Effects of rehabilitative exercise on peripheral muscle TNFalpha, IL-6, IGF-I and MyoD expression in patients with COPD.

BACKGROUND: Skeletal muscle wasting commonly occurs in patients with chronic obstructive pulmonary disease (COPD) and has been associated with the presence of systemic inflammation. This study investigated whether rehabilitative exercise training decreases the levels of systemic or local muscle inflammation or reverses the abnormalities associated with muscle deconditioning. METHODS: Fifteen patients with COPD (mean (SE) forced expiratory volume in 1 s 36 (4)% predicted) undertook high-intensity exercise training 3 days/week for 10 weeks. Before and after the training programme the concentration of tumour necrosis factor alpha (TNFalpha), interleukin-6 (IL-6) and C-reactive protein (CRP) in plasma was determined by ELISA, and vastus lateralis mRNA expression of TNFalpha, IL-6, total insulin-like growth factor-I (IGF-I) and its isoform mechanogrowth factor (MGF) and myogenic differentiation factor D (MyoD) were assessed by real-time PCR. Protein levels of TNFalpha, IGF-I and MyoD were measured by Western blotting. RESULTS: Rehabilitation improved peak exercise work rate by 10 (2%) (p = 0.004) and mean fibre cross-sectional area from 4061 (254) microm(2) to 4581 (241) microm(2) (p = 0.001). Plasma inflammatory mediators and vastus lateralis expression of TNFalpha and IL-6 were not significantly modified by training. In contrast, there was a significant increase in mRNA expression of IGF-I (by 67 (22)%; p = 0.044), MGF (by 67 (15)%; p = 0.002) and MyoD (by 116 (30)%; p = 0.001). The increase observed at the mRNA level was also seen at the protein level for IGF-I (by 72 (36)%; p = 0.046) and MyoD (by 67 (21)%; p = 0.012). CONCLUSIONS: Pulmonary rehabilitation can induce peripheral muscle adaptations and modifications in factors regulating skeletal muscle hypertrophy and regeneration without decreasing the levels of systemic or local muscle inflammation.

Effects of hypoxia on diaphragmatic fatigue in highly trained athletes.

Previous work suggests that exercise-induced arterial hypoxaemia (EIAH), causing only moderate arterial oxygen desaturation (SaO2 : 92 +/- 1%), does not exaggerate diaphragmatic fatigue exhibited by highly trained endurance athletes. Since changes in arterial O2 tension have a significant effect on the rate of development of locomotor muscle fatigue during strenuous exercise, the present study investigated whether hypoxia superimposed on EIAH exacerbates the exercise-induced diaphragmatic fatigue in these athletes. Eight trained cyclists (VO2max : 67.0 +/- 2.6 ml kg(-1) min(-1); mean +/- S.E.M.) completed in balanced order four 5 min exercise tests leading to different levels of end-exercise SaO2 (64 +/- 2, 83 +/- 1, 91 +/- 1 and 96 +/- 1%) via variations in inspired O2 fraction (FiO2 : 0.13, 0.17, 0.21 and 0.26, respectively). Measurements were made at corresponding intensities (65 +/- 3, 80 +/- 3, 85 +/- 3 and 90 +/- 3% of normoxic maximal work rate, respectively) in order to produce the same tidal volume, breathing frequency and respiratory muscle load at each FiO2. The mean pressure time product of the diaphragm did not differ across the four exercise tests and ranged between 312 +/- 28 and 382 +/- 22 cmH2O s min(-1). Ten minutes into recovery, twitch transdiaphragmatic pressure (P(di,tw)) determined by bilateral phrenic nerve stimulation, was significantly (P = 0.0001) reduced after all tests. After both hypoxic tests (FiO2 : 0.13, 0.17) the degree of fall in P(di,tw) (by 26.9 +/- 2.7 and 27.4 +/- 2.6%, respectively) was significantly greater (P < 0.05) than after the normoxic test (by 20.1 +/- 3.4%). The greater amount of diaphragmatic fatigue in hypoxia at lower leg work rates (presumably requiring smaller leg blood flow compared with normoxia at higher leg work rates), suggests that when ventilatory muscle load is similar between normoxia and hypoxia, hypoxia exaggerates diaphragmatic fatigue in spite of potentially greater respiratory muscle blood flow availability.

Effects of exercise-induced arterial hypoxaemia and work rate on diaphragmatic fatigue in highly trained endurance athletes.

Diaphragmatic fatigue occurs in highly trained athletes during exhaustive exercise. Since approximately half of them also exhibit exercise-induced arterial hypoxaemia (EIAH) during high-intensity exercise, the present study sought to test the hypothesis that arterial hypoxaemia contributes to exercise-induced diaphragmatic fatigue in this population. Ten cyclists ( : 70.0 +/- 1.6 ml kg(-1) min(-1); mean +/-s.e.m.) completed, in a balanced ordering sequence, one normoxic (end-exercise arterial O(2) saturation (S(a,O(2))): 92 +/- 1%) and one hyperoxic (F(I,O(2)): 0.5% O(2); S(a,O(2)) : 97 +/- 1%) 5 min exercise test at intensities equal to 80 +/- 3 and 90 +/- 3% of maximal work rate (WR(max)), respectively, producing the same tidal volume (V(T)) and breathing frequency (f) throughout exercise. Cervical magnetic stimulation was used to determine reduction in twitch transdiaphragmatic pressure (P(di,tw)) during recovery. Hyperoxic exercise at 90% WR(max) induced significantly (P= 0.022) greater post-exercise reduction in P(di,tw) (15 +/- 2%) than did normoxic exercise at 80% WR(max) (9 +/- 2%), despite the similar mean ventilation (123 +/- 8 and 119 +/- 8 l min(-1), respectively), breathing pattern (V(T): 2.53 +/- 0.05 and 2.61 +/- 0.05 l, f: 49 +/- 2 and 46 +/- 2 breaths min(-1), respectively), mean changes in P(di) during exercise (37.1 +/- 2.4 and 38.2 +/- 2.8 cmH(2)O, respectively) and end-exercise arterial lactate (12.1 +/- 1.4 and 10.8 +/- 1.1 mmol l(-1), respectively). The difference found in diaphragmatic fatigue between the hyperoxic (at higher leg work rate) and the normoxic (at lower leg work rate) tests suggests that neither EIAH nor lactic acidosis per se are likely predominant causative factors in diaphragmatic fatigue in this population, at least at the level of S(a,O(2)) tested. Rather, this result leads us to hypothesize that blood flow competition with the legs is an important contributor to diaphragmatic fatigue in heavy exercise, assuming that higher leg work required greater leg blood flow.

Skeletal muscle adaptations to interval training in patients with advanced COPD.

STUDY OBJECTIVES: To investigate the response to interval exercise (IE) training by looking at changes in morphologic and biochemical characteristics of the vastus lateralis muscle, and to compare these changes to those incurred after constant-load exercise (CLE) training. DESIGN: Randomized, controlled, parallel, two-group study (IE vs CLE training). SETTING: Multidisciplinary, outpatient, hospital-based, pulmonary rehabilitation program. PATIENTS: Nineteen patients with stable advanced COPD (mean +/- SEM FEV1, 40 +/- 4% predicted). INTERVENTIONS: Patients (n = 10) assigned to IE training exercised at a mean intensity of 124 +/- 15% of baseline peak exercise capacity (peak work rate [Wpeak]) with 30-s work periods interspersed with 30-s rest periods for 45 min/d. Patients (n = 9) allocated to CLE training exercised at a mean intensity of 75 +/- 5% Wpeak for 30 min/d. Patients exercised 3 d/wk for 10 weeks. MEASUREMENTS AND RESULTS: Needle biopsies of the right vastus lateralis muscle were performed before and after rehabilitation. After IE training, the cross-sectional areas of type I and IIa fibers were significantly increased (type I before, 3,972 +/- 455 microm2; after, 4,934 +/- 467 microm2 [p = 0.004]; type IIa before, 3,695 +/- 372 microm2; after, 4,486 +/- 346 microm2 [p = 0.008]), whereas the capillary-to-fiber ratio was significantly enlarged (from 1.13 +/- 0.08 to 1.24 +/- 0.07 [p = 0.013]). Citrate synthase activity increased (from 14.3 +/- 1.4 to 20.5 +/- 4.2 micromol/min/g), albeit not significantly (p = 0.097). There was also a significant improvement in Wpeak (by 19 +/- 5%; p = 0.04) and in lactate threshold (by 17 +/- 5%; p = 0.02). The magnitude of changes in all the above variables was not significantly different compared to that incurred after CLE training. During training sessions, however, ratings of dyspnea and leg discomfort, expressed as fraction of values achieved at baseline Wpeak, were significantly lower (p < 0.05) for IE training (73 +/- 9% and 60 +/- 8%, respectively) compared to CLE training (83 +/- 10% and 87 +/- 13%, respectively). CONCLUSIONS: High-intensity IE training is equally effective to moderately intense CLE training in inducing peripheral muscle adaptations; however, IE is associated with fewer training symptoms.

Respiratory kinematics by optoelectronic plethysmography during exercise in men and women.

Gender differences in resting pulmonary function are attributable to the smaller lung volumes in women relative to men. We sought to investigate whether the pattern of response in operational lung volumes during exercise is different between men and women of similar fitness levels. Breath-by-breath volume changes of the entire chest wall ( V(.)( CW)) and its rib cage ( V(.)( Rc)) and abdominal ( V(.)( Ab)) compartments were studied by optoelectronic plethysmography in 15 healthy subjects (10 men) who underwent a symptom-limited ( W (peak)) incremental bicycle test. The pattern of change in end-inspiratory and end-expiratory V(.)( CW) ( V(.)( CW,EI) and V(.)( CW,EE), respectively) did not differ between the sexes. With increasing workload the decrease in V(.)( CW,EE) was almost entirely attributable to a reduction in end-expiratory V(.)( Ab), whereas the increase in V(.)( CW,EI) was due to the increase in end-inspiratory V(.)( Rc) in both sexes. In men, at W (peak) tidal volume [ V(.)( T), 2.7 (0.2) l] and inspiratory capacity [IC, 3.4 (0.2) l] were significantly greater than in women [1.8 (0.2) and 2.6 (0.2) l, respectively]. However, after controlling for lung size using forced vital capacity (FVC) as a surrogate, the differences between men and women were eliminated [ V(.)( T) /FVC 49 (3) and 45 (3) respectively, and IC/FVC 63 (2) and 65 (3) respectively]. All data are presented as mean (SE). In both men and women the contribution of the rib cage compartment to V(.)( T) expansion was significantly greater than that of the abdominal compartment. We conclude that gender differences in operational lung volumes in response to progressive exercise are principally attributable to differences related to lung size, whereas compartmental chest wall kinematics do not differ among sexes.