Dynamic Hyperinflation and Exercise Intolerance in Chronic Obstructive Pulmonary Disease

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Dynamic Hyperinflation and Exercise Intolerance in Chronic Obstructive Pulmonary Disease

DENIS E. O'DONNELL, SUSAN M. REVILL, and KATHERINE A. WEBB

Respiratory Investigation Unit, Department of Medicine, Queen's University, Kingston, Ontario, Canada

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

The role of dynamic hyperinflation (DH) in exercise limitation in chronic obstructive pulmonary disease (COPD) remains tobe defined. We examined DH during exercise in 105 patients withCOPD (FEV₁ = 37 ± 13% predicted; mean ± SD) and studied the relationshipsbetween resting lung volumes, DH during exercise, and peak oxygenconsumption ( $V$ O₂). Patients completed pulmonary function testsand incremental cycle exercise tests. We measured the change ininspiratory capacity ( $Delta$ IC) during exercise to reflect changesin DH. During exercise, 80% of patients showed significant DHabove resting values. IC decreased 0.37 ± 0.39 L or 14 ± 15% predictedduring exercise (p < 0.0005), but with large variation in range. $Delta$ IC correlated best with resting IC, both expressed %predicted(r = $-$ 0.50, p < 0.0005). Peak $V$ O₂ (%predicted maximum) correlatedbest with the peak tidal volume attained (VT standardized as %of predicted vital capacity) (r = 0.68, p < 0.0005), which, inturn, correlated strongly with IC at peak exercise (r = 0.79,p < 0.0005) or at rest (r = 0.75, p < 0.0005). The extent of DHduring exercise in COPD correlated best with resting IC. DH curtailedthe VT response to exercise. This inability to expand VT in responseto increasing metabolic demand contributed importantly to exerciseintolerance inCOPD.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Keywords: COPD; exercise; inspiratory capacity; dynamic lung hyperinflation; emphysema; dyspnea

Chronic obstructive pulmonary disease (COPD) is a heterogeneous disorder characterized by dysfunction of the small and largeairways, as well as destruction of the lung parenchyma and itsvasculature in highly variable combinations. The pathophysiologicalhallmark of COPD is expiratory flow limitation, which, in moreadvanced disease, occurs even during resting quiet breathing.As a consequence, resting lung volume (functional residual capacity[FRC]) is dynamically, and not statically, determined. Duringexercise, as ventilatory demands increase in flow-limited patients,progressive air trapping and further dynamic lung hyperinflation(DH) above already increased resting values is inevitable (1,2). Recent studies have shown that DH during exercise contributesto perceived respiratory discomfort (3, 4). Indirect evidenceof the importance of DH comes from studies that have demonstratedthat alleviation of dyspnea following bronchodilator therapy andlung volume reduction surgery (LVRS) was explained, in part, byreduced operating lung volumes (5, 6). However, it is notclear from previous studies to what extent the behavior of operatinglung volumes during exercise influences peak exercise capacityin COPD. Moreover, earlier studies have shown wide variabilityin the extent of DH with exercise and the factors that determinethis variability have not been elucidated (3).

We hypothesized that DH and the consequent restrictive constraints on volume expansion during exercise would contribute importantlyto reduced exercise performance in COPD. Although volume constraintsare, by no means, an exclusive source of ventilatory limitationin COPD, they are likely to be important. They contribute to exertionaldyspnea and influence breathing pattern responses during exercise.Furthermore, the operating lung volumes determine, in part, themagnitude of fractional inspiratory muscle force generation (relativeto maximum). High inflation volumes may also affect cardiac performanceand, thus, peripheral muscle function during exercise inCOPD.

Therefore, the objectives of this study were (1) to determine the range and pattern of change in the various operating lungvolume components during incremental exercise in a large COPDpopulation; (2) to examine factors contributing to the intersubjectvariability in DH during exercise; (3) to examine the relationshipbetween resting hyperinflation, further DH during exercise, andsymptom limited peak $V$ O₂; and (4 ) to compare operating lungvolumes and exercise performance in a subgroup of patients witha more "emphysematous" clinical profile with patients who werematched for FEV₁ but with a better preserved diffusioncapacity.

We conducted incremental cardiopulmonary cycle exercise testing in 105 clinically stable patients with COPD and 25 healthyage-matched control subjects. We measured and compared ventilation,breathing pattern, operating lung volumes, metabolic factors,and exertional symptoms. We evaluated dynamic changes in end-expiratorylung volume (EELV) from resting FRC by collecting serial inspiratorycapacity (IC) measurements throughout exercise, having establishedthe reliability of this measurement in a previous study (7).

	METHODS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Subjects

We studied 105 clinically stable patients with COPD (FEV₁ < 70% predicted, FEV₁/FVC < 70%). Exclusion criteria included ahistory of asthma, atopy, or nasal polyps; other active lung disease;significant disease that could contribute to dyspnea or exerciselimitation; and oxygen desaturation to < 75% during exercise onroom air. Twenty-five age-matched (> 50 yr), healthy subjectswere alsostudied.

Study Design

COPD subjects included patients who had performed pulmonary function tests (PFTs) and an incremental cycle exercise test duringassessment before pulmonary rehabilitation or as part of screeningprior to entering various clinical research studies. Healthy normalsubjects were recruited from the local community to perform spirometryand incremental cycle exercise tests for comparison of the behaviorof operational lung volumes duringexercise.

All subjects signed written informed consent at the time of their first assessments and were aware that their test data mightbe used in future analyses. Subjects were familiarized with allprocedures prior to collection of the test results evaluated inthisstudy.

Procedures

Spirometry, body plethysmography, single-breath diffusing capacity (DL_CO), and maximal inspiratory mouth occlusion pressure(MIP) were performed as previously described (8) (see onlinedata supplement). Chronic dyspnea was assessed using the modifiedBaseline Dyspnea Index (9).

Symptom-limited incremental cycle exercise tests were conducted as previously described (8) (see online data supplement).Subjects breathed through a mouthpiece with noseclips in place.In the majority of subjects (COPD n = 74, normal subjects n =20), flow signals were sampled at 100 Hz using computer-baseddata acquisition software (CODAS; Dataq Instruments Inc., Akron,OH), from which breath-by-breath measurements of volume, flow,and timing were calculated. In these subjects, expired air channelledthrough a 10-L mixing chamber was analyzed for fraction of O₂(S-3A Oyxgen Analyzer; Applied Electrochemistry, Pasadena, CA)and CO₂ (LB-2 Gas Analyzer; SensorMedics, Anaheim, CA). In allremaining subjects, breath-by-breath measurements were collectedusing a Vmax229d Cardiopulmonary Exercise Testing Instrument (SensorMedics,Yorba Linda, CA). Electrocardiography and pulse oximetry weremonitored continuously. Blood pressure was auscultated at rest,each stage of exercise, peak exercise, and recovery. The modifiedBorg Scale (10) was used to rate intensity of dyspnea (i.e.,"breathing discomfort") and leg discomfort at rest, each stageof exercise, and peak exercise. Subjects also specified why theystoppedexercise.

Statistical Analysis

Results are means ± SD. COPD subgroup comparisons using unpaired Student's t tests included (1) patients who had an emphysematousprofile with DL_CO $=<$ 50% predicted and FRC $>=$ 130% predicted (GroupA), versus patients with DL_CO > 50% predicted and FRC < 130% predicted(Group B); (2) patients stopping primarily due to breathing discomfortversus leg discomfort; and (3) patients with different patternsof DH withexercise.

Relationships between exercise capacity, exertional dyspnea, and operational lung volumes in COPD were evaluated using Pearson'scorrelations. Stepwise multiple regression analysis establishedthe best predictive equations for peak $V$ O₂, Borg ratings of dyspnea,and DH (dependent variables). Independent variables included standardizedexercise measurements of minute ventilation ( $V$ E), breathing pattern(F, VT, TI, TE, TI/Ttot), gas exchange ( $V$ CO₂/ $V$ O₂, Sp_O₂), volumeconstraints (IC, IRV, VT/IC, EELV, EILV), and DH (change in IC),as well as resting pulmonary function and lung volume measurements(expressed as % of predictednormal).

	RESULTS

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

Subject Characteristics

Subject characteristics are summarized in Table 1. In the COPD group as a whole, there was a wide range of airflow obstruction(FEV₁ from 12 to 68% predicted), lung hyperinflation (plethysmographicFRC from 94 to 307% predicted), diffusing capacity (DL_CO from16 to 121% predicted), and chronic activity-related dyspnea (modifiedBaseline Dyspnea Index focal scores from 2 "very severe" to 9"mild"). The healthy control subjects had normal spirometry andwere well matched for age, sex, and body mass index.

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TABLE 1

SUBJECT CHARACTERISTICS^*

The majority of patients with COPD (80%) stopped exercise due to severe breathing discomfort, either alone or in combinationwith leg discomfort, at a low peak oxygen consumption ( $V$ O₂) (Table2, Figure 1). In contrast, the majority of normal subjects (76%)stopped exercise primarily because of leg discomfort. Comparedwith normal subjects during exercise, patients with COPD had significantlygreater ventilatory slopes ( $V$ E/ $V$ CO₂) and reduced ventilatoryreserve at end exercise. In this latter regard, peak $V$ E expressedas a percentage of maximal ventilatory capacity (MVC estimatedas 40 × FEV₁) was 92 ± 31% versus 64 ± 22% in patients with COPDand normal subjects, respectively (p < 0.0005). Also of note,the exercise breathing pattern was significantly more rapid andshallow in patients with COPD than in normal subjects.

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TABLE 2

SYMPTOM-LIMITED INCREMENTAL CYCLE EXERCISE

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Figure 1. Inspiratory capacity (IC) measurements expressed as liters or as a % of predicted normal in 105 patients with COPD and a healthy age-matched normal control group (n = 25) for a given ventilation during exercise. Predicted normal IC was calculated as predicted normal TLC minus predicted normal FRC. Values shown are means (solid lines) ± 95% confidence interval (dotted lines).

The patients with COPD who stopped exercise primarily due to breathing discomfort (n = 64) had significantly greater restingairflow limitation (i.e., decreased FEV₁) and thoracic hyperinflation(i.e., increased FRC with reduced IC) than those who stopped primarilydue to leg discomfort (n = 19) (Table 3). Those limited by dyspneaalso had greater impairment in dynamic mechanics during exercise,that is, significantly reduced IC and IRV, increased EILV/TLCand VT/IC, and less VT expansion during exercise (Table 3).

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TABLE 3

COPD SUBGROUPS: (1) GROUP A VERSUS GROUP B, (2) DYSPNEA VERSUS LEG LIMITED

Measurements of Operational Lung Volumes

There are no current equations for predicting normal spirometric IC values, therefore, a predicted normal value for IC wascalculated as predicted TLC minus predicted FRC. In our normalsample, mean resting IC was 3.11 ± 1.13 L or 110 ± 32% predicted;the latter value indicates that this method of calculating a predictednormal value for IC was reasonable, or possibly an underestimation,in this older population. In the COPD sample, mean resting ICwas significantly reduced at 1.89 ± 0.72 L or 69 ± 23% predicted,with measurements as low as 0.74 L or 23% predicted. The 95% CIfor resting IC measurements was ± 0.14 L or ± 4.5% predicted withinthe COPD group, indicating that a reproducibility criteria ofwithin 150 ml, or approximately 10%, may be appropriate for testingIC in this population. The 95% CI for peak IC was similar at ±0.12 L or ± 3.9%predicted.

During exercise in COPD, IC decreased significantly by 0.37 ± 0.39 L (p < 0.0005), with the change ( $Delta$ ) in IC ranging between $-$ 1.42 and +0.77 L (Figures 1 and 2): this corresponds to a mean $Delta$ IC of 18 ± 19% or 14 ± 15% predicted. On average, the reductionin IC occurred progressively throughout exercise, with $Delta$ IC/ $Delta$ $V$ Eduring the first 2-3 min of exercise matching the $Delta$ IC/ $Delta$ $V$ E inthe later stages of exercise. In contrast to COPD, there was nosignificant change in IC from rest to peak exercise in the normalgroup ( $Delta$ IC = 0.17 ± 0.46 L or 4 ± 14% predicted), although $Delta$ ICranged between $-$ 0.56 and +1.14 L (Figures 1 and 2). Whereas 80%of patients with COPD significantly decreased IC during exercise(i.e., outside the 95% confidence limits or > 4.5% predicted),the majority of our older normal subjects either increased (40%of subjects) or did not change (40% of subjects) IC during exercise.

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Figure 2. The distribution of the extent of change ( $Delta$ ) in IC during exercise is shown in patients with COPD (n = 105) and in age-matched normal subjects (n = 25). A negative $Delta$ IC reflects dynamic hyperinflation (DH) during exercise; each bar width corresponds to a $Delta$ IC range of 0.10 L. In contrast to normal subjects, the majority of patients with COPD experienced significant DH during exercise despite reaching a much lower peak ventilation, that is, 33 versus 64 L/min in patients with COPD and normal subjects, respectively.

In COPD, the VT response to exercise was limited from both above (i.e., the TLC envelope) and below (i.e., due to a reducedIC, which decreased even further as ventilation increased) (Figure3). At the peak of symptom-limited exercise, patients breathedwith a tidal end-inspiratory lung volume (EILV) that approached,but never quite reached, their TLC. We defined this upper volumeboundary as the "minimal IRV" that could be achieved during exercise,and set its level at the lower 95% confidence limit for peak IRVin this COPD group (i.e., 0.35 L or 5.9% of the predicted TLC).Over half of our patients with COPD reached a "minimal IRV" $=<$ 5.9% predicted TLC (n = 56), with 15 of these patients still havingapparent ventilatory reserve by traditional estimates (i.e., peak $V$ E/MVC < 75%).

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Figure 3. Changes in operational lung volumes are shown as ventilation increases with exercise in patients with COPD and in normal subjects. "Restrictive" constraints on tidal volume (VT, solid area) expansion during exercise are significantly greater in the COPD group from both below (reduced IC) and above (minimal IRV, open area).

Volume constraints on VT expansion were significantly less in normal subjects than in patients with COPD at a standardized $V$ E during exercise (Table 2). Even at the end of exercise innormals, IRV did not reach the same minimal level as it did inCOPD (Table 2 and Figure 3).

Increased versus No Change in DH during Exercise in COPD

Of the 84 patients who decreased IC during exercise outside the 95% CI at rest, 62 decreased IC by at least 10% predicted.This latter subgroup (DH subgroup) was compared with the subgroupof 14 patients who did not change IC during exercise ( $Delta$ IC within± 4.5% predicted). These subgroups had similar mean baseline FEV₁%predicted, FRC %predicted, and DL_CO %predicted. Although bothsubgroups reached a similar peak IC %predicted (and VT/%predictedVC), patients who did not change IC during exercise tended tohave greater volume constraints at rest, that is, smaller IC (p= 0.06) and IRV (p = 0.08).

Reduced DL_CO (Group A) versus Preserved DL_CO (Group B)

As selected, Group A (n = 24) had significantly greater baseline lung hyperinflation and a greater reduction in diffusingcapacity than Group B (n = 24) (Table 3). These subgroups werewell matched for age, sex, height, and body mass index, but GroupA had greater exercise impairment due to exertional dyspnea thanGroup B (Figure 4). Although the overall extent of change in ICduring exercise was similar in both subgroups, Group A had a significantlygreater rate of DH, which occurred in the early stages of exercise,than Group B. Therefore, Group A had an earlier attainment ofa limiting mechanical restriction (i.e., minimal IRV) resultingin a reduced peak $V$ O₂ (Table 3 and Figure 4).

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Figure 4. Ventilatory responses to exercise are shown in COPD (n = 105) and its subgroups: A with a low DL_CO < 50% predicted (n = 24), and B with a better preserved DL_CO > 50% predicted (n = 24). Group A had significantly (p < 0.05) greater exertional dyspnea, greater levels of lung hyperinflation, and earlier attainment of a limiting mechanical restriction (i.e., minimal IRV, shaded area) than Group B.

Correlates of Dynamic Hyperinflation in COPD

The total extent of change in IC (%predicted) during exercise was determined primarily by resting volume constraints, thatis, IC expressed as %predicted (r = $-$ 0.503, p < 0.0005) and IRVexpressed as % of predicted TLC (r = $-$ 0.497, p < 0.0005). By stepwisemultiple regression analysis, the FEF_50% and DL_CO (both expressedas %predicted) added an additional 8% to the variance in $Delta$ IC %predicted(p < 0.05each).

The rate of change in IC during exercise (slope of IC %predicted over $V$ O₂ %predicted maximum) correlated best with DL/VA%predicted (r = 0.412, p < 0.005). Comparison of subgroups bestillustrates this model: the subgroup with a reduced DL_CO had asignificantly faster rate of DH, occurring early in exercise,than those with a preserved DL_CO (Group A versus B, p < 0.05)(Figure 4).

Correlates of Exercise Capacity in COPD

In COPD, the best physiological correlate of peak $V$ O₂ (expressed %predicted maximum) was the peak VT (standardized as %predictedVC) (r = 0.682, p < 0.0005) (Figure 5 and Table 4). By stepwisemultiple regression analysis, peak $V$ O₂ %predicted was best describedby the combination of peak VT/%predicted VC, peak F, and the slopeof $V$ E/ $V$ O₂ %predicted (r² = 0.816, p < 0.0005). Within each of the COPD subgroups (seeabove), peak VT continued to be the best correlate of peak $V$ O₂(p < 0.0005 each). In turn, peak VT was determined primarily bythe peak IC (r = 0.791, p < 0.0005) (Figure 5) or the restingIC (r = 0.745, p < 0.0005), both expressed as %predicted. As seenin Figure 5, the relationship between peak VT and peak IC wasstrong in the 85 patients with an IC < 70% predicted (r = 0.866,p < 0.0005), but was not significant within the 20 patients witha preserved IC (r = 0.273, p = 0.244). Finally, an index of themechanical constraints on tidal volume expansion (VT/IC) as exerciseprogressed was the best correlate of concurrent estimates of thelevel of ventilatory limitation ( $V$ E/MVC), and accounted for 43%of its variance after accounting for repeated measurements withinpatients (p < 0.0005).

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Figure 5. In COPD (n = 105), the best correlate of peak oxygen consumption ( $V$ O₂) was the peak tidal volume attained (VT standardized as %predicted vital capacity). In turn, the strongest correlate of peak VT was the peak inspiratory capacity (IC).

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TABLE 4

CORRELATIONS WITH SYMPTOM-LIMITED PEAK $V$ O₂ (%PREDICTED MAXIMUM) IN COPD (n = 105)

Correlates of Exertional Dyspnea in COPD

The strongest correlate of exertional dyspnea intensity was an index of the concurrent constraints on tidal volume: for allpoints during exercise, after accounting for repeated measurementswithin patients, the VT/IC ratio accounted for 32% (p < 0.0005)of the variance in concurrent Borg dyspnea ratings. Less importantcontributing variables included $V$ E/MVC, breathing frequency,and IRV/predicted TLC, each accounting for 25% of the variancein Borg dyspnea ratings (p < 0.0005).

	DISCUSSION

TOP ABSTRACT INTRODUCTION METHODS RESULTS DISCUSSION REFERENCES

The novel findings of this study are as follows. (1) Although the pattern and magnitude of DH was variable among COPD patientsduring exercise, the majority (80%) demonstrated significant dynamicincreases in lung volumes above resting values. (2) The extentof DH during exercise varied inversely with the level of restinghyperinflation. (3) For a given level of airway obstruction, patientswith a more emphysematous clinical profile (low DL_CO) had fasterrates of DH, greater constraints on tidal volume expansion duringexercise, greater dyspnea, and a lower peak $V$ O₂. (4) Finally,there was a clear statistical association between the level ofresting and dynamic hyperinflation, the degree of tidal volumerestriction (i.e., peak VT) during exercise, and peak exerciseperformance.

Operational Lung Volumes during Exercise in COPD

Serial IC measurements have been used to track dynamic EELV during exercise for more than 30 yr (2, 3, 11, 21).This approach is based on the assumption that TLC does not changeappreciably during exercise in COPD, and that reductions in dynamicIC must therefore reflect increases in dynamic EELV (or FRC) (11).However, regardless of any possible changes in TLC with exercise,progressive reduction of an already diminished resting IC meansthat VT becomes positioned closer to the actual TLC and the upperalinear extreme of the respiratory system's pressure-volume relationship,where there is increased elastic loading of the inspiratory muscles(1). The reduction of IC as exercise progresses is likely atrue reflection of shifts in EELV, rather than simply the inabilityto generate maximum effort because of dyspnea or functional muscleweakness. In fact, several studies have established that dyspneicpatients, even at the end of exhaustive exercise, are capableof generating maximal inspiratory efforts as assessed by peakinspiratory esophageal pressures (4, 13). Moreover, we haverecently shown that exercise IC measurements are both highly reproducibleand responsive in patients with severe COPD, provided due attentionis taken with their measurement (7).

Pattern and Magnitude of DH in COPD

This is the first large study to document dynamic volume components during incremental exercise in COPD. Although, in absoluteterms, a mean reduction in IC of 0.37 L seems small, this representsa significant further reduction of an already diminished baselinevalue. In the COPD group, the mean change in IC with exercisewas well beyond the within-group 95% confidence interval for theresting IC measurement (i.e., ± 0.14 L or ± 4.5% of the predictednormal value) (Figure 2).

The extent of DH from rest to the peak of exercise was variable between patients (Figure 2). The change in IC correlated bestwith the resting IC (or IRV): those with the greatest IC (or IRV)reduction at rest tended to have smaller changes in both EELVand EILV with exercise (Figures 1 and 2). After accounting forthe resting IC, the maximal mid expiratory flow rate also contributedto the variance in DH: those with higher expiratory flows availableover the tidal volume operating ranges tended to have less DH.Not surprisingly, this was a weak correlation because the measurementof forced expiratory flow rates, which is prone to measurementartifact (gas and airway compression effects), is a very crudeindex of the extent of expiratory flow limitation, which is likelythe crucial determinant of DH during exercise inCOPD.

Of interest, the rate of change in DH correlated inversely with resting diffusion capacity (DL_CO/VA). Patients with a lowerDL_CO would be expected to have a greater propensity to expiratoryflow limitation because of reduced lung recoil and airway tetheringeffects. We have previously reported that patients with COPD anda lower DL_CO (an average of 32% predicted) had greater chronicactivity-related dyspnea and poorer exercise performance thanpatients with a similar FEV₁ but with an average DL_CO of 65% predicted(24). In this study we further explored the mechanistic linkbetween low DL_CO and poor exercise performance. Thus, patientswith a lower DL_CO (Group A) had greater resting hyperinflation,greater rates of DH at lower exercise levels, greater exertionaldyspnea, earlier attainment of critical volume constraints, acceleratedbreathing frequency, and a lower peak $V$ E and peak $V$ O₂ than patientswith a better preserved DL_CO (Group B) (Figure 3).

Operational Lung Volumes and Exercise Intolerance

Several recent studies have confirmed that exercise intolerance in COPD is multifactorial and ultimately reflects integratedabnormalities of the ventilatory, cardiovascular, peripheral muscle,and metabolic systems in variable combinations (18, 25). Inour study patients in whom dyspnea was the main symptom limitingexercise (61% of patients), ventilatory factors played a predominantrole in exercise curtailment. Those who stopped primarily becauseof leg discomfort had significantly less ventilatory constraintsat peak exercise. A recent study by Diaz and coworkers (25)has shown that the resting IC %predicted correlated well withsymptom-limited peak $V$ O₂. The present study extends these findingsto highlight the importance of ventilatory restriction duringexercise in flow-limitedpatients.

Compared with age-matched healthy control subjects at a similar low level of ventilation, IC and IRV were markedly diminishedin the COPD group. At this point of comparison, VT/IC ratios inCOPD and in health were 74% and 52%, respectively (Table 2).These patients with COPD, therefore, had a very limited abilityto further expand VT in the face of the increasing metabolic demandof continued exercise. The resting IC (not the VC) and, in particular,the dynamic IC with exercise, represent the true operating limitsfor VT expansion in any given patient. When the VT during exerciseapproximated the peak IC, or the dynamic EILV encroached on theTLC envelope, further volume expansion was impossible, even ifit were possible to further increase inspiratory muscleeffort.

In a multiple regression analysis with symptom-limited peak $V$ O₂ as the dependent variable, and several relevant physiologicalmeasurements as independent variables, including FEV₁, FEV₁/FVCratio, and $V$ E/MVC, peak VT emerged as the strongest contributoryvariable, explaining 47% of the variance. Peak VT, in turn, correlatedstrongly with both the resting and peak dynamic IC. It is noteworthythat this correlation was particularly strong (r = 0.9) in approximately80% of the sample who had a diminished peak IC (i.e., < 70% predicted).Similarly, the intensity of breathlessness throughout exercisecorrelated better with concurrent measurements of VT/IC (p < 0.0005)than any other ventilatory variable. We can conclude, therefore,that volume constraints contribute importantly to both exerciseintolerance and dyspnea in patients withCOPD.

Previous small studies provide a basis for a possible mechanistic link between lung hyperinflation, volume restriction, andexercise intolerance in COPD (2, 21). The greater the increasesin dynamic lung volume components during exercise, the greaterthe elastic and threshold loads on inspiratory muscles alreadyburdened with increased resistive work. With progressive DH, inspiratorymuscles become functionally weakened. This combination of increasedloading and reduced strength means that the inspiratory musclesare operating at a high fraction of their maximal force-generatingcapacity during tidal breathing. The constrained VT response meansa greater reliance on tachypnea to increase ventilation, but thisrebounds to further aggravate DH in a vicious cycle. Progressivevolume restriction in the face of increasing inspiratory effortduring exercise ultimately reflects neuromechanical uncouplingof the respiratory pump, which, in turn, may contribute to thequality and intensity of exertional dyspnea that these patientsexperience (4).

The reduced peak VT, as a result of a reduced IC, has similarly been shown to correlate strongly with poor exercise performancein patients with ventilatory restriction due to interstitial lungdisease (33), as well as in normal healthy subjects where chestwall restriction was imposed (34). The contention that restrictivemechanics, secondary to lung hyperinflation, contribute to exerciseintolerance in severe COPD is bolstered by recent interventivestudies (i.e., bronchodilators and oxygen therapy) that show thatreduction of resting and/or exercise lung volumes improves exerciseendurance in severe COPD (5, 7, 35).

Traditionally, assessment of breathing reserve (i.e., 1 $-$ $V$ E/ MVC ratio) has been used to assess ventilatory limitation toexercise in COPD. This study shows that additional measurementsof dynamic lung volumes during exercise provide insights intothe nature of the critical ventilatory constraints on exerciseperformance. There was a strong correlation between the $V$ E/MVCand the VT/IC ratio during exercise (p < 0.0005). However, a full14% of patients with apparent ventilatory reserve at peak exercise(i.e., $V$ E/MVC < 75%) had coexisting limiting restrictive ventilatoryconstraints as indicated by an EILV of 96% of TLC (i.e., a significantlyreduced peak IRV) at the same timepoint.

In summary, the inability to further expand VT in response to the increased respiratory drive of exercise contributes importantlyto exercise intolerance in patients with moderate to severe COPD.The main clinical implication of our findings is that exerciseperformance and dyspnea should be improved by therapeutic interventionsthat reduce operational lung volumes at rest and during exercisein severe COPD. Measurement of IC and its derived volume componentsduring exercise complement the traditional assessments of ventilatoryconstraints and can provide additional insight into the impairment-disabilityinterface in patients withCOPD.

	Footnotes

Correspondence and requests for reprints should be addressed to Dr. Denis O'Donnell, Richardson House, 102 Stuart Street, c/o Kingston General Hospital, Kingston, ON, K7L 2V7 Canada. E-mail: odonnell{at}post.queensu.ca

(Received in original form December 26, 2000 and in revised form May 8, 2001).

This article has an online data supplement, which is accessible from this issue's table of contents online at www.atsjournals.org

Acknowledgments: Supported by the Ontario Thoracic Society and the Ontario Ministry ofHealth.

References

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

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