chest wall or neuromuscular disorders, whereas a decrease suggests ILDs. In the presence of airflow obstruction, a decreased D_L,CO suggests emphysema 146, but airway obstruction and a low D_L,CO are also seen in lymphangioleiomyomatosis 147. Patients with ILD, sarcoidosis and pulmonary fibrosis usually have a low D_L,CO 135–137, 140. A low D_L,CO is also seen in patients with chronic pulmonary embolism, primary pulmonary hypertension 148, and other pulmonary vascular diseases. These patients may or may not also have restriction of lung volumes 149.

A high D_L,CO is associated with asthma 150, obesity 151 and intrapulmonary haemorrhage 152.

Adjustments of D_L,CO for changes in haemoglobin and carboxyhaemoglobin are important, especially in situations where patients are being monitored for possible drug toxicity, and where haemoglobin is subject to large shifts (e.g. chemotherapy for cancer).

Adjusting D_L,CO for lung volume using D_L,CO/V_A or D_L,CO/TLC is controversial 153, 154. Conceptually, a loss of D_L,CO that is much less than a loss of volume (low D_L,CO but high D_L,CO/V_A) might suggest an extraparenchymal abnormality, such as a pneumonectomy or chest wall restriction, whereas a loss of D_L,CO that is much greater than a loss of volume (low D_L,CO and low D_L,CO/V_A) might suggest parenchymal abnormalities. The relationship between D_L,CO and lung volume, however, is not linear and markedly less than 1:1, so these simple ratios as traditionally reported do not provide an appropriate way to normalise D_L,CO for lung volume 154–159. Nonlinear adjustments may be considered, but their clinical utility must be established before they can be recommended. Meanwhile, it is advisable to keep examining D_L,CO/V_A and V_A separately 153, in so far as it may provide information on disease pathophysiology that cannot be obtained from their product, the D_L,CO.

Table 15⇓ shows a summary on the considerations for D_L,CO interpretation.

ABBREVIATIONS

Table 16⇓ contains a list of abbreviations and their meanings, which have been used in this series of Task Force reports.