雄性大鼠长期有氧运动期间血液铁状态与饮食铁含量的关系*

背景：运动对雌性大鼠血液铁状态的影响也已经得到广泛研究,但运动对雄性大鼠血液铁状态的影响仍不明确。 目的：观察不同铁含量饮食以及游泳运动对雄性大鼠血液铁状态的影响。 方法：断乳雄性SD大鼠90只,分为饮食低铁含量组、标准铁含量组、高铁含量组。每组再分为运动组和静息组。用不同的铁含量饲料喂养1个月后,运动组开始游泳,每天1次,持续3个月,静息组除不做运动外,其余处理同对应运动组。最后1次运动后,大鼠空腹24 h,戊巴比妥钠麻醉下取静脉血测定红细胞相关指标和血清铁状态指标。 结果与结论：饮食铁含量对红细胞和血清铁状态指标的主效应都有显著影响,运动对红细胞分布宽度、血浆总铁结合力的主效应也显著影响。饮食低铁含量静息组表现为铁缺乏性贫血的典型改变,而运动组血清铁和转铁蛋白饱和度显著降低,血浆总铁结合力显著增大,说明低铁饮食情况下运动加重了血液低铁状态。饮食标准铁含量、高铁含量的运动组都表现为红细胞分布宽度显著增大,血浆总铁结合力显著增大,但其他指标均无显著改变,说明运动没有导致血液低铁状态。     

Atrial natriuretic peptide during and after maximal and submaximal exercise under normoxic and hypoxic conditions

Summary The present study was designed to investigate the influence of exercise intensity and duration as well as of inspiratory oxygen content on plasma atrial natriuretic peptide concentration ([ANP]) and furthermore to compare ANP with the effect on aldosterone concentration ([Aldo]). Ten untrained male subjects performed a maximal exercise test (ME) on a cycle ergometer and a submaximal test of 60-min duration at 60% of maximal performance (SE) under normoxia (N) and normobaric hypoxia (H) (partial pressure of oxygen: 12.3 kPa). Five subjects were exposed to hypoxia at rest for 90 min. The [ANP] was mostly affected by exercise intensity (5 min after ME-N, +298.1%, SEM 39.1%) and less by exercise duration (at the end of SE-N: +229.5%, SEM 33.2%). Hypoxia had no effect at rest and reduced the exercise response (ME-H, +184.3%, SEM 27.2%; SE-H, +172.4%, SEM 15.7%). In contrast to ANP, the Aldo response was affected more by duration at submaximal level (+290.1%, SEM 34.0%) than by short maximal exercise (+235.7%, SEM 22.2%). Exposure to hypoxia rapidly decreased [Aldo] (–28.5%, SEM 3.7% after 30 min, P<0.01), but did not influence the exercise effects (ME-H, +206.2%, SEM 26.4%; SE-H, +321.6%, SEM 51.6%). The [ANP] increase was faster than that of [Aldo] during the maximal tests and there was no difference during submaximal exercise. Changes in plasma volume (PV), sodium concentration, and osmolality (Osm) were most pronounced during maximal exercise (for ME-N: PV –13.1%, SD 3.6%, sodium +6.2 mmol·1^–1, SD 2.7, Osm +18.4 mosmol·kg H₂O^–1, SD 6.5). Regression analysis showed high correlations between changes in [ANP] and in Osm during and after maximal exercise and between changes in [ANP] and heart rate for submaximal exercise. It is concluded that besides other mechanisms increased Osm might be involved in the exercise-dependent increase of plasma [ANP].     

Cardiovascular,hormonal and body fluid changes during prolonged exercise

Summary During prolonged heavy exercise a gradual upward drift in heart rate (HR) is seen after the first 10 min of exercise. This secondary rise might be caused by a reduction in stroke volume due to reduced filling of the heart, which is dependent upon both hemodynamic pressure and blood volume. Swimming and bicycling differ with respect to hydrostatic pressure and to water loss, due to sweating. Five subjects were studied during 90 min of bicycle exercise, and swimming the leg kick of free style. The horizontal position during swimming resulted in a larger cardiac output and stroke volume. After the initial rise in heart rate the secondary rise followed parallel courses in the two situations. The rises were positively related to the measured increments in plasma catecholamine concentrations, which continued to increase as exercise progresssed. The secondary rise in HR could not be explained by changes in plasma volume or in water balance, nor by changes in plasma [K]. The plasma volume decreased 5–6% (225–250 ml) within the first 5 to 10 min of exercise both in bicycling and swimming, but thereafter remained virtually unchanged. The sweat loss during bicycling was four times greater than during swimming; but during swimming the hydrostatic conditions induced a diuresis, so that the total water loss was only 25% less than during bicycling.     

Low dosage monophasic oral contraceptive use and intermittent exercise performance and metabolism in humans

Nine untrained women using low dosage monophasic oral contraceptives (OC) performed an intermittent treadmill test on two different occasions within one pill-cycle to determine the effect of OC on performance and some commonly used metabolic markers. The first test was performed after 5–8 days of resuming the OC agents after menstrual bleeding while the other test was performed after 19–21 days. Performance time on the final exhausting run of six intermittent high intensity 20 s runs was no different between trials [mean days 5–8: 22.3 (SEM 1.2) s vs days 19–21: 22.7 (SEM 1.1) s]. There was no difference in heart rate [peak heart rate days 5–8: 183 (SEM 3) beats^.min^–1 vs days 19–21: 186 (SEM 2) beats^.min^–1], oxygen consumption during any run [run 5 of days 5–8: 1,392 (SEM 51) ml·min^–1 vs run 5 of days 19–21: 1,494 (SEM 3) ml·min^–1] or in any of the metabolic variables measured at any time in venous blood [peak blood lactate concentration days 5–8: 8.4 (SEM 0.3) mmol·l^–1 vs days 19–21: 8.1 (SEM 0.5) mmol·l^–1; peak blood glycerol concentration days 5–8: 0.39 (SEM 0.02) mmol·l^–1 vs days 19–21: 0.38 (SEM 0.02) mmol·l^–1; resting free fatty acids concentration days 5–8: 0.25 (SEM 0.05) mmol·l^–1 vs days 19–21: 0.29 (SEM 0.07) mmol·l^–1; peak blood glucose concentration days 5–8: 6.7 (SEM 0.5) mmol·l^–1 vs days 19–21: 6.6 (SEM 0.2) mmol·l^–1; peak capillary blood ammonia concentration days 5–8: 139 (SEM 18.3) μmol·l^–1 vs days 19–21: 170 (SEM 18.0) μmol·l^–1]. These results suggest neither intermittent high intensity exercise performance nor energy metabolism change between days 5–8 and days 19–21 of a low dosage monophasic OC pill during one pill-cycle. Electronic Publication     

Body fluid homeostasis and cardiovascular adjustments during submaximal exercise: influence of chewing coca leaves

The present study was undertaken to determine the haematological and cardiovascular status, at rest and during prolonged (1?h) submaximal exercise (approximately 70% of peak oxygen uptake) in a group (n?=?12) of chronic coca users after chewing approximately 50?g of coca leaves. The results were compared to those obtained in a group (n?=?12) of nonchewers. At rest, coca chewing was accompanied by a significant increase in heart rate [from 60 (SEM?4) TO 76?(SEM?3) beats?·?min^?1], in haematocrit [from 53.2 (SEM 1.2) to 55.6 (SEM 1.1)%] in haemoglobin concentration, and plasma noradrenaline concentration [from 2.8 (SEM?0.4) to 5.0?(SEM?0.5)?μmol?·?l^?1]. It was calculated that coca chewing for 1?h resulted in a significant decrease in blood [?4.3?(SEM?2.2)%] and plasma [?8.7?(SEM?1.2)%] volume. During submaximal exercise, coca chewers displayed a significantly higher heart rate and mean arterial blood pressure. The exercise-induced haemoconcentration was blunted in coca chewers compared to nonchewers. It was concluded that the coca-induced fluid shift observed at rest in these coca chewers was not cumulative with that of exercise, and that the hypovolaemia induced by coca chewing at rest compromised circulatory adjustments during exercise.     

Kinetics of heart rate and catecholamines during exercise in humans

Summary To elucidate the role of factors other than the nervous system in heart rate (f _c) control during exercise, the kinetics off _c and plasma catecholamine concentrations were studied in ten heart transplant recipients during and after 10-min cycle ergometer exercise at 50 W. Thef _c did not increase at the beginning of the exercise for about 60 s. Then in the eight subjects who completed the exercise it increased following an exponential kinetic with a mean time constant of 210 (SEM 22) s. The two other subjects were exhausted after 5 and 8 min of exercise during whichf _c increased linearly. At the cessation of the exercise,f _c remained unchanged for about 50 s and then decreased exponentially with a time constant which was unchanged from that at the beginning of exercise. In the group of eight subjects plasma noradrenaline concentration ([NA]) increased after 30 s to a mean value above resting of 547 (SEM 124) pg · ml^–1, showing a tendency to a plateau, while adrenaline concentration ([A]) did not increase significantly. In the two subjects who became exhausted an almost linear increase in [NA] occurred up to about 1,300 pg · ml^–1 coupled with a significant increase in [A]. During recovery an immediate decrease in [NA] was observed towards resting values. The values of thef _c increase above resting levels determined at the time of blood collection were linearly related with [NA] increments both at the beginning and end of exercise with a similar slope, i.e. about 2.5 beats · min^–1 per 100 pg · ml^–1 of [NA] change. These findings would seem to suggest that in the absence of heart innervation the increase inf _c depends on plasma [NA].     

Alpha and beta adrenergic sensitivity in trained and untrained albino rats

The effects on the blood pressure and heart rate responses of different adrenergic stimulants (norepinephrine, sympathomim, epinephrine and isoproterenol) and blocking agents (phenoxybenzamine and propranolol) were studied in control (N = 55) and exercising (N = 52) albino rats under anaesthesia. The test rats exercised by regular swimming for 10–14 weeks.Alpha stimulation and beta blocking produced smaller responses while alpha blocking and beta stimulation were followed by greater changes after training as compared with the control animals. The assumption of a modified adrenergic receptor sensitivity could not be substantiated by the results; the observations indicate rather a complex change in the autonomous regulation following regular physical exercise.     

Effect of ingestion pattern on rehydration and exercise performance subsequent to passive dehydration

Six male volunteers performed three tests, each comprising a passive heating session to obtain dehydration (loss of 2.6% body mass), followed by exercise on a treadmill until exhaustion (50% of maximal oxygen consumption) in a warm environment (dry bulb temperature 35° C, relative humidity 20%–30%). In one test, the subjects exercised without rehydration (Dh). In the two other tests, 50% of the fluid lost in the dehydration session was replaced by drinking mineral water given either in one amount [913 (SEM 23) ml] before the exercise (Rh1) or divided into four equal portions [228 (SEM 5) ml] before the exercise and on three occasions at 15-min intervals during exercise (Rh4). Rehydration increased exercise duration in Rh1 compared to Dh [112 (SEM 7) min and 82 (SEM 3) min, respectively;P < 0.05]. The difference was not significant with Rh4 [103 (SEM 9) min]. A restoration of the time course of changes in plasma volume, plasma osmolality, heart rate and rectal temperature occurred immediately in Rh1 and was delayed in Rh4 until after 60 min of exercise. Our results demonstrated that the swift replacement of the fluid loss in the dehydrated subjects was beneficial to exercise performance by rapidly correcting the disturbances in body fluid balance.     

Effects of lycium on liver cellular ultrastructure and antioxidant activity of rats under tolerance training

64 eight-week-old female rats were randomly divided into to 8 groups with four in medical treatment group and four in control group. The treatment groups were trained by progressive intensifying endurance swimming, and the medical-taken groups were fed with lycium for 5 weeks, and then the changes of the liver cellular free radical metabolism and ultrastructure were investigated. The effects of lycium and endurance training on liver cellular ultrastructure and free radical metabolism in rats were then explored. The results showed that exhaustive swimming time of rats could be extended by endurance training, and that exhaustive swimming time of rats could significantly be prolonged after taking lycium, and the ultrastructure of liver cell with taking lycium was more complete than that without taking lyceum. Lycium could cause significant increase of the activity of liver superoxide dismutase (SOD) and the ratio of SOD/MDA, and meanwhile cause decrease of the content of liver MDA. Conclusions can be drawn that lycium and endurance training can improve exercise capacity of rats, and lycium has certain protecting functions of the liver.     

Effects of prolonged exercise on the contractile properties of human quadriceps muscle

The contractile properties of the quadriceps muscle were measured in seven healthy male subjects before, during and after prolonged cycling to exhaustion. Special efforts were made to obtain measurements immediately after exercise. The exercise intensity corresponded to about 75% of estimated maximal O₂ uptake and time to exhaustion was mean 85 (SEM 9) min. At the end of the cycling heart rate and perceived exertion for the legs were 94% and 97% of maximal values, respectively. Maximal voluntary isometric force (MVC) had decreased after 5 min of exercise to a mean 91 (SEM 4)% of the pre-exercise value (P < 0.05) and decreased further to a mean 82 (SEM 6) and mean 66 (SEM 5)% after 40-min cycling and at exhaustion, respectively. A new finding was that during recovery reversal of MVC occurred in different phases where the half recovery time of the initial rapid phase was about 2 min. The MVC was a mean 80 (SEM 2)% of the pre-exercise value after 30 min and was not affected by superimposed electrical stimulation. Maximal voluntary concentric and eccentric forces decreased to 74% and 80% o of initial values at exhaustion (P < 0.05). The kinetics of isometric contraction expressed as the time between 5% and 50% of tension (rise time) and the time between 95% and 50% of tension (relaxation time) were not significantly affected by the prolonged cycling. The electromechanical delay measured as the time between the first electrical stimulus and 5% of tension decreased from a mean 32 (SEM 1) ms at rest to a mean 26.6 (SEM 0.6) ms at fatigue (P < 0.05). It is concluded that prolonged exhausting cycling results in reduced force-generating capacity during isometric, concentric and eccentric conditions. The absence of a slowing of relaxation and the incomplete reversal of MVC after 30 min of recovery indicate that the mechanism(s) of fatigue during prolonged exercise involve other components than those involved during high intensity exercise.     

The effect of short and long duration exercise on serum erythropoietin concentrations

Summary The effects of short and long duration exercise on serum erythropoietin concentrations [EPO]_s were studied in seven male cross-country skiers of national team standard and eight male marathon runners, respectively. The short duration exercise was performed as 60 min of cycling at an intensity of 80%–95% of maximal heart rate. Arterial blood oxygen saturations monitored by pulse-oximetry remained unchanged throughout exercise. The partial pressure of O₂ at which haemoglobin was half-saturated with O₂ calculated from forearm venous blood gas tension and blood O₂ saturation, and the erythrocyte 2,3-diphosphoglycerate did not change significantly during the exercise. Blood lactate concentrations were increased at the end of exercise [from 1.3 (SEM 0.1) to 3.6 (SEM 0.3) mmol · 1^–1]. The [EPO]_s determined (by enzyme-linked immunosorbent assay) pre-exercise, 5 min, 6 h, 19 h, and 30 h after the exercise were unchanged [from 16.1 (SEM 2.6) to 19.1 (SEM 3.2), 17.9 (SEM 3.0), 17.0 (SEM 2.5), and 18.6 (SEM 2.9) U·l^–1, respectively]. The [EPO]_s were not correlated to the earlier parameters. The long duration exercise consisted of habitual training, a 3 week break from training followed by 2 and 4 weeks of re-training. The [EPO]_s, body fat (BF), and serum free-testosterone concentrations determined at the end of each period remained unchanged. The maximal oxygen uptakes were decreased after the break from training and increased during retraining (P=0.04). Body mass (m _b) increased after the break in training (P=0.02). The [EPO]_s were correlated to BF,r=0.42,P=0.02;m _b,r=0.45,P=0.01; and free-testosterone concentrations,r=0.44,P=0.01. Thus, short and long-duration exercise had no direct influence on [EPO]_s; but relationships among [EPO]_s, free-testosterone concentrations and body composition were noted.     

Effect of creatine supplementation on cardiac muscle of exercise-stressed rats

The role of creatine supplementation in altering the physiological parameters regulating cardiac muscle's functional capacity through the initiation of cardiac hypertrophy and altered contractile protein expression has not been determined. The purpose of this study was to determine the effect of creatine supplementation, with and without exercise stress, on physiological parameters regulating functional capacity through alterations in rat cardiac mass and contractile-protein expression. Thirty male Sprague-Dawley rats were subjected to 30 min of exercise stress 5 days/week for 3 weeks with 2% of total body mass attached to the tail. Animals were randomly assigned to one of four treatment groups: group 1 (Con) received (1 ml/day) sucrose water by intubation tube (n=8); group 2 (Cr) received (1 ml/day) sucrose/creatine solution (n=6); group 3 (EX) received 1 ml/day sucrose water and the exercise stimulus (n=8), and group 4 (Cr/EX) received (1 ml/day) sucrose/creatine solution and the exercise stimulus (n=8). At the conclusion of the 21-day exercise-training period, the heart was collected and weighed for determination of wet weight, total protein, total RNA, and myosin heavy chain protein expression. RNA concentration decreased significantly (13%) in the EX group, but not in the CR/EX group, indicating an interactive effect of creatine and exercise. Total RNA significantly decreased (15%) in the EX group. Protein concentration significantly increased (9%) in the exercising treatments, while total protein did not change. Cardiac myosin heavy chain expression significantly shifted towards a predominant expression of the β-isoform in the Cr/EX group [54.53% (3.42) β]. These results indicate an interaction of creatine supplementation and swimming exercise stress that potentially alters cardiac protein synthesis and demonstrates a possible mechanism through which the combination of creatine supplementation and swimming stress stimuli act to alter the physiological parameters regulating cardiac functional capacity. Electronic Publication     

Effects of Prolonged Aerobic Exercise on Myocardial Responses to Ischaemia-Reperfusion in the Rat

The effects of low-intensity, prolonged swimming on functional recovery of the rat heart (Langendorff preparations) from ischaemia-reperfusion (I/R) were investigated. Three groups of rats (120 days old) were used: sedentary rats (S) and rats exercised by a single bout of swimming lasting 5 (E5) or 8 h (E8), respectively. The effect of exercise on the response to I/R was related to an index of oxidative damage such as lipid peroxidation, as well as to the tissue antioxidant capacity and the response of heart tissue to in vitro oxidative stress. The intrinsic performance of E5 Langendorff preparations paced at 220 beats x min(-1) was also determined. A group of sedentary animals was used for H2O2-treated preparations. The effect of antioxidant treatment on inotropic recovery during reperfusion was studied on preparations from 5 or 8 h swimming vitamin E-treated (EVT5 and EVT8 and 5 or 8 h swimming untreated (EVU5 and EVU8) rats. Hearts from exercised animals displayed a reduced preischaemic inotropism, which in E5 rats was accompanied by an increase in the intrinsic heart rate. The lower intrinsic cardiac inotropism of E5 animals was confirmed in the paced preparations. The reduced contractility found in control hearts after addition of H2O2 to perfusion medium suggested that the low inotropism of E5 and E8 hearts was due to an exercise-induced increase in reactive oxygen species. Inotropic recovery during reperfusion was low in the S hearts, was significantly increased in the E5 hearts, and was again reduced to the S level in the E8 hearts. In the E8 hearts the indexes of cellular damage (LDH release) and oxidative stress increased, and antioxidant capacity decreased, while in E5 hearts there was no evidence of significant changes in such parameters. Performance and reperfusion recovery of hearts from 5 h swimming rats was not affected by vitamin E treatment, while those of hearts from 8 h swimming rats was the highest observed. We suggest that the higher inotropic recovery during reperfusion in the hearts from the E5 rats is related to the negative inotropic effect of exercise. The fall in recovery following the 8 h exercise was instead related to the increased oxidative stress.     

Effect of repeated bouts of short-term exercise on plasma free and sulphoconjugated catecholamines in humans

We tested the hypothesis that measurement of plasma catecholamine sulphate concentration after exercise reflects the overall activation of the sympathoadrenergic system during the whole period of repeated bouts of short-term exercise. A group of 11 male athletes performed two exercise tests at similar average power outputs consisting of three sets each. The tests either started with one set of three very intense sprints (95% of maximal running speed) followed by two sets of three less intense sprints (85% of maximal running speed; HLX) or vice versa (LHX). Similar mean areas under the curve of free noradrenaline (NA) during HLX and LHX [622 (SEM 13) vs 611 (SEM 14) nmol?·?l^?1?·?min) as well as similar mean heart rates [143 (SEM 9) vs 143 (SEM 8) beats?·?min^?1] indicated comparable sympathetic activation during both exercise tests. Even so, plasma concentration of free NA was still significantly higher at the end of LHX than of HLX [35.7 (SEM 3.5) vs 22.5 (SEM 2.1) nmol?·?l^?1, respectively], i.e. when exercise ended with the more intense set of sprints. Plasma noradrenaline sulphate (NA-S) increased with exercise intensity showing higher mean increments after the first set of HLX compared to LHX [1.83 (SEM 0.42) vs 1.18 (SEM 0.29) nmol?·?l^?1; P?0.05]. However, after the end of HLX and LHX, increments in plasma NA-S were similar [4.52 (SEM 0.76) vs 4.06 (SEM 0.79) nmol?·?l^?1], suggesting that NA-S response changed in parallel with the overall activation of the sympathetic nervous system during repeated bouts of short-term exercise. The results supported the hypothesis that measurement of plasma NA-S immediately after repeated bouts of short-term exercise reflects overall activation of the sympathetic nervous system during prolonged periods of this type of exercise.     

Renal urea clearance in normal and adrenalectomized rats after exercise

In groups of male Wistar rats, blood level, urinary excretion of urea, and renal urea clearance were determined in resting conditions or during 48-60 h after swimming for 30 min with an additional load of 10% of body weight as well as after swimming for 3 or 10 h without additional load. Both types of swimming exercise caused a significant increase in the blood level, urinary excretion, and renal clearance of urea. After 10-h swimming, the increase of renal urea clearance was observed only from the second period (0-12 h) of urine collection. In this type of exercise, an elevation of blood level of corticosterone was obtained after 6-h restitution. The increased urinary excretion and renal urea clearance persisted for a longer time than was necessary for the normalization of the blood level. A significant rise in blood urea level and a drop in renal urea clearance occurred after adrenalectomy. In adrenalectomized rats, increased urea excretion and renal clearance were observed 12-24 h after 3-h swimming, but the level of renal clearance obtained in sedentary normal rats was not achieved. The blood level of urea did not increase. This suggested that the glucocorticoids play a role both in urea formation during exercise and in its elevated renal clearance after exercise.     

Effect of graded changes in extracellular muscle volume on cardiovascular drives during static exercise

Summary The effects of graded changes in peripheral extracellular volume on heart rate and blood pressure during isometric exercise were studied in 12 healthy male subjects. Each subject performed four calf ergometer tests with each calf. In all tests, static plantar flexion of one foot was performed in a supine body position with the knee joint flexed to 90°. After a pre-exercise period of 18 min, during which the calf volume was manipulated, the subjects had to counteract a spring force of 120 N for 8 min. In the pre-exercise period the peripheral extracellular volume of the calf muscle to be tested was manipulated in four ways. Test 1: 15 min of rest in the exercise position. During the last 3.5 min, the calf volume was increased by venous congestion [80 mmHg (10.67 kPa) applied to the distal part of the thigh by pneumatic cuff]. Test 2: the same protocol as in test 1 but with 7.5-min venous congestion. Test 3: 15 min of venous congestion. Test 4: the calf volume was decreased by a negative hydrostatic pressure for 15 min (calf raised about 40 cm above heart level). To clamp the changed calf volume, the thigh cuff was rapidely inflated to 300 mmHg (40.0 kPa) at the end of the volume manipulation and the subjects remained resting for a further 3 min. In test 4, the leg of the subject was passively brought into the exercise position. The occlusion was maintained until 2 min after exercise. The calf volume manipulation led to changes ranging from +105 ml (test 3) to –134 ml (test 4) as measured by water displacement plethysmography. The blood pressure response to exercise was inversely related to the calf volume changes while the heart rate response during exercise showed no clearcut relationship to the pretreatments.     

Regional capillary and myocyte distribution in normal and exercise trained male and female rat hearts

Adult Sprague-Dawley male and female rats were exercise trained for five months by either treadmill running or swimming. Significant differences in left ventricular regional capillary density and myocyte cross-sectional area were found. In control rats the epicardial regions had greater capillary density than endocardial regions. Endocardial myocyte cross-sectional areas were greater than those of epicardial myocytes in both sexes. Male rats had larger endocardial myocytes and larger hearts than females. After exercise training, myocyte size increased in the epicardial region but not in the endocardial region, while capillary density increased significantly only in the endocardial region. Similar changes were seen in both male and female rats with comparable degrees of exercise induced hypertrophy. These data suggest that exercise training "normalizes" the distribution of capillaries in the myocardium. Capillary density increased only in the regions where myocyte cross-sectional area did not increase. Further, the effects of exercise on male and female rat hearts is not different when the degree of exercise induced hypertrophy is similar.     

Phagocytic responses of peritoneal macrophages and neutrophils are different in rats following prolonged exercise

OBJECTIVE:

To analyze the effects of exhausting long‐duration physical exercise (swimming) sessions of different durations and intensities on the number and phagocytic capacity of macrophages and neutrophils in sedentary rats.

INTRODUCTION:

Exercise intensity, duration and frequency are important factors in determining immune response to physical effort. Thus, the effects of exhausting long‐duration exercise are unclear.

METHODS:

Wistar rats were divided into two groups: an untreated group (macrophage study) and oyster glycogen‐treated rats (neutrophil study). In each group, the animals were subdivided into five groups (10 rats per group): unexercised controls, an unadapted low‐intensity exercise group, an unadapted moderate‐intensity exercise group, a preadapted low‐intensity exercise group and a preadapted moderate‐intensity exercise group. All exercises were performed to exhaustion, and preadaptation consisted of 5, 15, 30 and 45 min sessions.

RESULTS:

Macrophage study: the number of peritoneal macrophages significantly decreased (9.22 ± 1.78 × 10⁶) after unadapted exercise but increased (21.50 ± 0.63 × 10⁶) after preadapted low‐intensity exercise, with no changes in the moderate‐intensity exercise group. Phagocytic capacity, however, increased by more than 80% in all exercise groups (low/moderate, unadapted/preadapted). Neutrophil study: the number of peritoneal neutrophils significantly decreased after unadapted (29.20 ± 3.34 × 10⁶) and preadapted (50.00 ± 3.53 × 10⁶) low‐intensity exercise but increased after unadapted (127.60 ± 5.14 × 10⁶) and preadapted (221.80 ± 14.85 × 10⁶) moderate exercise. Neutrophil phagocytic capacity decreased by 63% after unadapted moderate exercise but increased by 90% after corresponding preadapted sessions, with no changes in the low‐intensity exercise groups.

CONCLUSION:

Neutrophils and macrophages of sedentary rats respond differently to exercise‐induced stress. Adaptation sessions reduce exercise‐induced stress on the immune system.     

Ventilatory and circulatory responses at the onset of voluntary exercise and passive movement in sprinters

The purpose of this study was to clarify the characteristics of ventilatory and circulatory responses at the onset of voluntary exercise and passive movement in sprinters. Eleven male university sprinters and 11 male untrained subjects participated in the present study. Voluntary exercise consisted of leg extension–flexion movement for 20 s with weights corresponding to 5% of each subjects body mass attached to each ankle. Passive movement was achieved without weights by the experimenter alternately pulling ropes that were connected to the subjects ankles for the same period and frequency as during voluntary exercise. In the present study, the following results were found: (1) the magnitude of relative changes (gain) of minute ventilation at the onset of passive movement in the sprinters was significantly smaller than that in the untrained subjects [mean (SEM) 33.3 (2.9) vs 61.7 (6.4)%, P<0.05]; (2) the time for reaching one-half of the gain (response time) of heart rate at the onset of voluntary exercise and passive movement in the sprinters was significantly slower than that in the untrained subjects [2.5 (0.2) vs 1.7 (0.2) s in voluntary exercise and 3.4 (0.8) vs 1.5 (0.1) s in passive movement, P<0.05]; (3) the gain and response time of mean blood pressure at the onset of voluntary exercise and passive movement showed no significant differences between the two groups. It is concluded that sprinters show slowed heart rate response at the onset of voluntary exercise, and attenuated ventilatory and slowed heart rate responses at the onset of passive movement as compared with untrained subjects.     

Effects of running training on the blood glucose and lactate in rats during rest and swimming.

The purpose of this study was to examine the effect of physical training on the concentrations of glucose and lactate in the blood of rats during rest and after an acute bout of exercise. We used the following types and periods of training; (i) swimming for 4 weeks, (ii) running for 4 weeks, and (iii) running for 10 weeks. The results clearly show that the resting levels of blood glucose was significantly lower in groups trained by either swimming or running than untrained groups. In addition, after the acute exercise of swimming, animals trained by either running or swimming showed a lower increase in the blood lactate than untrained animals. Furthermore, the increases in the blood glucose after swimming were significantly lower in the group trained by swimming for 4 weeks and by running for 10 weeks than in untrained groups. These results suggest that after physical training by running, animals show an adaptation in the changes in the blood glucose and the blood lactate that are induced by a different type of physical stress, swimming.