慢性阻塞性肺疾病患者运动能力与通气效率的相关性分析

目的:通过分析二氧化碳通气当量和运动能力的关系,探讨稳定期慢性阻塞性肺疾病(COPD)患者运动中通气效率与最大运动能力的相关性。方法:选取54例稳定期COPD患者,行运动心肺功能测试,实时监测摄氧量(VO2)、分钟通气量(VE)和二氧化碳排出量(VCO2),根据公式:EqCO2=VE/VCO2计算得出静态二氧化碳通气当量(EqCO2rest)、无氧阈时二氧化碳通气当量(EqCO2at)和最大运动状态下的二氧化碳通气当量(EqCO2max)。结果:1.EqCO2rest、EqCO2at及EqCO2max呈递减趋势,差异有统计学意义(P=0.001)。2.EqCO2at与最大摄氧量(VO2max)(r=-0.294,P<0.05)、EqCO2max与VO2max(r=-0.301,P<0.05)均呈负相关;EqCO2rest与最大摄氧量占预计值的百分比(VO2max/Pred)呈负相关(r=-0.345,P<0.05)。3.肺功能GOLD 3级患者(21例)的VO2max(15.99±3.39)mL·min-1·kg-1明显低于GOLD 2级患者(25例)的VO2max[(18.88±5.36)mL·min-1·kg-1,P=0.038]。两组的EqCO2rest、EqCO2at及EqCO2max差异无统计学意义。结论:稳定期COPD患者运动中通气效率呈进行性下降趋势,这可能是导致其运动能力下降的重要因素之一。     

运动心肺功能与慢性阻塞性肺疾病严重程度相关性分析

目的 探讨心肺运动试验(CPET)与慢性阻塞性肺疾病(COPD)GOLD分级间的相关性,明确何者为优.方法 67例稳定期COPD患者经GOLD分级后,先后进行静态肺通气功能(PFT)、CPET检测.记录FEV1%、FVC%、FEV1/FVC,CPET的最大运动功率(Wmax)、最大运功功率与预计值的比(Wmax%)、最大公斤摄氧量(VO2max)、无氧阈(VO2at AT)、氧脉(O2 Pulse)、最大呼吸频率(RRmax)、呼吸储备(BR%)、最大心率(HRmax)、心率储备(HRR)和每分钟通气量(VE).分析各参数与疾病分期之间的相关性.结果 VO2max、Wmax、O2 Pulse各期间差异有统计学意义;BR%、VE在Ⅰ、Ⅱ期间差异无统计学意义;VO2 at AT在各分期间差异无统计学意义;VO2max、O2 Pulse、VE分别与FEV1%或GOLD分期均显著相关;Wmax、VO2 at AT、BR%与FEV1%或GOLD分期均呈显著相关,而RRmax、HRmax与FEV1%或GOLD分期无相关性.运动受限原因主要有(40/67)为下肢乏力,(9/67)为气促,(7/67)为气促伴下肢乏力.结论 CPET参数与COPD的GOLD分期相关,同时CPET参数与FEV1相关性更高,单纯GOLD分期不能全面评估COPD患者疾病的严重程度,此外,CPET有助于明确运动受限原因.     

Role of inspiratory capacity on exercise tolerance in COPD patients with and without tidal expiratory flow limitation at rest.

Expiratory flow limitation promotes dynamic hyperinflation during exercise in chronic obstructive pulmonary disease (COPD) patients with a consequent reduction in inspiratory capacity (IC), limiting their exercise tolerance. Therefore, the exercise capacity of patients with tidal expiratory flow limitation (FL) at rest should depend on the magnitude of IC. The presented study was designed to evaluate the role of FL on the relationship between resting IC, other respiratory function variables and exercise performance in COPD patients. Fifty-two patients were included in the study. Negative expiratory pressure (NEP) uptake (VO2,max) were measured during an incremental symptom-limited cycle exercise. Twenty-nine patients were FL at rest. The IC was normal in all non-FL patients, while in most FL subjects it was decreased. Both WRmax and VO2,max were lower in FL patients (p<0.001, each). A close relationship of WRmax and O2,max to IC was found (r=0.73 and 0.75, respectively; p<0.0001, each). In the whole group, stepwise regression analysis selected IC and forced expiratory volume in one second (FEV1)/forced vital capacity (FVC) (% predicted) as the only significant contributors to exercise tolerance. Subgroup analysis showed that IC was the sole predictor in FL patients, and FEV1/FVC in non-FL patients. Detection of flow limitation provides useful information on the factors that influence exercise capacity in chronic obstructive pulmonary disease patients. Accordingly, in patients with flow limitation, inspiratory capacity appears as the best predictor of exercise tolerance, reflecting the presence of dynamic hyperinflation.     

Exercise capacity as a predictor of post-thoracotomy morbidity

Although severe impairment on routine pulmonary function tests will identify patients with a high post-thoracotomy morbidity, cardiopulmonary complications often develop in patients with only a mild-to-moderate impairment in pulmonary function. To determine whether the preoperative exercise capacity can prospectively identify those at risk of developing complications, 22 patients scheduled for thoracotomy (mean age, 55.7 +/- 2 yr) underwent an incremental exercise test on a cycle ergometer to determine their maximal O2 uptake (VO2max) prior to thoracotomy. Routine pulmonary function tests were performed and postoperative forced expiratory volume in one second (FEV1) was predicted from split function perfusion lung scan in all subjects. Eleven of the 22 patients had no cardiopulmonary complications postoperatively. The age, history of prior cardiovascular disease, degree of impairment on routine pulmonary function tests, and predicted postoperative FEV1 were similar in those who did and those who did not experience complications. However, those without complications had a significantly higher VO2max than did those who experienced complications (22.4 +/- 1.4 versus 14.9 +/- 0.9 ml/kg/min, p less than 0.001). Only 1 of 10 patients with a VO2max greater than 20 ml/kg/min had a complication, whereas all 6 patients with a VO2max less than 15 ml/kg/min had a complication. We conclude that exercise testing is a useful adjunct in the evaluation of operative risk for thoracotomy.     

Reduced mechanical efficiency in chronic obstructive pulmonary disease but normal peak VO2 with small muscle mass exercise

We studied six patients with chronic obstructive pulmonary disease (COPD) (FEV1 = 1.1 +/- 0.2 L, 32% of predicted) and six age- and activity level-matched control subjects while performing both maximal bicycle exercise and single leg knee-extensor exercise. Arterial and femoral venous blood sampling, thermodilution blood flow measurements, and needle biopsies allowed the assessment of muscle oxygen supply, utilization, and structure. Maximal work rates and single leg VO2max (control subjects = 0.63 +/- 0.1; patients with COPD = 0.37 +/- 0.1 L/minute) were significantly greater in the control group during bicycle exercise. During knee-extensor exercise this difference in VO2max disappeared, whereas maximal work capacity was reduced (flywheel resistance: control subjects = 923 +/- 198; patients with COPD = 612 +/- 81 g) revealing a significantly reduced mechanical efficiency (work per unit oxygen consumed) with COPD. The patients had an elevated number of less efficient type II muscle fibers, whereas muscle fiber cross-sectional areas, capillarity, and mitochondrial volume density were not different between the groups. Therefore, although metabolic capacity per se is unchanged, fiber type differences associated with COPD may account for the reduced muscular mechanical efficiency that becomes clearly apparent during knee-extensor exercise, when muscle function is no longer overshadowed by the decrement in lung function.     

Body composition analysis by dual energy X-ray absorptiometry and exercise performance in underweight patients with COPD

STUDY OBJECTIVES: The aim of this study was to examine the effect of body composition on maximal exercise performance in patients with COPD. METHODS: The study was carried out on 27 patients with COPD and was confirmed by pulmonary function testing. Body composition was measured by dual energy x-ray absorptiometry (DXA). Exercise performance was conducted on a cycle ergometer and was measured as maximal work rate (WRmax) and maximal oxygen uptake (VO2max). Bone mineral content (BMC), lean mass (LEAN), and fat mass (FAT) were assessed by DXA and were expressed as a percentage of ideal body weight, BMC, LEAN, and FAT. RESULTS: LEAN% correlated significantly with VO2max (r = 0.66, p = 0.0002) and WRmax (r = 0.70, p < 0.0001). No significant correlation was found between FAT% and exercise performance. By stepwise regression analysis, variables significantly contributing to WRmax and VO2max were LEAN% and the maximal voluntary ventilation. Total variance explained in these models was 81% for WRmax aid 82% for VO2max. CONCLUSION: Lean mass was an important determinant of maximal exercise performance in patients with COPD.     

Relationship of respiratory drives to dyspnea and exercise performance in chronic obstructive pulmonary disease

Frequently, patients with COPD with similar spirometric impairment have marked differences in dyspnea and exercise limitation. As the classic "blue bloater" with attenuated respiratory drive is described as being less dyspneic than his "pink puffer" counterpart, we wondered whether the variability in dyspnea and exercise tolerance in a group of patients with COPD with relatively similar degrees of air-flow obstruction might be partly explained by the variability in resting respiratory drives (unstimulated P0.1 and hypoxic and hypercapnic P0.1 responses). Therefore, we measured unstimulated mouth occlusion pressure (P0.1), hypoxic response (-delta P0.1/delta SaO2), hypercapnic response (delta P0.1/delta PCO2), 6-min walk distance, VO2max, steady-state exercise VE/VO2, exercise SaO2, and dyspnea using an oxygen cost diagram in 15 subjects with severe COPD (mean FEV1% 35.2 +/- 1.9 SEM). No correlations between spirometric impairment and either dyspnea or exercise performance were seen. Unstimulated P0.1 correlated inversely with spirometric impairment but did not correlate with dyspnea, VO2max or 6-min walk distance. Both hypoxic and hypercapnic responses were significantly correlated with greater exercise ventilation (VE/VO2), less exercise O2 desaturation, and a greater VO2max, but not with dyspnea or 6-min walk distance. The results of this study do not support the concept that depressed respiratory drives are associated with less dyspnea or greater exercise capability in COPD.     

Prediction of maximum exercise tolerance in patients with COPD

Exercise tolerance in patients with COPD is difficult to predict from measurements of lung function. We examined multiple physiologic and psychosocial variables in an attempt to predict exercise performance in a group of patients with COPD enrolled in a clinical trial of pulmonary rehabilitation. A total of 119 patients (FEV1 = 1.41 +/- 0.64 L) were divided randomly into either a study group (group A, n = 58) or validation group (group B, n = 61). Stepwise multiple regression in group A revealed that peak oxygen uptake (peak VO2) was predicted best by the following equation: Peak VO2 (L/min) = (0.0327 x DCO) + (0.0040 x MVV)-(0.0156 x peak-exercise VD/VT) + (0.0259 x resting VE) + 0.848; r = 0.90; SE = 0.233 L/min. This equation was then cross-validated in group B. It demonstrated excellent validity: measured peak VO2 (L/min) = (1.13 x predicted peak VO2)-0.0891; r = 0.90; SE = 0.239 L/min. We conclude that exercise tolerance was predicted reasonably well from measurements of lung function and gas exchange in this group of patients with COPD. However, the variability of the prediction would limit its usefulness in individual patients.     

Peak physiologic responses to arm and leg ergometry in male and female patients with airflow obstruction

STUDY OBJECTIVE: To investigate differences in work capacity for the arms and legs in patients with moderate-to-severe COPD. DESIGN: Cross-sectional investigation. PATIENTS: One hundred twenty-four patients (90 men and 34 women) aged 45 to 81 years with moderate-to-very severe COPD. FEV(1) ranged from 0.70 to 2.79 L/min (FVC, 1.73 to 5.77 L; FEV(1)/FVC, 24 to 69%). All patients were in stable condition at the time of testing and receiving a stable drug regime. MEASUREMENTS: Each patient completed a demographic and medical history questionnaire, pulmonary function studies (spirometry, lung volumes, and diffusion capacity), peak exercise ergometry with gas exchange for the arms and legs; they also rated their subjective assessment of perceived dyspnea and extremity fatigue using Borg scores during exercise. RESULTS: Patients were of comparable age, with men taller and heavier than women. Smoking history was significantly less for women (47.9 pack-years vs 66.6 pack-years for men) even though each group presented with equivalent age (p > 0.05). Women were less obstructed than men, with FEV(1)/FVC (mean +/- SD) of 46.5 +/- 10.9% vs 40.2 +/- 9.3%, respectively. Ventilatory limitation during exercise was noted for all patients studied. Peak work capacity was greater for men, and leg peak responses were greater than arm values for each gender. As airway obstruction increased, work capacity became more limited. Peak arm work achieved was 38.9 +/- 19.6 W, oxygen uptake (VO(2)) was 903.9 +/- 263.5 mL/min, and minute ventilation (VE) was 33.7 +/- 9.5 L. Peak leg work value was 62.9 +/- 24.8 W, VO(2) was 1,091.4 +/- 321.5 mL/min, and VE was 39.3 +/- 12.0 L. Hence, arm values were 62%, 83%, and 85% of the measured leg values, respectively. Dyspnea and extremity effort scores were similar for men and women, and for arms and legs. Regression analysis was used to derive prediction equations for arm work from measured leg ergometry testing. For watts of work, a three-variable model emerged explaining 66% of the variance; VO(2) yielded a four-variable model with 80% of the variance explained; and VE yielded a three-variable model explaining 72% of the variance. CONCLUSION: Arm work is reduced by 38% that of the legs, while more modest reductions are noted for VO(2) and VE, suggesting greater mechanical efficiency for leg work as compared to arm work. These data also suggest greater metabolic demand for respiratory muscles and arm ergometry. Dyspnea and extremity Borg scores were equivalent for each modality and level of airway obstruction studied, suggesting that perception plays an important role in limiting exercise, and that a threshold for termination of exercise may exist. Further, peak leg ergometry results can be used with pulmonary function indexes to predict peak arm workload in watts, VO(2), and VE. These data may be used to assist the clinician in prescribing rehabilitation or estimating arm exercise ability when arm testing is unavailable.     

Replacement of the 6-min walk test with maximal oxygen consumption in the BODE Index applied to patients with COPD: an equivalency study

INTRODUCTION: Patients with COPD have decreased exercise capacity and low oxygen consumption (Vo(2)) during formal cardiopulmonary exercise testing, and lower scores on health-related quality of life questionnaires. When isolated, these three variables show different correlations with COPD mortality. The multidimensional BODE (body mass index[BMI], airflow obstruction, dyspnea, and exercise capacity in COPD) index, which comprises four variables including the 6-min walk test (6MWT), predicts survival in COPD. OBJECTIVES: To evaluate the degree of association between the values of the BODE index using the 6MWT with the BODE index using maximal Vo(2) (Vo(2)max) obtained in a maximal incremental test. MATERIALS AND METHODS: Fifty patients with mild-to-severe COPD (average age, 63.5 +/- 9.9 years; FEV(1), 65.3 +/- 23.6% of predicted) [+/- SD] had BMI, spirometric function (FVC and FEV(1)), and dyspnea status (Medical Research Council) evaluated. Two BODE index scores were then completed: one with the 6MWT, and one with the Vo(2)max obtained during maximal incremental testing on a treadmill. RESULTS: Correlation between BODE index and Vo(2) in milliliters per minute per kilogram (r = - 0.41) was weak; the correlation was moderate (r = - 0.64) when Vo(2) percentage of predicted was used. The BODE index modified by replacing the 6MWT with Vo(2) showed excellent correlations with Vo(2) in milliliters per minute per kilogram (r = 0.92) and Vo(2) percentage of predicted (r = 0.95). CONCLUSION: The excellent correlation between the conventional BODE index and the modified BODE index with Vo(2) replacing the 6MWT enables us to reach the conclusion that the original BODE index is very effective in the evaluation of COPD patients.     

Unsuspected loss of lung elastic recoil in chronic persistent asthma

STUDY OBJECTIVES: To investigate the progression and mechanism(s) for fixed maximum expiratory airflow (max) limitation in patients with chronic persistent asthma. METHODS: When optimally treated and in clinically stable condition, we studied 21 asthmatic patients and classified them into three groups based on the severity of expiratory airflow limitation: (1) group A included 5 asthmatic patients (four women; mean +/- SD age, 51 +/- 17 years) with mild persistent asthma (FEV(1) > 80% predicted) with serial FEV(1) measurements obtained prior to the present study for 16 +/- 4 years; (2) group B included 11 asthmatic patients (three women; mean age, 64 +/- 11 years) with moderate persistent asthma (FEV(1) of 60 to 80% predicted) with serial FEV(1) measurements for 12 +/- 4 years; and (3) group C included 5 asthmatic patients (three women; mean age, 55 +/- 16 years) with severe persistent asthma (FEV(1) < 60% predicted) with serial FEV(1) measurements for 11 plus minus 5 years. RESULTS: Lung CT indicated no or trivial emphysema, and diffusion was normal in all asthmatics. There was a marked loss of lung elastic recoil at total lung capacity (TLC) in all asthmatic patients in group B (16 +/- 4 cm H(2)O) and group C (15 +/- 5 cm H(2)O), but none or minimal in group A (22 +/- 1 cm H(2)O) [p < 0.01], and loss of elastic recoil accounted for 34% and 50% of decreased maximal expiratory airflow (max) at 80% and 70% TLC, respectively. Comparison with previous longitudinal data indicated individual asthmatics when in clinically stable condition remained predominantly in the same FEV(1) percent predicted classification group as in the current study. CONCLUSION: Patients with chronic moderate and severe persistent asthma, despite optimal therapy, have reduced max for many years in part due to (early?) loss of lung elastic recoil from unknown mechanism(s). This challenges current concept of airway remodeling.     

Arm exercise capacity and dyspnea ratings in subjects with chronic obstructive pulmonary disease

PURPOSE: This study aimed to compare the metabolic, ventilatory, and dyspnea responses to unsupported arm exercise, supported arm exercise and leg exercise between subjects with chronic obstructive pulmonary disease (COPD) and healthy age-matched controls. METHODS: For this study, 21 subjects with COPD (mean age, 62 +/- 2 years; predicted forced expiratory volume in 1 second [FEV(1)], 37 +/- 3%) and 7 healthy age-matched control subjects (% pred FEV(1) = 109 +/- 5%) were included in the analyses of three incremental exercise tests to peak work capacity: unsupported arm exercise, supported arm exercise (arm ergometry), and leg exercise (cycle ergometry). Work level, oxygen consumption (VO(2)), minute ventilation (V(E)), dyspnea, and rate of perceived exertion were measured each minute. RESULTS: Peak work level and peak VO(2) were significantly reduced in the subjects with COPD for all exercise tests (P <.01 for all), as compared with the control subjects. Within the COPD group, the VO(2) and V(E) at peak exercise were significantly lower for unsupported arm exercise than for both the leg and supported arm exercises (both P <.001). The ratio of V(E) to maximal voluntary ventilation was high for leg exercise (96%), supported arm exercise (91%), and unsupported arm exercise (77%) among the subjects with COPD. At a given percentage of VO(2) peak, dyspnea scores were similar for all the exercise tests. CONCLUSIONS: Ventilatory constraints limit exercise performance in COPD. The lowest amount of work, in terms of VO(2,), was during unsupported arm exercise. Because the subjects with COPD had scores showing similar levels of dyspnea at the same percentage of VO(2) peak, it is suggested that patients be encouraged to reach equivalent dyspnea levels when performing unsupported and supported arm exercise training and leg training.     

Pulmonary exercise testing predicts prognosis in patients with chronic obstructive pulmonary disease

OBJECTIVE: In patients with chronic obstructive pulmonary disease (COPD), patient age and initial value of forced expiratory volume in 1 second (FEV1) have been considered the most accurate predictors of mortality among the parameters obtained from pulmonary exercise tests. However, few studies have examined the predictive variables of prognosis among exercise parameters in COPD. We therefore attempted to identify the best index for predicting long-term survival in patients with COPD among the cardiopulmonary variables obtained during exercise testing. PATIENTS AND METHODS: Fifty-eight patients with COPD (50 men and 8 women) without hypoxemia at rest or other serious complications performed resting pulmonary function tests followed by a symptom-limited ramp exercise test on a cycle ergometer with breath-by-breath gas analysis and arterial blood gas sampling. RESULTS: After 3,570+/-1,373 days follow-up (mean+/-SD), 21 died because of deaths by respiratory failure. The overall survival rates calculated by the Kaplan-Meier method were 92.9% and 75.8% at 5 years and 10 years, respectively. In univariate Cox hazards analysis, age, FEV1, VC, RV/TLC, VEmax, VO2max, VCO2max, PaO2max, PacO2max, and PaO2 at rest were found to be significant prognostic indices of survival. However, multivariate analysis revealed only FEV1, PaO2max, and age as independent predictors of mortality. In severe COPD patients (FEV1 <50% predicted, n=35), PaO2max and age also correlated with prognosis, whereas FEV1 did not. CONCLUSION: Pulmonary exercise testing is useful in predicting prognosis in patients with COPD.     

P wave height during incremental exercise in patients with chronic airway obstruction.

We examined changes in P wave height in lead 2 of an ECG obtained during progressive exercise in 23 patients with COPD, and measured both P wave changes and pulmonary hemodynamics during exercise at a constant workload corresponding to approximately 50 to 60 percent of VO2 max in nine patients. The P wave response to exercise (delta P/delta VO2, %/ml/min), estimated by the relationship between percentage of change in P wave height and VO2, was significantly greater (p less than 0.01) in 15 patients who had a decrease in PaO2 with exercise (group A) than eight patients who did not have a fall in PaO2 with exercise (group B). There was a significant negative correlation between change in PaO2 and change in P wave height from rest to maximal exercise (r = -0.68, p less than 0.001). Oxygen therapy in nine patients in group A reduced the increase in P wave height during exercise. Furthermore, change in P wave height from rest to exercise correlated significantly with that of mean pulmonary artery pressure (r = 0.75, p less than 0.01). These results suggest that increase in P wave height during exercise in COPD patients is related partly to oxygen desaturation during exercise, and continuous measurement of P wave change may be useful for noninvasively predicting the pulmonary vascular pressure response to exercise.     

Complications of lung resection and exercise capacity: a meta-analysis

RATIONALE: While exercise capacity, expressed as maximal oxygen consumption (VO2max), has been proposed to be the best predictor of postoperative cardiopulmonary complications after surgical resection in lung cancer patients, the literature remains controversial. The purpose of this study was to use the meta-analytic approach to determine if VO2max, expressed as either ml kg(-1) min(-1) or as a percentage of predicted, differed between patients who develop postoperative cardiopulmonary complications versus those that do not. METHODS: Studies were retrieved via (1) computerized literature searches, (2) cross referencing from retrieved articles, and (3) expert review of our reference list. Trials were included if they reported preoperative VO2max values (ml kg(-1) min(-1) or percentage of predicted) and had patients in which postoperative cardiopulmonary complications occurred. RESULTS: Fourteen studies representing a total of 955 men and women met our criteria for inclusion. Across all designs and categories, random-effects modeling demonstrated that patients without postoperative pulmonary complications had significantly higher levels of VO2max in ml kg(-1) min(-1) (mean difference=3.0, 95% confidence interval (CI), 1.9-4.0) as well as VO2max as a percentage of predicted (mean difference=8, 95% CI, 3.3-12.8). CONCLUSION: After a systematic review of the literature, we found that exercise capacity, expressed as VO2max, is lower in patients that develop clinically relevant complications after curative lung resection. These results are important for the practicing clinician because they answer the literature controversy on the usefulness of measuring preoperative exercise capacity and reinforce the current guidelines on decision making for lung resection.     

Exercise outcomes after pulmonary rehabilitation depend on the initial mechanism of exercise limitation among non-oxygen-dependent COPD patients

STUDY OBJECTIVES: Pulmonary rehabilitation (PR) that includes exercise training can improve exercise tolerance and quality of life for patients with COPD. However, the degree of benefit from PR is variable. We hypothesized that the exercise response to PR varies depending on the initial factors that limit exercise. DESIGN, SETTING, PARTICIPANTS, AND MEASUREMENTS: We retrospectively analyzed the change in exercise capacity after PR in 290 nonhypoxemic patients with COPD. We classified patients into the following subgroups based on the primary limitation seen on initial exercise testing: (1) ventilatory-limited (VL); (2) cardiovascular-limited (CVL); (3) mixed ventilatory/cardiovascular-limited (VLCVL); and (4) non-cardiopulmonary-limited (NL). We compared outcomes among subgroups. RESULTS: In the entire study population, PR led to increased timed walk distance (30.3%; p < 0.0001) and maximal oxygen consumption (VO2max) [84.8 mL/min; p < 0.0001]. Stepwise multiple regression selected age, ventilatory reserve at peak exercise, and exercise arterial oxygen pressure as individual predictors of improvement in VO2max. VO2max increased in the VL subgroup (30.4 mL/min; p = 0.008), the CVL subgroup (109.0 mL/min; p < 0.0001), the mixed VLCVL subgroup (61.3 mL/min; p < 0.0001), and NL subgroups (110.5 L/min; p < 0.0001). The improvement in VO2max was greater in the CVL subgroup than in the VL subgroup (p < 0.0001). Timed walk distance improved to a similar degree in all subgroups (26 to 36%). CONCLUSIONS: Patients with nonventilatory exercise limitations experience the greatest increase in VO2max after PR. However, even patients with severe ventilatory limitation can improve exercise tolerance with PR.     

Lung function and exercise performance in smoking and nonsmoking asbestos-exposed workers

Evaluation of impairment caused by exposure to an occupational toxin can be complicated by additional exposure to other injurious agents. Because cigarette smoking is common and cigarettes are implicated in obstructive lung disease and cardiovascular diseases, we assessed the contribution of smoking to functional abnormalities in a group of asbestos-exposed shipyard workers. Seventy-three workers who never smoked were paired with 73 current smokers by age and asbestos exposure. Pulmonary function and performance during cycle incremental exercise were compared between the 2 groups. Nonsmokers had significantly higher VC, FEV1, FEV1/VC, and diffusing capacity for carbon monoxide than did smokers. Only 3 of the 73 nonsmokers but 23 of the 73 smokers had a FEV1/VC below the 95% confidence limit of predicted value. The FEF25-75%, on the other hand, failed to identify additional subjects with obstruction not found by the FEV1/VC. During exercise, despite no difference in maximal heart rate, the maximal O2 uptake (VO2max) and oxygen-pulse were lower among smokers. In addition, smokers more frequently had abnormal AaPO2 at maximal exercise. Of 33 smokers who had a VO2max less than 80% of predicted, 16 were judged to have cardiac disease, whereas only 2 appeared to be limited by obstruction. Only 15 of the 73 nonsmokers had a VO2max less than 80%. We conclude that cigarette smoking was the major contributing factor to the obstructive lung disease observed in asbestos workers, and it also had a strong influence on the occurrence, nature, and magnitude of exercise limitation. The history of cigarette smoking has an important effect on the assessment of impairment from asbestos.     

Exercise responses during incremental and high intensity and low intensity steady state exercise in patients with obstructive lung disease and normal control subjects

A study was undertaken to compare the cardiac and ventilatory responses to different types of exercise between 12 patients with COPD and ten normal age-matched control subjects. Both groups attained comparable heart rates and the percentage of their maximum predicted heart rate. Patients had a higher heart rate and VE with a lower O2P at every level of work load. Patients had a mean VT which approximated their FEV1 and increased their VE predominantly by increasing their respiratory frequency. During the low intensity test, despite the differences in work load, the patients had comparable heart rates and VE. No resting spirometric value accurately predicted work load, VE, or maximal VO2. We conclude that patients have a reduced work tolerance that is not adequately explained by their reduced lung function. Thus, cardiac factors, deconditioning, and the dyspneic sensation may be determinants of exercise limitation in some patients.     

Maximum intensity exercise training in patients with chronic obstructive pulmonary disease

We studied high intensity, symptom-limited, endurance exercise training in 52 patients with COPD participating in a pulmonary rehabilitation program. The patients had moderate to severe airway obstruction and reduced exercise tolerance with ventilatory limitation. The target workload for endurance exercise testing was 95 percent of the baseline maximum treadmill work load. At training weeks 1, 4 and 8, they were training at 85, 84, and 86 percent respectively, of baseline maximum. After rehabilitation, there was an increase in maximal treadmill work load, VO2max, and endurance exercise time, and a decrease in perceived symptoms. Patients who did not reach anaerobic threshold (group 2) were able to train at a higher percentage of maximum exercise tolerance than patients who reached anaerobic threshold (group 1). The increase in exercise performance of both groups, however, was similar. We conclude that patients with moderate to severe COPD can perform exercise training successfully at intensity targets which represent higher percentages of maximum than typically recommended in normal individuals or other patients.