Oxidation of exogenous medium-chain free fatty acids during prolonged exercise: comparison with glucose

The purpose of this study was to compare the oxidation rate of exogenous 13C-labeled medium-chain triacylglycerols (MCT) with that of an isocaloric amount of exogenous [13C]glucose and to evaluate their respective effects on endocrine and metabolic responses to moderate prolonged exercise. To take into account changes in isotopic composition of 13CO2 arising from oxidation of endogenous substrates because of exercise and/or substrate ingestion that overestimates the oxidation rate of exogenous substrates, two levels of 13C enrichment were used for each substrate. Six young healthy males (20-26 yr of age) completed five 2-h periods of exercise at 65 +/- 3% maximal O2 uptake (VO2max) on a cycle ergometer at 7-day intervals: one control exercise with water ingestion, two trials with ingestion of 25 g of [13C]MCT (trioctanoate) 1 h before exercise, and two trials with 57 g of [13C]glucose (dissolved in 1,000 ml of water) ingested during exercise. Exogenous MCT and glucose began to be oxidized within the first 30 min of exercise, and the oxidation rate increased progressively until the end of exercise for both substrates. Over the 2-h period of exercise, 13.6 +/- 3.5 g of ingested MCT and 36.4 +/- 8.2 g of exogenous glucose were oxidized, which represent 54 and 64%, respectively, of the total amount ingested. The contribution of MCT (119 +/- 31 kcal) and glucose (140 +/- 36 kcal) was not significantly different and represented 7 and 8.5%, respectively, of the total energy expenditure.(ABSTRACT TRUNCATED AT 250 WORDS)

PNMT inhibition decreases exercise performance in the rat

The purpose of this investigation was to examine the effect of phenylethanolamine N-methyltransferase (PNMT) inhibition on the regulation of peripheral metabolic and hormonal responses during treadmill exercise in the rat. Changes in plasma catecholamine (epinephrine, norepinephrine, and dopamine), glucagon and glucose, and the glycogen content of the liver and two skeletal muscles were studied in four groups of rats. Two groups of rats were studied at rest: one group had been treated with LY134046, an inhibitor of PNMT, and the second group was treated with physiological saline. A third group treated with LY134046 was studied after treadmill exercise (28 m.min-1 and 8% slope). In this group of rats, exhaustion came after 37.5 +/- 7.9 minutes of exercise. In order to make appropriate comparisons, a fourth group of rats treated with physiological saline was exercised for 37.5 min. Running endurance during the treadmill exercise was thus reduced in LY134046-treated rats. Plasma epinephrine and glucagon concentrations and other metabolic (plasma glucose and gastrocnemius lateralis and superficial vastus lateralis muscles and liver glycogen contents) responses were similar between LY134046- and saline-treated rats at rest and after exercise. These results suggest that PNMT inhibition in epinephrine brain neurons might be the principal factor involved in the LY134046-induced reduction of exercise endurance.

Role of the sympathoadrenal system in the regulation of glycogen metabolism in resting and exercising skeletal muscles

The purpose of the present study was to characterize the role of catecholamines in the regulation of skeletal muscle glycogen metabolism during exercise. Using the rat hindlimb perfusion technique we have measured skeletal muscle glycogen content, glycogen phosphorylase and synthase activities in sympathectomized and/or demedullated rats under epinephrine treatment (10(-7) M) at rest and during muscle contraction. When epinephrine and/or norepinephrine deficiency was induced, muscle contraction resulted in a decrease in glycogen content (-63%) despite a decrease in glycogen phosphorylase activity ratio (0.25 to 0.11; p less than 0.001) and an increase in glycogen synthase activity ratio (0.13 to 0.27; p less than 0.001). Under these conditions, epinephrine treatment further reduced glycogen content while blunting the changes in the activity ratio of the rate-limiting enzymes. These data indicate that catecholamines do not play a primary role in skeletal muscle glycogen breakdown during acute exercise and suggest that allosteric regulators may be of prime importance.

Evidence against a humoral control mechanism in adrenal catecholamine secretion during insulin-induced hypoglycemia

The present study tested the hypothesis that a humoral control mechanism is involved in the enhanced adrenal catecholamine secretion during insulin-induced hypoglycemia. The experiments were carried out in anesthetized dogs in which neuronal and humoral components were simultaneously determined by measuring catecholamine output from the right innervated and the left acutely denervated adrenal gland, respectively. Different levels of hypoglycemia were induced by intravenous injection of insulin with doses of 0.075 (n = 6), 0.150 (n = 6), and 0.300 IU/kg (n = 6) in three separate groups of dogs. Catecholamine output in the right innervated gland increased dose dependently (P less than 0.05), reaching a maximum level 45 min after insulin administration. By contrast, catecholamine output from the left denervated adrenal gland remained unchanged at all doses tested. In sham-denervated animals (n = 7), catecholamine output from the left adrenal gland increased to a magnitude similar to that observed in the right innervated gland after insulin administration. Plasma glucose concentration significantly decreased in a dose-dependent manner, reaching a nadir 30 min after insulin administration. Maximum decreases in plasma glucose concentration could be strongly correlated with maximum increases in catecholamine output from the right innervated adrenal gland (r = -0.66, n = 18, P = 0.011), but not with those from the left denervated gland (r = -0.32, n = 18, P = 0.455). The present results do not support the functional existence of a humoral mechanism permitting the release of adrenal catecholamines during insulin-induced hypoglycemia.

A simple and disposable sweat collector

Apart from in cystic fibrosis, where sweat analysis provides valuable diagnostic information, sweat yields remain an overlooked biological fluid. Technical problems (dilution, condensation, contamination, evaporation, etc.) linked to currently available collection procedures are of concern and thwart their use. To overcome some of these technical difficulties, an original sweat-collection technique is described. A collection capsule is created inside a flexible, adhesive and disposable anchoring membrane pasted onto the skin. A fluid-tight window is positioned in the upper part of the pocket and gives access to its content. Through the collection window, complete emptying of the sweat collector can be achieved repeatedly by suction using a vacutainer tube inserted in a tube holder equipped with a long dull needle. With prior addition of a suitable marker, fractional samplings can also be performed using a precision micropipette. This collecting method allows for kinetic studies on sweat rate and sweat content. The limited bias-inducing manipulations linked to the described technique, coupled with the ease of performing kinetic studies on sweat volume and content, make this original tool a reliable and accurate sweat-collection technique.

HGH20k species and variability of GH responses to long-duration exercise in male cyclists fed different food supplements

Exercise studies dealing with hGH have always considered this hormone as a unique molecular entity. We postulated that the well-known variability in blood total hGH response could possibly be explained, at least in part, by concomitant changes in blood hGH20k levels, variant form possibly expressing some of the hGH anti-insulinic properties. Six male trained cyclists were imposed a 2-hr long ergocycle exercise. Food supplements were given prior to and/or during exertion to exacerbate a possible contribution from hGH20k to total hGH variability by modification of substrate availability. Both blood total hGH and hGH20k levels increased with exercise, the largest increases being observed in absence of supplementation. Large variability of responses were observed in both blood total hGH and hGH20k levels, the latter variant contributing minimally to total blood hGH response (4.3 +/- 0.8%), and being closely associated with the main species (r = 0.90; p less than 0.001). It was concluded that variations associated with hGH20k increases observed in response to prolonged exercise cannot explain the large intra-and inter-individual variability measured in blood total hGH response.

Table of nonprotein respiratory quotient: an update

The purpose of this paper is to point out some limits and inconsistencies in the table of nonprotein respiratory quotient that is universally used. This table, developed by Lusk in 1924, was derived from biochemical and physical data that are now outdated. A new table of nonprotein respiratory quotient, consistent with modern chemical and physical data, is proposed. The revised table is based on (a) the average composition of human triacylglycerol stores, (b) energy potential of fatty acids and glucose, and (c) the volumes occupied by one mole of oxygen or carbon dioxide (which are not ideal gases) under STPD conditions.

Prolactinotrophic effect of endogenous and exogenous heat loads in human male adults

Factors associated with heat-induced increase in blood prolactin (PRL) were investigated. Ten male volunteers (23.7 +/- 2.2 yr) were exposed to exogenous heating (head-out immersion) in 41 degrees C water (control 37 degrees C) for 30 min with and without face fanning and cooling. In seven of the subjects, endogenous heating was produced by a 45-min exercise in a warm environment (41 degrees C; control 10 degrees C) with and without selective face fanning. Venous blood was collected before and after each trial; blood hormones were analyzed by radioimmunologic techniques. Heat loading, whether exogenous or endogenous in origin, induced significant increases in blood PRL, beta-endorphin, and vasoactive intestinal peptide (VIP) levels. Blood thyrotropin (TSH) level decreased significantly during water immersion and more significantly with face cooling. From measurement in peripheral blood, the differential beta-endorphin, VIP, and TSH responses to selective face ventilation during exogenous and endogenous heat exposures suggest that blood PRL released in heat derives from secretory stimuli that are independent of these prolactinotropic factors.

A theoretical analysis of the effect of altitude on running performance

A theoretical analysis of the effect of altitude on running performance is presented using a mathematical model we have recently described and validated (J. Appl. Physiol. 67: 453-465, 1989). This model relates the average power output available over a given running time for a given combination of anaerobic capacity, maximal aerobic power, and endurance capability. For short sprinting distances, the contribution of aerobic metabolism to the energy requirement is small and the speed sustained is high. The reduction of maximal aerobic power with altitude is, thus, negligible, whereas the reduction of aerodynamic resistance is beneficial. Accordingly the performance steadily increases with altitude (e.g., average speed for 100 m at Mexico City is 101.9% of the average speed at sea level). On the other hand, the reduction in maximal aerobic power with altitude is associated with a reduction in performance over middle and long distances (800 m to marathon). For 400 m an improvement in performance is observed up to an altitude of approximately 2,400-2,500 m (average speed approximately 101.4% of sea level speed). Beyond this altitude the reduction in air density cannot compensate for the reduction in maximal aerobic power, and the performance deteriorates. Tables of performances equivalent to the current world records for selected altitudes ranging from 0 to 4,000 m are proposed.

6-OHDA sympathectomy and exercise performance in the rat

6-hydroxydopamine (6-OHDA) was utilised for the study of the sympathetic nervous system in the resting rats and rats submitted to prolonged exercise. In order to reduce the acute physiological stress associated with an injection of 6-OHDA, beta-1 and alpha-1 adrenoceptors were blocked before the treatment leading to sympathectomy. Sympathectomised rats were divided in two groups: one sacrificed at rest, 24 hours after the treatment. The other group was sacrificed after a treadmill exercise to exhaustion. Running time to exhaustion was 36.0 +/- 4.5 min (mean +/- S.E.M.). This group ran significantly less than a control group brought to exhaustion in 73.7 +/- 10.0 min of exercise (P < 0.05). In order to make appropriate comparisons, another control group was run for 36 min. Some differences were observed between corresponding control and sympathectomized groups. At rest: 1) a lower plasma level of insulin, and 2) a higher plasma free fatty acid concentration were observed in sympathectomized rats. After 36 min of exercise: 1) a lower plasma concentration of norepinephrine, 2) no decrease of the plasma level of insulin, 3) no increase in the plasma glucagon concentration, and 4) a higher plasma glucose level were observed in sympathectomised rats when compared to control rats running for the same time. The lower plasma norepinephrine concentration in exercised sympathectomised rats suggests a lower sympathetic nervous activity in these animals than in control rats. The absence of a decrease of plasma insulin concentration and of an increase in glucagon can be attributed to this lower sympathetic activity in sympathectomised rats.(ABSTRACT TRUNCATED AT 250 WORDS)

Use of 13C substrates for metabolic studies in exercise: methodological considerations

The purpose of this study is to outline a common mistake made when the rate of oxidation of exogenous substrates during prolonged exercise is computed using 13C naturally labeled substrates. The equation proposed and commonly used in the computation does not take into account that exercise and/or exogenous substrate ingestion modifies the composition of the mixture of endogenous substrates oxidized and, consequently, the isotopic composition of CO2 arising from oxidation of endogenous substrates. The recovery of 13C and the amount of exogenous substrate oxidized are thus overestimated. An adequate procedure for the computation of exogenous substrate oxidation taking into account changes in isotopic composition of CO2 arising from oxidation of endogenous substrates is suggested. Results from a pilot experiment (4 subjects) using this procedure indicate that over 2 h of exercise (66% of maximal O2 uptake), with ingestion of 60 g of glucose, 39 +/- 4 g of glucose were oxidized. Estimates made without taking into account changes in isotopic composition of CO2 arising from oxidation of endogenous substrates range between 70 +/- 8 and 44 +/- 3 g depending on 1) the isotopic composition of exogenous glucose and 2) the isotopic composition of expired CO2 taken as reference (rest or exercise without glucose ingestion). These observations suggest that results from previous studies of exogenous substrate oxidation during exercise using 13C labeling should be used with caution.

Plasma catecholamines in the aorta and the phrenicoabdominal vein in exercising dogs

Plasma epinephrine and norepinephrine concentrations were measured in the aorta and phrenicoabdominal vein in five dogs at rest and during short-duration mild- and moderate-intensity exercise and during prolonged mild-intensity exercise. Plasma epinephrine and norepinephrine concentrations increased with exercise in both the aorta and the phrenicoabdominal vein. Plasma epinephrine concentration was much higher in the phrenicoabdominal vein than in the aorta (24-43 times). Plasma epinephrine concentrations in the aorta and phrenicoabdominal vein were significantly correlated (r = 0.88). This confirms that peripheral epinephrine concentration is a reliable index of the activity of the adrenal medulla during exercise. The epinephrine-to-norepinephrine ratio in the phrenicoabdominal vein was stable (4:1) throughout the experimental protocol, suggesting that the proportion of the two amines released by the adrenal medulla did not vary through this range of adrenal activity in dogs.

Oxidation of exogenous carbohydrate during prolonged exercise in fed and fasted conditions

The oxidation of glucose and fructose ingested during moderate exercise performed on a cycle ergometer (120 min, 52% VO2max) was compared in ten young males fasted (n = 5) or fed (n = 5) before exercise. The subjects ingested randomly 1.33 g/kg body weight (approximately 96 +/- 9 g) of either enriched 13C-glucose (G), 13C-fructose (F), or water only (W); the solutions were evenly distributed over the exercise period. The fasted subjects began the three exercises with a lower blood glucose (P less than or equal to 0.05 for F only) and insulin (P less than or equal to 0.05) levels and a higher free fatty acid (FFA) concentration (P less than or equal to 0.05) than the fed ones. Throughout the exercise period, blood glucose level was maintained in fasted as well as in fed group for G and F ingestions, while it decreased (P less than or equal to 0.05 at the 100th min in fasted subjects) with water ingestion. Insulin level was similar in both fed and fasted conditions with F and W ingestions and lower than G trials for the fed subjects. For the three ingestions, FFA was lower (P less than or equal to 0.05) in the fasted than in the fed group over the exercise period. Over the 2-h period of exercise, a greater (P less than or equal to 0.05) amount of exogenous F was oxidized in the fasted (49 +/- 6 g) than in the fed (36 +/- 5 g) group, which represent 31% and 20% of the total carbohydrate energy supply, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Face cooling-induced reduction of plasma prolactin response to exercise as part of an integrated response to thermal stress

This study was designed to verify if the decrease in blood prolactin (PRL) induced by selective face cooling during exercise could be part of a response to specific body thermal stress. Five healthy trained male cyclists presenting a significant plasma PRL elevation to exercise were, on three occasions and at weekly interval, submitted to a submaximal exercise (approx. 65% VO2max) on ergocycle with and without selective face cooling. In absence of face cooling a first trial served to establish reference values for workload, heart rate and plasma PRL levels, the latter increasing markedly (450% of resting values) in these conditions. On a second trial but with workload maintained at reference values (222 +/- 9 W), a significant bradycardia was observed with face cooling; furthermore, plasma PRL response to exercise was significantly reduced (to 31% of original response). On a third trial with face cooling, workload had to be significantly augmented (242 +/- 10 W) to maintain heart rate at reference level (78% HRmax); in addition, plasma PRL response to exercise was almost unchanged compared to the reference-value level. The absence of a significant face cooling-induced decrease in sympathetic tonus, as evaluated through peripheral plasma catecholamines response, does not indicate a role for the autonomic nervous system in the face cooling-induced reduction of both heart rate and PRL responses during exercise. Assay of circulating peripheral beta-endorphins could indicate that the face cooling-induced PRL blunted response does not necessarily involve an opioid mediation.(ABSTRACT TRUNCATED AT 250 WORDS)

Mathematical analysis of running performance and world running records

The objective of this study was to develop an empirical model relating human running performance to some characteristics of metabolic energy-yielding processes using A, the capacity of anaerobic metabolism (J/kg); MAP, the maximal aerobic power (W/kg); and E, the reduction in peak aerobic power with the natural logarithm of race duration T, when T greater than TMAP = 420 s. Accordingly, the model developed describes the average power output PT (W/kg) sustained over any T as PT = [S/T(1 - e-T/k2)] + 1/T integral of T O [BMR + B(1 - e-t/k1)]dt where S = A and B = MAP - BMR (basal metabolic rate) when T less than TMAP; and S = A + [Af ln(T/TMAP)] and B = (MAP - BMR) + [E ln(T/TMAP)] when T greater than TMAP; k1 = 30 s and k2 = 20 s are time constants describing the kinetics of aerobic and anaerobic metabolism, respectively, at the beginning of exercise; f is a constant describing the reduction in the amount of energy provided from anaerobic metabolism with increasing T; and t is the time from the onset of the race. This model accurately estimates actual power outputs sustained over a wide range of events, e.g., average absolute error between actual and estimated T for men's 1987 world records from 60 m to the marathon = 0.73%. In addition, satisfactory estimations of the metabolic characteristics of world-class male runners were made as follows: A = 1,658 J/kg; MAP = 83.5 ml O2.kg-1.min-1; 83.5% MAP sustained over the marathon distance. Application of the model to analysis of the evolution of A, MAP, and E, and of the progression of men's and women's world records over the years, is presented.

[A comparison of cyclists' time records according to altitude and materials used]

The purpose of this study was to re-assess the energy cost of track cycling in order (a) to compare the one-hour world records at sea-level and altitude with classical bicycles or with modern bicycles including aerodynamic components, and (b) to estimate the optimal altitude to set a new one-hour world record. Energy cost of track cycling with a classical or aerodynamic bicycle was estimated according to the equation developed by di Prampero et al. (1979) using data from Davies (1980) for the rolling resistance coefficient and from Gross et al. (1983) for the aerodynamic resistance coefficient for each type of bicycle. When compared to the classical track-bicycle, and to the bicycle studied by di Prampero et al. (1979), the aerodynamic track-bicycle reduces the resistance coefficient by 11.7 and 16.9% respectively. According to these estimations the cyclists sustain 87-95% of maximal aerobic power over one hour, which is a likely value for a 60 min exercise period for top-level athletes. When the reduction of air density and of maximal aerobic power with altitude are taken into account, equivalences between performances achieved at different altitudes and with the two types of track-bicycles, can be computed. The best overall performance appears to be the current one-hour record at sea-level using an aerodynamic bicycle (Moser: 50.644 km.h-1). This performance is equivalent to 53.5 km.h-1 in Mexico City (2230 m), 54.4 km.h-1 in La Paz (3417 m) and 54.5 km.h-1 at 3843 m (472 mmHg), which would be the optimal altitude to set the record.

Plasma atriopeptin during exercise in dogs under beta-blockade

The purpose of this study was to describe plasma atriopeptin concentrations at rest and in response to moderate treadmill exercise (10 min, 4 km/h, 26% slope) performed with or without nonspecific beta-adrenergic blockade (1 mg/kg iv propranolol) in 10 mongrel dogs [19 +/- 2 (SE) kg]. A small (20%) but significant (P less than 0.05) increase in plasma atriopeptin concentration was observed from rest (43 +/- 5 pg/ml) to exercise (52 +/- 6 pg/ml) without beta-blockade. Propranolol significantly reduced heart rate at rest (89 +/- 7 vs. 104 +/- 7 beats/min) and during exercise (96 +/- 10 vs. 176 +/- 11 beats/min), and this was associated with a larger increase in plasma atriopeptin concentration during exercise (rest 46 +/- 6 pg/ml; exercise 171 +/- 22 pg/ml). Exercise under beta-blockade is associated with an increased preload of the heart. These results further support the hypothesis that atriopeptin release during exercise is under the control of atrial stretch. The higher plasma atriopeptin concentration observed during exercise under beta-blockade may contribute to the reduction of the response of plasma renin activity (1.0 +/- 0.1 vs. 3.0 +/- 0.6 ng.ml-1.h-1) and aldosterone concentration (87 +/- 36 vs. 138 +/- 25 pg/ml). Vasopressin concentration was lower at rest and during exercise under propranolol (3.5 +/- 1.3 vs. 4.9 +/- 0.9 and 6.1 +/- 2.2 vs. 9.9 +/- 1.5 pg/ml, respectively), which might reflect a dissociation between activity of the renin-angiotensin system and vasopressin release.

Blood pressure and plasma catecholamine responses to various challenges during exercise-recovery in man

The purpose of this study was to assess the effects of a 2 h cycle exercise (50% VO2max) on heart rate (HR) and blood pressure (BP), and on plasma epinephrine (E) and norepinephrine (NE) concentrations, during the recovery period in seven normotensive subjects. Measurements were made at rest in supine (20 min) and standing (10 min) positions, during isometric exercise (hand-grip, 3 min, 25% maximal voluntary, contraction), in response to a mild psychosocial challenge (Stroop conflicting color word task) and during a 5-min period of light exercise (42 +/- 3% VO2max). Data were compared to measurements taken on another occasion under similar experimental conditions, without a previous exercise bout (control). The results showed HR to be slightly elevated in all conditions following the exercise bout. However, diastolic and systolic BP during the recovery period following exercise were not significantly different from the values observed in the control situation. Plasma NE concentrations in supine position and in response to the various physiological and/or psychosocial challenges were similar in the control situation and during the recovery period following exercise. On the other hand plasma E (nmol.1-1) was about 50% lower at rest (0.11 +/- 0.03 vs 0.23 +/- 0.04) as well as in response to hand-grip (0.21 +/- 0.04 vs 0.41 +/- 0.20) and the Stroop-test (0.21 +/- 0.05 vs 0.41 +/- 0.15) following the exercise bout.(ABSTRACT TRUNCATED AT 250 WORDS)

Metabolic and endocrine responses to prolonged exercise in rats under beta 2-adrenergic blockade

The respective roles of allosteric regulators and catecholamines in the control of muscle glycogen breakdown during exercise remain a matter of controversy. This study was designed to reassess the role of the sympathoadrenal system during prolonged exercise in rats. Animals were studied at rest or after treadmill exercise (28 m.min-1; 8% slope) to exhaustion in a control situation or following administration of a specific beta 2-adrenergic receptor antagonist (ICI 118,551, 1 mg.kg-1, i.v.). Running times to exhaustion were 54 and 36 min in control and treated rats, respectively. For the purpose of comparison, another group of control rats was studied after a 36-min exercise bout. The reduction in endurance in treated rats was associated with an impairment in glycogen utilization, as measured by muscle glycogen stores, in soleus muscle but not in superficial vastus lateralis or gastrocnemius lateralis muscles. Utilization of liver glycogen stores was similar in the two groups of animals, but plasma glucose (7 vs. 13 mM) and lactate (4 vs. 7 mM) levels were significantly lower in rats under beta-blockade than in control rats run for 36 min. Plasma free fatty acid and glycerol concentrations were not significantly different between groups. On the other hand, plasma epinephrine concentration was significantly higher in treated rats (13 vs. 5 mM), which might reflect a compensatory increase in adrenal activity. These results suggest that glycogen breakdown during prolonged exercise is under the control of the sympathoadrenal system in predominantly slow-twitch but not in predominantly fast-twitch muscles.(ABSTRACT TRUNCATED AT 250 WORDS)

Trait anxiety, submaximal physical exercise and blood androgens

This study evaluates the relationship between trait anxiety and both androgen and gonadotrophic hormone levels at rest and during severe physical exercise. Twelve volunteers were selected among 160 untrained male collegial students and classified as anxious (N = 6) or non-anxious (N = 6) subjects according to their scores on three trait-anxiety tests (STAI, IPAT, 16 PF). Serum delta 4-androgen (testosterone and delta 4-androstenedione), delta 5-androgen (DHEA and DHEA-SO4) and gonadotrophin (LH and FSH) concentrations were measured by radioimmunoassay before, during and after 20 minutes of intensive bicycle exercise (80% of maximal heart rate). Results indicate significantly lower serum delta 4-androgens in anxious subjects before exercise. However, for each subject and irrespective of his anxiety level, all measured serum androgen concentrations increased significantly during exercise, although delta 4-androstene-dione remained lower in anxious subjects than in non-anxious ones. Serum LH concentrations (but not FSH) were significantly higher in anxious subjects throughout the observation periods. However, exercise induced in each subject a significant decrease in the serum level of both gonadotrophic hormones. The results suggest that trait anxiety level may constitute an important factor that affects both pre-exercise and exercise serum androgen concentrations in untrained subjects.

Oxidation of a glucose polymer during exercise: comparison with glucose and fructose

The purpose of this study was to compare the oxidation of 13C-labeled glucose, fructose, and glucose polymer ingested (1.33 g.kg-1 in 19 ml.kg-1 water) during cycle exercise (120 min, 53 +/- 2% maximal O2 uptake) in six healthy male subjects. Oxidation of exogenous glucose and glucose polymer (72 +/- 15 and 65 +/- 18%, respectively, of the 98.9 +/- 4.7 g ingested) was similar and significantly greater than exogenous fructose oxidation (54 +/- 13%). A transient rise in plasma glucose concentration was observed with glucose ingestion only. However, plasma insulin levels were similar with glucose and glucose polymer ingestions and significantly higher than with water or fructose ingestion. Plasma free fatty acid and glycerol responses to exercise were blunted with carbohydrate ingestion. However, fat utilization was not significantly different with water (82 +/- 14 g), glucose (60 +/- 3 g), fructose (59 +/- 11 g), or glucose polymer ingestion (60 +/- 8 g). Endogenous carbohydrate utilization was significantly lower with glucose (184 +/- 22 g), glucose polymer (187 +/- 31 g), and fructose (211 +/- 18 g) than with water (239 +/- 30 g) ingestion. Plasma volume slightly increased with water ingestion (7.4 +/- 4.5%), but the decrease was similar with glucose (-7.6 +/- 5.1%) and glucose polymer (-8.2 +/- 4.6%), suggesting that the rate of water delivery to plasma was similar with the two carbohydrates.(ABSTRACT TRUNCATED AT 250 WORDS)

Sympatho-endocrine and metabolic responses to exercise under post-ganglionic blockade in rats

The purpose of this study was to further document the role of locally released norepinephrine (NE) in the control of metabolic and endocrine responses to exercise in rats. Post-ganglionic blockade with bretylium (20 mg.kg-1, i.v.) reduced NE release from sympathetic nerve endings and triggered a compensatory increase in epinephrine (E) release from the adrenal medulla, as reflected by plasma NE and E concentrations at rest and exercise (E/NE ratio = 2.92 +/- 0.53 and 2.48 +/- 0.51 vs 0.62 +/- 0.15 and 1.48 +/- 0.18 in control rats; mean +/- SE). Following bretylium administration a reduction in running time to exhaustion (28 m.min-1, 8% slope: 33 +/- 2 min vs 74 +/- 10 min) was associated with 1) a faster decrease in blood glucose concentration (3.58 +/- 0.80 mM vs 8.09 +/- 0.38 mM in control rats exercised for 33 min); and 2) an increased glycogen store utilization in fast-twitch muscles (superficial vastus lateralis and gastrocnemius lateralis). Glycogen utilization was not modified in soleus muscle and in the liver. Taken together these results suggest that post-ganglionic blockade increased carbohydrate store and peripheral blood glucose utilization. This could reflect an impairment in fat mobilization and utilization which might be secondary to a reduction of NE release in the adipose tissue and/or in the endocrine pancreas.

Electrophysiological evidence for a shared representational medium for visual images and visual percepts

Does mental imagery involve the activation of representations in the visual system? Systematic effects of imagery on visual signal detection performance have been used to argue that imagery and the perceptual processing of stimuli interact at some common locus of activity (Farah, 1985). However, such a result is neutral with respect to the question of whether the interaction occurs during modality-specific visual processing of the stimulus. If imagery affects stimulus processing at early, modality-specific stages of stimulus representation, this implies that the shared stimulus representations are visual, whereas if imagery affects stimulus processing only at later, amodal stages of stimulus representation, this implies that imagery involves more abstract, postvisual stimulus representations. To distinguish between these two possibilities, we repeated the earlier imagery-perception interaction experiment while recording event-related potentials (ERPs) to stimuli from 16 scalp electrodes. By observing the time course and scalp distribution of the effect of imagery on the ERP to stimuli, we can put constraints on the locus of the shared representations for imagery and perception. An effect of imagery was seen within 200 ms following stimulus presentation, at the latency of the first negative component of the visual ERP, localized at the occipital and posterior temporal regions of the scalp, that is, directly over visual cortex. This finding provides support for the claim that mental images interact with percepts in the visual system proper and hence that mental images are themselves visual representations.

Regional plasma catecholamine removal and release at rest and exercise in dogs

Dynamics of circulating catecholamines (CA) were studied at rest (heart rate = 104 +/- 3 beats/min) and during mild treadmill exercise (heart rate = 168 +/- 5 beats/min) in 60 dogs. Plasma epinephrine (E) and norepinephrine (NE) removal from circulation and release into circulation were estimated from plasma CA arteriovenous differences across the regional vascular beds studied (pulmonary, myocardial, hepatosplanchnic, renal, and skeletal muscle vascular beds) and from regional blood flows. Regional plasma E fractional extraction (PEFE) was used as an index of NE removal from plasma. Arterial plasma CA increased significantly from rest to exercise (P less than 0.05). A significant PEFE was observed at rest and exercise across all studied vascular beds but the pulmonary bed. When plasma flow was taken into account, the largest contributors to plasma CA removal were the hepatosplanchnic vascular bed at rest and skeletal muscle vascular beds during exercise. At rest, the hepatosplanchnic vascular bed was a major contributor to the plasma NE pool. During exercise, main contributors to NE release into plasma were skeletal muscle vascular beds. Circulating CA kinetics did not appear to vary from rest to exercise. Clearance and apparent distribution space were estimated to be, respectively, 1.5 l/min and 2 liters for circulating E and 2 l/min and 5 liters for NE at rest and exercise. Circulating E and NE half times were estimated to be approximately 1 and 1.8 min, respectively.

Epinephrine release from the heart during left stellate ganglion stimulation in dogs

Plasma epinephrine (E) and norepinephrine (NE) concentrations were measured (radioenzymatic assay) in blood samples simultaneously withdrawn from the aorta (Ao) and coronary sinus (CS) on 10 anesthetized dogs immediately before and during a 1-min period of electrical stimulation of the left stellate ganglion (4 V, 4 ms, 10 Hz). Heart rate and systolic blood pressure significantly increased in response to electrical stimulation (152 +/- 8 to 180 +/- 15 beats/min and 128 +/- 12 to 149 +/- 12 mmHg, mean +/- SE; P less than 0.05). Plasma NE concentrations were not significantly different in the Ao and the CS (432 +/- 110 and 319 +/- 67 pg/ml) before the stimulation, whereas a net removal of E was present across the myocardium (Ao, 172 +/- 61; CS, 71 +/- 22 pg/ml). A large NE spillover in the CS was observed during the stimulation (Ao, 1,555 +/- 513; CS, 10,583 +/- 3,753 pg/ml). A significant output of E from the myocardium was also present (Ao, 165 +/- 42; CS, 291 +/- 74 pg/ml) during the stimulation. Determination of NE and E concentrations by high-performance liquid chromatography in five of the dogs confirmed the observation made with the radioenzymatic assay, i.e., a significant uptake (66%) of blood-borne E was present across the myocardium in the control situation (Ao, 320 +/- 97; CS, 110 +/- 23 pg/ml), whereas plasma E concentrations in the CS (280 +/- 61 pg/ml) were 1.5 times the values found in Ao (184 +/- 56 pg/ml) under electrical stimulation. These observations give further support to the hypothesis that endogenous tissue E can act as a cotransmitter of sympathetic fibers.

Correlation between ventilatory threshold and endurance capability in marathon runners

The purpose of the study was to develop an index of endurance capability [i.e., "the ability to sustain a high fractional utilization of maximal oxygen uptake (VO2max) for a prolonged period of time"]. The index was based on the linear reduction of fractional utilization of VO2max with total running time greater than 7 min plotted on a log scale. The endurance index estimated from VO2max, running efficiency and the marathon performance of 18 male runners (30 +/- 7 yr old; VO2max = 66 +/- 5 ml.kg-1.min-1) ranged between -4.07 and -9.96% VO2max.1 nt-1 (mean +/- SD = -6.40 +/- 1.50) and was not related to VO2max (r = 0.107) or speed in the marathon race (r = 0.354). However, the endurance index was closely related (r = 0.853) to the fractional utilization of VO2max at ventilatory threshold (breakaway of the excess CO2 elimination curve) which occurred at 76.1 +/- 5.5% VO2max in response to a graded treadmill test. These results indicate that: (i) running time on long distance races is not, per se, an adequate measure of endurance capability because of the major contribution of VO2max to long distance running performance; (ii) the endurance index expressed as %VO2max.1n t-1 is an objective and independent index of endurance capability; and (iii) runners with a high endurance capability tend to hyperventilate at higher relative workload during a graded treadmill test.

Evidence for an interference of selective face ventilation on hyperprolactinemia induced by hyperthermic treadmill running

Selective face ventilation, known to interfere with bloodstreamed temperature signals, should alter exercise-induced prolactinemic (PRL) responses if, as recently suggested, the latter responses are associated with body temperature increases generated by working muscles. To test this hypothesis, 15 trained adult male and female volunteers were submitted to 45-min hyperthermic treadmill runs with and without selective face ventilation. Tympanic (Tt) and rectal (Tr) temperatures were measured in these experiments, and serum immunoreactive PRL was assayed on venous blood sampled immediately before and immediately after the exercise. Hyperthermic running induced significant Tr elevations whether selective face ventilation was present or not. In the absence of face ventilation, serum PRL rose markedly in 11 of the 15 hyperthermic runners, the lack of response in 4 runners confirming that exercise per se is not necessarily hyperprolactinotrophic. When the 11 responders (11/15) ran with face ventilation, serum PRL response was abolished in 6 of them, indicating a significant interference from face ventilation on temperature signals streamed through carotid blood; serum PRL-maintained responses in 5 of these 11 ventilated runners suggest the absence of a learning effect. It is concluded that the blood-streamed temperature signals arising from working muscles represent an important but not a unique determinant of blood PRL response during aerobic running. The contribution of TRH and plasma volume changes to blood PRL variations during hyperthermic running appeared nonsignificant.

Effects of exercise training on plasma catecholamines and blood pressure in labile hypertensive subjects

Plasma catecholamine concentrations (norepinephrine, NE; epinephrine, E) were measured along with heart rate (HR) and blood pressure (BP) at rest in supine (20 min) and standing (10 min) positions and in response to cycle ergometer exercise (5 min; 60% estimated maximal aerobic power) in 12 hypertensive patients before and after 20 weeks of aerobic training on cycle ergometer (six males, one female) or by jogging (five males). In a control group of labile hypertensive patients (five males, two females), estimated maximal aerobic power as well as HR and BP at rest in the supine and standing positions and in response to exercise were not modified from the first to the second evaluation (43 +/- 4 vs 43 +/- 5 ml.kg-1.min-1). In comparison estimated maximal aerobic power significantly increased in both training groups (cycle: 38 +/- 4 to 43 +/- 4; jogging: 38 +/- 3 to 46 +/- 4 ml.kg-1.min-1). However HR and BP were not modified following training, except for small reductions in systolic (18.9 to 18 kPa: 142 to 135 mmHg) and diastolic pressures (13.3 to 12 kPa: 100 to 90 mmHg) (p less than 0.05) at standing rest in the cycle group.(ABSTRACT TRUNCATED AT 250 WORDS)

Inhibition of exercise-induced blood prolactin response by acute hypoxia

Prolactin (PRL) secretion is regulated by a variety of factors, most of them being known for their enhancing effects on blood PRL levels. This study describes the inhibitory influence of an acute exposure to hypoxia (14.5% O2) on the blood PRL response induced by graded maximal exercise in eight trained male subjects.

[Hormonal responses to repeated lactic acid anaerobic exercise in male subjects]

The hormonal response to repeated lactic acid anaerobic exercise was investigated in 6 young male adults. The exercise protocol consisted of 3 one-minute bouts of voluntary maximal effort, each bout being separated from the subsequent one by a two-minute rest period. Venous blood samples were obtained at rest and at the end of each of the 3 work bouts, as well as following 15 minutes of recovery. A marked increase in plasma catecholamine concentrations was observed in response to the repeated exercise bouts, the rise being more important for the adrenaline (x 22) than the noradrenaline (x 10) concentrations. A progressive increase in plasma somatotropin hormone was observed between the first and the last venous sampling. Moreover, a delayed rise in plasma cortisol, insulin, prolactin, and androstenedione was also observed. Hormonal concentrations of LH, FSH, DHEA-SO4, testosterone, SHBG and testosterone/SHBG ratio were not modified in response to the type of exercise.

Echocardiographic assessment of left ventricular performance before and after marathon running

Echocardiography was used to indirectly assess the effects of marathon running on myocardial performance. Thirteen marathon runners (mean +/- SEM:30 +/- 1.6 years) were submitted to a resting echocardiographic examination before racing and during early recovery from marathon racing. Indices of left ventricular performance were computed from M-mode recordings of left ventricular dimensions and aortic valve motions. Comparison of basal and post-marathon indices of left ventricular performance showed no significant differences in either pre-ejection period (PEP), left ventricular ejection index (LVEI), fractional shortening (% delta D), ejection fraction (EF), or mean rate of circumferential fiber shortening (mVcf). Cardiac output (Qc) computed from left ventricular end-diastolic (LVEDV) and end-systolic volumes (LVESV) were significantly higher following marathon running (4.9 +/- 0.4 to 6.7 +/- 0.7 L/min) because of a marked increase in resting heart rate (HR) (58 +/- 3 to 76 +/- 3 bpm). A significant decrease in systolic blood pressure (118 +/- 4 to 108 +/- 3 mm Hg), associated with a slight reduction in calculated total peripheral resistance was also observed after the race. These circulatory adjustments probably reflect thermoregulatory activity that allows a greater blood flow to the skin for heat dissipation, as well as persistence of reactive muscle hyperemia. Echocardiographic evidence suggests that marathon running does not lead to marked impairments in left ventricular performance. However, the absence of change in the end-systolic volume, despite a marked reduction in cardiac afterload, may suggest a slight alteration in contractility that could not be detected with the use of echocardiography.

Metabolic response to [13C]glucose and [13C]fructose ingestion during exercise

Seven healthy male volunteers exercised on a cycle ergometer at 50 +/- 5% VO2max for 180 min, on three occasions during which they ingested either water only (W), [13C]glucose (G), or [13C]fructose (F) (140 +/- 12 g, diluted at 7% in water, and evenly distributed over the exercise period). Blood glucose concentration (in mM) significantly decreased during exercise with W (5.1 +/- 0.4 to 4.2 +/- 0.1) but remained stable with G (5.0 +/- 0.4 to 5.3 +/- 0.6) or F ingestion (5.4 +/- 0.5 to 5.1 +/- 0.4). Decreases in plasma insulin concentration (microU/ml) were greater (P less than 0.05) with W (11 +/- 3 to 3 +/- 1) and F (12 +/- 4 to 5 +/- 1) than with G ingestion (11 +/- 2 to 9 +/- 5), and fat utilization was greater with F (103 +/- 11 g) than with G ingestion (82 +/- 9 g) and lower than with W ingestion (132 +/- 14 g). However F was less readily available for combustion than G; over the 3-h period 75% (106 +/- 11 g) of ingested G was oxidized, compared with 56% (79 +/- 8 g) of ingested fructose. As a consequence, carbohydrate store utilizations were similar in the two conditions (G, 174 +/- 20 g; F, 173 +/- 17 g; vs. W, 193 +/- 22 g). These observations suggest that, during prolonged moderate exercise, F ingestion maintains blood glucose as well as G ingestion, and increases fat utilization when compared to G ingestion. However, due to a slower rate of utilization of F, carbohydrate store sparing is similar with G and F ingestions.

Metabolic and endocrine responses to graded exercise under acute hypoxia

Eight male subjects (24 +/- 1 years old) performed graded ergocycle exercises in normoxic (N) and acute hypoxic (H) conditions (14.5% O2). VO2max decreased from 55.5 +/- 1.3 to 45.8 +/- 1.4 ml . kg-1 . min-1 in H condition. Plasma glucose and free fatty acid concentrations remained unchanged throughout exercise in both conditions. Increase in blood lactate concentration was associated with relative workload in both conditions. At VO2max lactate concentrations were similar in the two conditions, plasma insulin, glucagon, and LH concentrations did not significantly change in either. Plasma delta 4-androstenedione and testosterone increased in a similar manner in both conditions. Finally plasma norepinephrine concentration reached at VO2max was significantly lower in hypoxia. These results suggest that acute moderate hypoxia does not affect metabolic and hormonal responses to short exercise performed at similar relative workloads, i.e. when the reduction of VO2max due to hypoxia is taken into consideration. The lower catecholamine response to maximal exercise under acute hypoxia might suggest that the sympathetic response could be related to relative as well as absolute workloads.

Sympathetic response to maximal bicycle exercise before and after leg strength training

Plasma catecholamine concentrations at rest and in response to maximal exercise on the cycle ergometer (278 +/- 15 watts, 6 min duration) have been measured on seven young active male subjects (19 +/- 1 years old; 80 +/- 3 kg; 176 +/- 3 cm) prior to and after a eight week leg strength training program (5RM, squat and leg press exercise). Strength training resulted in a significant increase in performance on squat (103 +/- 3 to 140 +/- 5 kg) and leg press exercise (180 +/- 9 to 247 +/- 15 kg) associated with a small significant increase in lean body mass (64.5 +/- 2.2 to 66.3 +/- 2.1 kg) and no change in maximal oxygen consumption (47.5 +/- 1.3 to 46.9 +/- 1.2 ml X kg-1 X min-1). Plasma norepinephrine (NE) and epinephrine (E) concentrations (pg X mL-1) were not significantly different before and after training at rest (NE: 172 +/- 19 vs 187 +/- 30; E: 33 +/- 10 vs 76 +/- 16) or in response to maximal exercise (NE: 3976 +/- 660 vs 4163 +/- 1081; E: 1072 +/- 322 vs 1321 +/- 508). Plasma lactate concentrations during recovery were similar before and after training (147 +/- 5 vs 147 +/- 15 mg X dL-1). Under the assumption that the "central command" is reduced for a given absolute workload on the bicycle ergometer following leg strength training, these observations support the hypothesis that the sympathetic response to exercise is under the control of information from muscle chemoreceptors.

Reproducibility of plasma catecholamine concentrations at rest and during exercise in man

The purpose of this study was to test the reproducibility of plasma norepinephrine (NE) and epinephrine (E) concentrations, at rest and during exercise, in man. Twelve young men were evaluated on two occasions (one week apart) at rest in supine and sitting positions and during dynamic exercise on bicycle ergometer: 5 min at a low intensity workload (heart rate = 131-133 bt min-1) and 5 and 20 min at a higher intensity (174-175 bt min-1). Mean plasma NE and E concentrations were not significantly different (p less than 0.05) on the two occasions in any of the experimental situations. However large within-subject variations were present, and the "standard errors of a single measurement" corrected for the variability of the catecholamine assay, ranged from 14 to 50% for NE and 14 to 37% for E. These results indicate that the mean plasma NE and E concentrations observed in a group of subjects are reproducible from one week to the other, but that individual plasma NE and E concentrations are not. This lack of reliability of a single determination of plasma catecholamine concentrations might be due to cyclic variations of plasma NE and E concentrations over time.

Plasma catecholamines at rest and exercise in subjects with high- and low-trait anxiety

The purpose of this study was to compare the plasma catecholamine concentration at rest and in response to exercise in subjects with low and high trait anxiety (TA). Six subjects with low TA and six subjects with high TA were selected among 149 males college students on the basis of their results on three TA tests (STAI, IPAT, 16 PF). Plasma norepinephrine (NE) and epinephrine (E) concentrations (pg/ml) were measured at rest in supine position and during mild and moderate exercises of 5 min duration (about 40% and 60% of the individual VO2max) on bicycle ergometer. Plasma E concentrations at rest and exercise were not significantly different in subjects with low (33 +/- 6, 82 +/- 11, and 197 +/- 49) or high TA (41 +/- 7, 62 +/- 13, and 229 +/- 52). Plasma NE concentration was not significantly different at rest and in response to mild exercise in low (235 +/- 52; 666 +/- 64) and high-TA subjects (223 +/- 36; 610 +/- 88) but was significantly higher in high-TA than in low-TA subjects in response to moderate exercise (2510 +/- 618 vs. 1243 +/- 234). These results show 1) that plasma NE and E concentrations at rest and in response to light exercise are similar in low- and high-TA subjects, and 2) that subjects with high TA have a greater plasma NE response to the psychologic stress and/or to the homeostatic challenge of moderate exercise.

Exercise-induced blood prolactin variations in trained adult males: a thermic stress more than an osmotic stress

Blood prolactin (PRL) variations have been linked to temperature and osmotic changes in several species. The latter factors are here explored to better understand blood PRL responses frequently induced during physical exercise. Since body heat generated by exercise can lead to marked body fluid shifts, it was postulated that PRL changes observed during exercise could be associated with variations in body temperature and/or blood osmolality (OSM). A wide range (38.5-40.5 degrees C) of rectal temperatures (Tr; used here to appreciate core temperatures) were theoretically selected and randomly assigned as targets to male runners. Measured by thermistor probe, target Tr were obtained by a combination of factors: (a) increases heat production by treadmill running, and (b) decreases heat losses by appropriate clothing (decreases evaporation) in warmed (decreases radiation) and hypoventilated (decreases convection) laboratory conditions. For each subject, target Tr was attained not prior to 30 min after initiation of running, and had to be maintained for at least 10 min, for a mean (+/- SD) running time of 52.6 +/- 10.0 min. In a first protocol, hypohydration was provoked in 26 runners (23.9 +/- 4.7 years) by total restriction of water intake. In a second protocol (10 different runners: 22.3 +/- 3.3 years), euhydration was maintained by water intake (20 ml/kg body weight). Venous blood was sampled at rest before and immediately after the run. PRL was assayed by RIA; OSM was measured by freezing point depression; sodium was analyzed by flame photometry. At rest, before the heat-producing exercise, mean PRL values were 9.4 +/- 3.4 ng/ml for both eu/hypohydrated groups.(ABSTRACT TRUNCATED AT 250 WORDS)

Free and conjugated catecholamines in plasma and erythrocytes of normotensive and labile hypertensive subjects during exercise and recovery

Several lines of investigation suggest an abnormal sympathetic nervous activity (SNA) in hypertension. In an attempt to better evaluate SNA in a subgroup of hypertensive patients, free and sulpho-conjugated (conjugated) catecholamines (CA) [norepine-phrine (NE) and epinephrine (E)] were measured in plasma and red blood cells (RBC) of 10 labile hypertensive subjects at rest, during dynamic exercise and during recovery. Results were compared with the levels observed in seven normotensive subjects. At a given heart rate during the first 15 min of exercise, free plasma CA and diastolic blood pressure were significantly greater in labile hypertensives. Throughout the 1 h of exercise, conjugated plasma CA increased only in labile hypertensives, while free RBC NE increased only in normotensives. During recovery, free plasma CA decreased more slowly and blood pressure remained higher in labile hypertensives. These observations indicate that the mechanisms regulating sulphoconjugation may be altered in labile hypertensives and also suggest a defect in RBC CA transport mechanisms in these subjects. It is possible that these defects could contribute to the higher CA levels observed in labile hypertensives during exercise and recovery, and that they could be linked with the slower cardiovascular recovery observed in these subjects.

Plasma norepinephrine, epinephrine, and dopamine beta-hydroxylase activity during exercise in man

Many experimental studies have utilized the activity of dopamine-beta-hydroxylase (DBH) as an index of sympathetic activity, since this enzyme is not submitted to uptake mechanisms or to enzymatic metabolism as are the circulating catecholamines norepinephrine (NE) and epinephrine (E). However, large discrepancies have been found between the results of these studies. The hypothesis which is examined in this study is that these discrepancies might arise from the different intensities in the stimuli utilized. In order to examine this possibility, plasma DBH activity was measured in seven subjects at rest and in three different conditions known to increase sympathetic activity to varying degrees, i.e., during hand-grip, standing, and supra-maximal bicycle exercise. Plasma NE and E concentrations were also measured during these stimuli. The results of this study show that DBH activity increases above resting levels only during supramaximal dynamic exercise, while plasma NE and E concentrations increase during each experimental condition. Furthermore, the increases in NE and E are related to each other and are also related to heart rate when all experimental conditions are considered. On the contrary, the variations in plasma DBH (expressed as a percentage of the resting value) are not related to other sympathetic indices or to heart rate. Since NE and E vary little from subject to subject at rest and increase discretely in response to the various stimuli, these plasma catecholamine concentrations therefore appear to represent the most accurate indices of sympathetic activity.

Effects of muscle CHO-loading manipulations on hormonal responses during prolonged exercise

This study examined the effects of a pre-experimental period of muscle carbohydrate (CHO)-loading manipulations followed by a 24-h CHO-poor diet, intended to increase muscle glycogen content and reduce hepatic glycogen levels, on substrate and endocrine responses during a period of prolonged exercise. Seven subjects pedaled a cycle ergometer for 70 min at 64% leg VO2max (1) after normal CHO intake (CHON) and (2) after leg muscle CHO loading (CHOL), both of these procedures being followed by a period of arm exercise (70 min; 70% arm VO2max) and 24 h CHO-poor intake. CHON, as compared to CHOL condition, resulted in greater blood concentrations of free fatty acids (1.8 vs 1.3 mmol X L-1), glycerol (0.41 vs 0.28 mmol X L-1), norepinephrine (2.2 vs 1.5 ng X ml-1), epinephrine (0.90 vs 0.27 ng X ml-1), and cortisol (47 vs 23 g X dl-1) at min 70 of exercise. Insulin concentrations during exercise showed a strong tendency to be lower in CHON than in CHOL condition, although the differences were not significant. There were no significant differences between the two conditions in blood glucose, lactate, and glucagon concentrations. These data indicate that muscle CHO-loading manipulations intended to specifically increase the muscle glycogen content are associated with the difference in metabolic adaptation and hormonal changes during exercise.