Muscle metabolism during exercise in hemiparetic patients.

1. A group of eight male patients with moderate hemiparesis was studied at rest and during 40 min of exercise on four occasions. Both two-leg and one-leg exercise were performed and each leg was studied separately. Arterial concentrations and leg exchange of carbohydrate substrates and free fatty acids were examined. In addition, the concentrations of intramuscular metabolites for each leg were measured at rest and immediately after exercise. 2. In two-leg exercise, oxygen uptake for the paretic leg was significantly lower than for the non-paretic leg at rest (55%) as well as during exercise (40%). Glucose uptake by the paretic leg was smaller (25–50%) and there was no measurable net leg exchange for lactate. Recordings of pedal pressure indicated that the paretic leg did considerably less work than the non-paretic leg throughout the exercise period. The rate of uptake of oleic acid was lower for the paretic leg (50%) in the resting state but similar for the two legs during exercise. The recovery of 14 CO 2 from [ 14 C]oleic acid during exercise was significantly reduced for the paretic leg. 3. During one-leg exercise, oxygen and glucose uptakes by the working leg were similar for the paretic and non-paretic leg but lactate release was significantly greater for the paretic leg during exercise (30–45%). 4. The concentrations of ATP and creatine phosphate in the basal state were similar for the two legs. ATP and creatine phosphate fell significantly in the two legs during both the two-leg and the one-leg exercise period. The most marked decrease in ATP was noted for the paretic leg during one-leg exercise. The pattern of glycogen depletion during one-leg exercise for the paretic leg indicated primarily activation of the type II fibres. In contrast, the depletion pattern for the non-paretic leg suggested mainly recruitment of type I fibres. 5. The results indicate that, during exercise, paretic muscle shows a reduced blood flow, an augmented lactate production and a diminished capacity to oxidize free fatty acids. These metabolic derangements may be referrable to an augmented number and increased activation of type II muscle fibres as well as to alterations in the structure of muscle mitochondria. In addition, the present study indicates that one-leg exercise should be preferred to two-leg exercise when studying leg muscle circulation and metabolism in hemiparetic patients.

[1]  L. Edström,et al.  HISTOCHEMICAL TYPES AND SIZES OF FIBRES IN NORMAL HUMAN MUSCLES , 1969, Acta neurologica Scandinavica.

[2]  K. Piehl Glycogen storage and depletion in human skeletal muscle fibres. , 1974, Acta physiologica Scandinavica. Supplementum.

[3]  Thorstensson Muscle strength, fibre types and enzyme activities in man. , 1976, Acta physiologica Scandinavica. Supplementum.

[4]  L. Jorfeldt,et al.  Leg blood flow during exercise in man. , 1971, Clinical science.

[5]  N. Jones,et al.  Uptake and release of free fatty acids and other metabolites in the legs of exercising men. , 1967, Journal of applied physiology.

[6]  J. Wahren,et al.  Free fatty acid metabolism of leg muscles during exercise in patients with obliterative iliac and femoral artery disease before and after reconstructive surgery. , 1972, Journal of Clinical Investigation.

[7]  B. Saltin,et al.  Work capacity, muscle strength and SDH activity in both legs of hemiparetic patients and patients with Parkinson's disease. , 1975, Scandinavian journal of clinical and laboratory investigation.

[8]  P D Gollnick,et al.  Enzyme activity and fiber composition in skeletal muscle of untrained and trained men. , 1972, Journal of applied physiology.

[9]  P D Gollnick,et al.  Selective glycogen depletion pattern in human muscle fibres after exercise of varying intensity and at varying pedalling rates , 1974, The Journal of physiology.

[10]  J. Hannerz,et al.  Firing rate and recruitment order of toe extensor motor units in different modes of voluntary conraction. , 1977, The Journal of physiology.

[11]  J. Wahren,et al.  Substrate utilization in paretic human forearm muscle during electrically induced exercise. , 1971, Clinical science.

[12]  B. Saltin,et al.  Muscle metabolism during exercise in patients with Parkinson's disease. , 1974, Clinical science and molecular medicine.

[13]  J. Hannerz,et al.  Discharge properties of motor units in relation to recruitment order in voluntary contraction. , 1974, Acta physiologica Scandinavica.

[14]  J. Bergstrom MUSCLE ELECTROLYTES IN MAN DETERMINED BY NEUTRON ACTIVATION ANALYSIS ON NEEDLE BIOPSY SPECIMENS , 1962 .

[15]  S. Landin,et al.  Ultrastructure of skeletal muscle in patients with Parkinson's disease and upper motor lesions. , 1975, Laboratory investigation; a journal of technical methods and pathology.

[16]  B. Linde,et al.  The validity of some conventional methods for the diagnosis of obliterative arterial disease in the lower limb as evaluated by arteriography. , 1971, Scandinavian journal of clinical and laboratory investigation.

[17]  J. T. Shepherd,et al.  The circulation in the chronically denervated forearm. , 1953, Clinical science.

[18]  J. Wahren,et al.  Human forearm muscle metabolism during exercise. VII. FFA uptake and oxidation at different work intensities. , 1972, Scandinavian journal of clinical and laboratory investigation.

[19]  L. Jorfeldt,et al.  Glucose metabolism during leg exercise in man. , 1971, The Journal of clinical investigation.

[20]  BLOOD FLOW IN THE EXTREMITIES AT REST, DURING REACTIVE HYPERAEMIA AND AFTER GANGLIONIC BLOCK IN CASES OF FRIEDREICH'S ATAXIA. , 2009, Acta medica Scandinavica.