Your search keyword '"Chin ER"' showing total 3 results

1. Role of intracellular calcium and metabolites in low-frequency fatigue of mouse skeletal muscle.

Author

Chin ER, Balnave CD, and Allen DG

Subjects

Animals, Electric Stimulation methods, Mice, Muscle Contraction, Time Factors, Calcium metabolism, Intracellular Membranes metabolism, Muscle Fatigue physiology, Muscle, Skeletal physiology

Abstract

We have examined the extent to which prolonged reductions in low-frequency force (i.e., low-frequency fatigue) result from increases in intracellular free Ca2+ concentration ([Ca2+]i) and alterations in muscle metabolites. Force and [Ca2+]i were measured in mammalian single muscle fibers in response to short, intermediate, and long series of tetani that elevated the [Ca2+]i-time integral to 5, 17, and 29 microM x s, respectively. Only the intermediate and long series resulted in prolonged (>60 x min) reductions in Ca2+ release and low-frequency fatigue. When fibers recovered from the long series of tetani without glucose, Ca2+ release was reduced to a greater extent and force was reduced at high and low frequencies. These findings indicate that the decrease in sarcoplasmic reticulum Ca2+ release associated with fatigue has at least two components: 1) a metabolic component, which, in the presence of glucose, recovers within 1 h, and 2) a component dependent on the elevation of the [Ca2+]i-time integral, which recovers more slowly. It is this Ca2+-dependent component that is primarily responsible for low-frequency fatigue.

Published

1997

2. Increases in human skeletal muscle Na(+)-K(+)-ATPase concentration with short-term training.

Author

Green HJ, Chin ER, Ball-Burnett M, and Ranney D

Subjects

Adult, Humans, Male, Osmolar Concentration, Oxygen Consumption, Plasma Volume, Potassium blood, Potassium metabolism, Time Factors, Muscles enzymology, Physical Education and Training, Sodium-Potassium-Exchanging ATPase metabolism

Abstract

To investigate the effect of short-term training on Na(+)-K(+)-adenosine triphosphatase (ATPase) concentration in skeletal muscle and on plasma K+ homeostasis during exercise, 9 subjects performed cycle exercise for 2 h per day for 6 consecutive days at 65% of maximal aerobic power (VO2 max). Na(+)-K(+)-ATPase concentration determined from biopsies obtained from the vastus lateralis muscle using the [3H]ouabain-binding technique increased 13.6% (P < 0.05) as a result of the training (339 +/- 16 vs. 385 +/- 19 pmol/g wet wt, means +/- SE). Increases in Na(+)-K(+)-ATPase concentration were accompanied by a small but significant increase in VO2 max (3.36 +/- 0.16 vs. 3.58 +/- 0.13 l/min). The increase in arterialized plasma K+ concentration and plasma K+ content determined during continuous exercise at three different intensities (60, 79, and 94% VO2 max) was depressed (P < 0.05) following training. These results indicate that not only is training capable of inducing an upregulation in sarcolemmal Na(+)-K(+)-ATPase concentration in humans, but provided that the exercise is of sufficient intensity and duration, the upregulation can occur within the first week of training. Moreover, our findings are consistent with the notion that the increase in Na(+)-K(+)-ATPase pump concentration attenuates the loss of K+ from the working muscle.

Published

1993

3. Lactate metabolism in inactive skeletal muscle during lactacidosis.

Author

Chin ER, Lindinger MI, and Heigenhauser GJ

Subjects

Animals, Glucose metabolism, Hindlimb, Lactates pharmacology, Lactic Acid, Male, Oxygen Consumption, Rats, Rats, Inbred Strains, Acidosis, Lactic metabolism, Lactates metabolism, Muscles metabolism

Abstract

Contributions of carbohydrate and fat metabolism to the removal of a lactate (Lac-) load were quantified in inactive soleus (SL), plantaris (PL), and white gastrocnemius (WG) rat hindlimb muscle. Male Sprague-Dawley rats were perfused for 60 min with normal perfusate (NP, n = 8) or a high-lactate perfusate (LP, n = 8), simulating ionic conditions found in arterial blood and plasma after intense exercise: Lac- = 11.0 mM, K+ = 7.88 mM, and pH = 7.15. Metabolite fluxes across the hindlimb were calculated from blood flow and arteriovenous differences. In NP, Lac- was continuously released (2.9 +/- 0.2 mumol.min-1 x 100 g-1). However, in LP, a rapid and significant uptake of Lac- increased muscle Lac- fivefold to 39.6 +/- 1.1, 33.1 +/- 2.2, and 28.8 +/- 1.7 mumol/g dry wt in SL, PL, and WG, respectively. Glucose and O2 uptakes were similar during LP and NP perfusion. Glycerol release increased eightfold to 3.3 +/- 0.7 mumol.min-1 x 100 g-1 in response to LP. Muscle ATP, creatine phosphate, glycogen, glycolytic intermediate, and triacylglycerol concentrations did not change. However, muscle lactate-to-pyruvate ratios were elevated in all muscles of the LP group postperfusion, indicating changes in the mass action ratio at the pyruvate dehydrogenase reaction. In LP, of 80 mumol of Lac- taken up, 11% was accounted for by increased muscle Lac-, 12-24% was oxidized, and 5% may have been involved in glycerol release. The remaining Lac- may have been involved in metabolic cycling along the glyconeogenic-glycolytic pathway and/or in triacylglycerol-free fatty acid substrate cycling.

Published

1991