Changes in muscle oxygenation during weight-lifting exercise

The quantitative analysis of haemoglobin oxygenation of contracting human muscle during weight-lifting exercise was studied noninvasively and directly using near-infrared spectroscopy. This method was developed as a three-wavelength method which confirmed the volume changes in oxygenated haemoglobin (oxy-Hb), deoxygenated haemoglobin (deoxy-Hb) and blood volume (total-Hb; Oxy-Hb + deoxy-Hb). Nine healthy adult men with various levels of training experience took part in the study. Ten repetition maximum (10 RM) one-arm curl exercise was performed by all the subjects. Results showed that at the beginning of the 10-RM exercise, rapid increases of deoxy-Hb and decreases of oxy-Hb were observed. In addition, total-Hb gradually increased during exercise. These results corresponded to the condition of arm blood flow experimentally restricted using a tourniquet in contact with the shoulder joint, and they showed the restriction of venous blood flow and an anoxic state occurring in the dynamically contracted muscle. In three sets of lifting exercise with short rest periods, these tendencies were accelerated in each set, while total-Hb volume did not return to the resting state after the third set for more than 90 s. These results would suggest that a training regimen emphasizing a moderately high load and a high number of repetitions, and a serial set with short rest periods such as usually performed by bodybuilders, caused a relatively long-term anoxic state in the muscle.     

Glucocorticoid receptor activation during exercise in muscle

This investigation was undertaken to evaluate whether endurance running of the type known to retard the muscle atrophy associated with glucocorticoid excess inhibits activation of glucocorticoid-receptor complexes to a DNA binding state. Female adrenalectomized rats received an injection (50 microCi/100 g body wt ip) of [3H]triamcinolone acetonide and remained sedentary or were immediately exercised by endurance running at 23 m/min for up to 90 min. Receptor activation, as quantified by binding to DNA-cellulose, steadily increased from 10-20% of the receptors capable of binding DNA in uninjected controls to 25-45% by 5 min and to 53-80% by 90 min after receiving the hormone in all muscles studied (fast-twitch red vastus lateralis, fast-twitch white vastus lateralis, slow-twitch soleus, mixed gastrocnemius, and heart). Exercise did not influence the time-course changes in percent activation. When activation was determined from changes in the conformational state of the receptor as measured by diethylaminoethyl-cellulose anion exchange chromatography, there was a similar time-dependent formation of activated receptor forms in all muscle types. However, exercise did not inhibit or delay the appearance of the activated receptor from the unactivated state. These results indicate that glucocorticoid receptor activation occurs at a rate that is independent of both fiber type and delivery of steroid to working muscles during exercise. If exercise alters receptor activation, a longer time period, beyond 90 min of running, or even additional training may be needed for inhibition to be expressed.     

Gluconeogenic pathway in liver and muscle glycogen synthesis after exercise

To determine whether prior exercise affects the pathways of liver and muscle glycogen synthesis, rested and postexercised rats fasted for 24 h were infused with glucose (200 mumol.min-1.kg-1 iv) containing [6-3H]glucose. Hyperglycemia was exaggerated in postexercised rats, but blood lactate levels were lower than in nonexercised rats. The percent of hepatic glycogen synthesized from the indirect pathway (via gluconeogenesis) did not differ between exercised (39%) and nonexercised (36%) rats. In red muscle, glycogen was synthesized entirely by the direct pathway (uptake and phosphorylation of plasma glucose) in both groups. However, only approximately 50% of glycogen was formed via the direct pathway in white muscle of exercised and nonexercised rats. Therefore prior exercise did not alter the pathways of tissue glycogen synthesis. To further study the incorporation of gluconeogenic precursors into muscle glycogen, exercised rats were infused with either saline, lactate (100 mumol.min-1.kg-1), or glucose (200 mumol.min-1.kg-1), containing [6-3H]glucose and [14C(U)]lactate. Plasma glucose was elevated one- to twofold and three- to fourfold by lactate and glucose infusion, respectively. Plasma lactate levels were elevated by about threefold during both glucose and lactate infusion. Glycogen was partially synthesized via an indirect pathway in white muscle and liver of glucose- or lactate-infused rats but not in saline-infused animals. Thus participation of an indirect pathway in white skeletal muscle glycogen synthesis required prolonged elevation of plasma lactate levels produced by nutritive support.     

Skeletal muscle oxygenation during incremental exercise

The purpose of this study was to investigate the relationship between muscle oxygenation level at exhaustion and maximal oxygen uptake (VO2max) in an incremental cycling exercise. Nine male subjects took part in an incremental exhaustive cycling exercise, and then cuff occlusion was performed. Changes in oxy-(deltaHbO2) and deoxy-(deltaHb) hemoglobin concentrations in the vastus lateralis muscle were measured with a near infrared spectroscopy (NIRS). Muscle oxygenation during incremental exercise was expressed as a percentage (%Moxy) of the maximal range observed during an arterial occlusion as the lower reference point. A systematic decrease was observed in %Moxy with increasing intensity. A significant relationship was observed between %Moxy at exhaustion and VO2max (p < 0.01). We concluded that the one of the limiting factor of VO2max is the muscle oxygen diffusion capacity, and %Moxy during exercise could be one of the indexes of muscle oxygen diffusion capacity.     

Respiratory muscle reserve in rats during heavy exercise

Gosselin, Luc E., David Megirian, Joshua Rodman, DonnaMueller, and Gaspar A. Farkas. Respiratory muscle reserve in ratsduring heavy exercise. J. Appl.Physiol. 83(4): 1405-1409, 1997.The extent towhich the respiratory pump muscles limit maximal aerobic capacity inquadrupeds is not entirely clear. To examine the effect of reducedrespiratory muscle reserve on aerobic capacity, whole bodypeak oxygen consumption(O_{2 peak}) wasmeasured in healthy Sprague-Dawley rats before and after Sham,unilateral, or bilateral hemidiaphragm denervation (Dnv) surgery.O_{2 peak} wasdetermined by using a graded treadmill running test.Hemidiaphragm paralysis was verified after testing byrecording the absence of electromyographic activity duringinspiration. Before surgery, O_{2 peak} averaged 86, 87, and 92 ml · kg¹ · min¹for the Sham, unilateral, and bilateral Dnv groups, respectively. Twoweeks after surgery, there was no significant change inO_{2 peak} foreither the Sham or unilateral Dnv group. However,O_{2 peak} decreased~19% in the bilateral Dnv group 2 wk after surgery. These findingsstrongly suggest that the pulmonary system in rats is designed suchthat during heavy exercise, the remaining respiratory pump muscles areable to compensate for the loss of one hemidiaphragm, but not of both.

     

Training decreases muscle glycogen turnover during exercise

The present study was undertaken to determine the effects of endurance training on glycogen kinetics during exercise. A new model describing glycogen kinetics was applied to quantitate the rates of synthesis and degradation of glycogen. Trained and untrained rats were infused with a 25% glucose solution with 6-³H-glucose and U-¹⁴C-lactate at 1.5 and 0.5 μCi · min⁻¹ (where 1 Ci = 3.7 × 10¹⁰ Bq), respectively, during rest (30 min) and exercise (60 min). Blood samples were taken at 10-min intervals starting just prior to isotopic infusion, until the cessation of exercise. Tissues harvested after the cessation of exercise were muscle (soleus, deep, and superficial vastus lateralis, gastrocnemius), liver, and heart. Tissue glycogen was quantitated and analyzed for incorporation of ³H and ¹⁴C via liquid scintillation counting. There were no net decreases in muscle glycogen concentration from trained rats, whereas muscle glycogen concentration decreased to as much as 64% (P < 0.05) in soleus in muscles from untrained rats after exercise. Liver glycogen decreased in both trained (30%) and untrained (40%) rats. Glycogen specific activity increased in all tissues after exercise indicating isotope incorporation and, thus, glycogen synthesis during exercise. There were no differences in muscle glycogen synthesis rates between trained and untrained rats after exercise. However, training decreased muscle glycogen degradation rates in total muscle (i.e., the sum of the degradation rates of all of the muscles sampled) tenfold (P < 0.05). We have applied a model to describe glycogen kinetics in relation to glucose and lactate metabolism during exercise in trained and untrained rats. Training significantly decreases muscle glycogen degradation rates during exercise. Accepted: 22 May 1998     

Splanchnic and muscle fructose metabolism during and after exercise

Regional substrate exchange was studied in 12 healthy males during 90 min of bicycle exercise at 30% of maximal O2 consumption with a 20-min recovery. Six subjects received an intravenous fructose infusion (8.5 mmol/min) from 40 min of exercise to the end of recovery. Splanchnic glucose output, muscle glucose uptake, arterial glucose, and insulin were uninfluenced by the infusion. The respiratory exchange ratio rose to 0.93 +/- 0.04, and arterial free fatty acids fell by 50% (P less than 0.05). Fructose was taken up by splanchnic tissues (45% of administered load), leg muscle (28%), and resting muscle (28%). During infusion, arterial lactate and pyruvate rose two- to threefold, and these substrates were released from splanchnic tissues and taken up by exercising and resting muscle. Splanchnic release of lactate, pyruvate, and glucose accounted for 78% of fructose uptake at 90 min of exercise. Uptake of fructose, lactate, and pyruvate accounted for 55% and together with glucose for 103% of the total oxidative metabolism by exercising muscle. The regional fructose uptakes and lactate exchanges persisted throughout recovery. The present results indicate that fructose infusion during leg exercise 1) results in increased carbohydrate oxidation from fructose, lactate, and pyruvate in exercising muscle, 2) exerts a glycogenic effect in resting muscle and liver during exercise and in liver and muscle recovering from exercise, and 3) does not interfere with glucose metabolism, and that fructose transport into muscle differs from that of glucose.     

Regulation of muscle pyruvate metabolism during exercise

Pyruvate dehydrogenase and phosphoenolpyruvate carboxykinase are important enzymes in the regulation of muscle pyruvate metabolism and their in vitro measured activities have been studied in muscle from rested and exercised rats. In addition, the muscle concentration of metabolic intermediates associated with pyruvate metabolism has been measured after exercise. Phosphoenolpyruvate concentration was decreased to less than half the value found in rested muscle but pyruvate concentration did not change. This suggests an increase in the in vivo rate of conversion of phosphoenolpyruvate to pyruvate. Concentrations of malate and aspartate increased two- to threefold which suggests that oxaloacetate concentration was also increased. An increase in oxaloacetate availability would increase acetyl CoA metabolism and therefore would increase pyruvate dehydrogenase activity in vivo. The basal activity of pyruvate dehydrogenase measured in vitro increased approximately twofold after 2 hr of exercise and returned to control values 5 min after the cessation of exercise. Total pyruvate dehydrogenase activity (activated to the maximal extent) was not changed by exercise. Muscle PEPCK activity was also increased during exercise suggesting an increased rate of conversion of oxaloacetate to pyruvate to provide net oxidation of oxaloacetate and other citric acid cycle intermediates. Results of this study demonstrate that the rates of formation and metabolism of pyruvate are increased during exercise.     

Severe depletion in liver glutathione during physical exercise

Physical exercise at submaximal levels in rats results in a progressive depletion of liver glutathione to about 20% of the levels found in sedentary controls which persists for several hours following the cessation of exercise. Skeletal muscle appears to be spared this severe depletion phenomenon. The levels of plasma glutathione show a transient increase at the beginning of the exercise bout followed by a linear decrease with increased running time of the animals. These results may be particularly relevant when attempting to understand the effects of physical exercise on a large number of cellular and organismal functions that are known or suspected to depend critically on the glutathione status of the liver.     

Adrenal hormones enhance glycogenolysis in nonexercising muscle during exercise

The purpose of this study was to investigate whether epinephrine exerts an effect on glycogen metabolism in nonexercising (Non-Ex) as well as in exercising (Ex) skeletal muscle. Rats ran (15 m/min; 8% grade) on their forelimbs while their hindlimbs (Non-Ex) were suspended above the treadmill. Electromyographic records confirmed the lack of significant contractile activity in muscles during suspension. Plasma epinephrine levels were manipulated in three experimental groups (n = 20 for each group): adrenalectomized (ADX), intact adrenals (IA), and IA + epinephrine injection (+Ep). Another group of rats performed normal exercise on all four limbs (15 m/min; 8% grade). Muscle glycogen levels were measured in selected hindlimb muscles at t = 0 and after 90 min exercise (15 m/min; 8% grade) or suspended rest. In the absence of epinephrine (ADX), no glycogen loss was found (P greater than 0.05) in Non-Ex muscles during the exercise period. In the IA group (epinephrine levels elevated sixfold above basal at t = 90 min), glycogen levels in the nonexercising soleus, plantaris, and red and white gastrocnemius were significantly (P less than 0.05) depleted to 62 +/- 6, 67 +/- 6, 58 +/- 5, and 67 +/- 9% of control values, respectively. Similar decrements occurred in these muscles when exercise was performed on all four limbs (P greater than 0.05). We conclude that glycogenolysis occurs in nonexercising skeletal muscle independent of contractile activity, probably due to the effect of epinephrine. Furthermore, the present data strongly suggest that glycogen depletion patterns in muscles during exercise cannot be used as an index of motor unit recruitment.     

Beta-blockade and oxygen delivery to muscle during exercise.

The most commonly observed effect of beta-blockade on cardiovascular function has been a reduction in heart rate both at rest and during exercise. The body attempts to compensate by increasing stroke volume and (or) increasing the extraction of O2 from the blood to maintain O2 delivery to the muscle. This paper examines the roles of muscle mass involved in the exercise as well as the time course of change in cardiac output and peripheral blood flow in an attempt to understand whether O2 supply is limited by beta-blockade. Experiments are reported in which the kinetics of cardiac output response at the onset of submaximal cycle exercise were slowed in subjects taking oral propranolol. Taken in consideration with other data from our laboratory and with data in the literature, it was concluded that beta-blockade does impair O2 transport. The degree of impairment is dependent on the total muscle mass involved and the metabolic demand.     

Creatine supplementation and age influence muscle metabolism during exercise

Young[n = 5, 30 ± 5 (SD) yr] andmiddle-aged (n = 4, 58 ± 4 yr) menand women performed single-leg knee-extension exercise inside a wholebody magnetic resonance system. Two trials were performed 7 days apartand consisted of two 2-min bouts and a third bout continued toexhaustion, all separated by 3 min of recovery.³¹P spectra were used to determinepH and relative concentrations ofP_i, phosphocreatine (PCr), and-ATP every 10 s. The subjects consumed 0.3 g · kg¹ · day¹of a placebo (trial 1) or creatine(trial 2) for 5 days before eachtrial. During the placebo trial, the middle-aged group had a lowerresting PCr compared with the young group (35.0 ± 5.2 vs. 39.5 ± 5.1 mmol/kg, P < 0.05) and alower mean initial PCr resynthesis rate (18.1 ± 3.5 vs. 23.2 ± 6.0 mmol · kg¹ · min¹,P < 0.05). After creatinesupplementation, resting PCr increased 15%(P < 0.05) in the young group and30% (P < 0.05) in the middle-aged group to 45.7 ± 7.5 vs. 45.7 ± 5.5 mmol/kg, respectively. Mean initial PCr resynthesis rate also increased in the middle-aged group(P < 0.05) to a level not differentfrom the young group (24.3 ± 3.8 vs. 24.2 ± 3.2 mmol · kg¹ · min¹).Time to exhaustion was increased in both groups combined after creatinesupplementation (118 ± 34 vs. 154 ± 70 s,P < 0.05). In conclusion, creatinesupplementation has a greater effect on PCr availability andresynthesis rate in middle-aged compared with youngerpersons.