Biochemical and hormonal changes in endurance trained volunteers during and after exposure to bed rest and chronic hyperhydration.

The objective of this investigation was to assess the effect of a daily intake of fluid and salt supplementation on biochemical and hormonal changes in endurance trained volunteers aged 19-24 yrs during 30-day bed rest and during 15 days of post bed rest period. The studies were performed on 30 long distance runners aged 19-24 yrs who had a peak oxygen uptake of 66 ml/kg/min and had taken 14.5 km/day on average prior to their participation in the study. The volunteers were divided into three groups: the volunteers in the first group were under normal ambulatory conditions (control subjects); the second group subjected to bed rest alone unsupplemented (bed rested volunteers); the third group was submitted to bed rest and consumed daily 30 ml water/kg bodyweight and 0.1 g of sodium chloride (NaCl)/kg body weight (supplemented bed rested volunteers). The second and third groups of volunteers were kept under a rigorous bed rest regime for 30 days. During the pre bed rest period of 15 days, during the bed rest period of 30 days and during the post bed rest period of 15 days cyclic adenosine monophosphate, cyclic guanosine monophosphate, prostaglandins of pressor, prostaglandins depressor groups, renin activity in plasma and aldosterone in plasma and in urine were determined. We found that in bed rested volunteers without fluid and salt supplementation intake plasma renin activity and aldosterone in plasma and urine continued to increase during the bed rest period as plasma volume decreased. Moreover, in this group, cyclic nucleotides measured as an indicator of adrenosympathetic system activity increased and prostaglandins as local vasoactive substances decreased during the bed rest period. These variables returned toward the baselines in the post bed rest period as plasma volume deficit was restituted. On the other hand, the hormonal levels in the other two groups remained rather constant during the experimental period. We concluded that daily intake of fluid and salt supplementation may minimize the biochemical and hormonal changes in endurance trained volunteers dorm their exposure to bed rest conditions.

Water and electrolyte excretion in rats during prolonged restriction of motor activity and chronic hyperhydration.

The objective of this investigation was to evaluate the effect of daily intakes of water and salt on water and electrolyte changes and body hydration status of rats during prolonged restriction of motor activity (hypokinesia). Ninety Wistar rats weighing 370 to 390 g were used to perform the studies: They were equally divided into three groups: 1. Unsupplemented vivarium control rats (UVCR); 2 Unsupplemented hypokinetic rats (UHKR) and 3. Supplemented hypokinetic rats (SHKR). For the simulation of the effect of hypokinesia (HK), the UHKR and SHKR groups were kept in small individual cages made of wood, which restricted their movements in all directions without hindering food and water intake. The SHKR received daily an additional amount of 5 ml water/100 g body weight and 3 g sodium chloride per 100 g body weights. During the prehypokinetic period of 15 days and during the hypokinetic period of 90 days plasma and urinary sodium and potassium, water intake and water loss, food intake, body weight, plasma osmolality, whole blood hemoglobin, hematocrit and plasma protein concentration were determined. In the UHKR group, plasma and urinary electrolytes, diuresis, plasma osmolality, whole blood hemoglobin, hematocrit and plasma protein concentration increased significantly while fluid and food intake and body weight decreased significantly when compared with the SHKR and UVCR groups. In the SHKR, plasma and urinary electrolytes, urine excretion, plasma osmolality, whole blood hemoglobin, hematocrit and plasma protein concentration decreased while food and water intake and body weight increased significantly when compared with the UHKR group. In the UVCR group, these same variables remained stable or changed very little when compared with the SHKR group throughout the experimental period. It was concluded that daily intakes of fluid and a salt supplement may be used to increase body hydration level and decrease fluid-electrolyte excretion and body weight losses during prolonged restriction of motor activity.

Morphometric examination of glomerulus and juxta glomerural system of rat kidney during prolonged restriction of motor activity.

The aim of this study was to examine the structural changes of glomerular and juxta glomerular system (JGS) of the kidney of rats during prolonged restriction of motor activity (hypokinesia). The studies were performed during 90 days of hypokinesia (HK) on 144 male Wistar rats divided into two groups: Group one placed under ordinary vivarium conditions and serving as vivarium control rats (VCR) and Group two subjected to HK and serving as hypokinetic rats (HKR). For the simulation of the hypokinetic effect the HKR group was kept in small individual cages made of wood that restricted the movements of rats in all directions without hindering food and water intake. During a prehypokinetic period of 15 days and the hypokinetic period of 90 days, body weight and food intake were measured and morphometric examinations were done to measure the cortical and juxta medullary glomerulus on kidney sections from the VCR and HKR groups (eight rats from each group). Body weight and food intake decreased significantly in the HKR groups when compared with the VCR group. Kidney weight of rats increased, the superficial volume decreased and that of the juxta medullary glomerules increased, whereas juxta glomerular granularity indexes decreased significantly in the HKR group when compared with the VCR group. The measured parameters did not change significantly in the VCR group when compared with the baseline control values. It was concluded that prolonged exposure to HK induces a significant increase in the kidney weight and a relationship appeared between variations of the volume of cortical and juxta medullary glomerulus and the function of the juxtaglomerular apparatus.

Fluid electrolyte changes in trained subjects after water loading and during restriction of muscular activity and chronic hyperhydration.

The objective of this investigation was to determine fluid electrolyte changes after water-loading tests and during hypokinesia (decreased number of km taken per day) and daily intake of fluid and salt supplementation (FSS). The studies during hypokinesia (HK) were performed for 364 d on 30 endurance-trained male volunteers in the age range of 23-26 yr, with an average peak oxygen uptake, POU, of 64 mL/kg/min. All volunteers were divided into three equal groups: 10 volunteers were placed on a continuous regime of exercise of 14.4 km/d and served as control subjects (CS); 10 volunteers were submitted to continuous HK without FSS and were considered as the unsupplemented hypokinetic subjects (UHS); and 10 volunteers were under continuous HK and FSS and were considered as the supplemented hypokinetic subjects (SHS). For the simulation of the hypokinetic effect, the UHS and SHS groups were kept continuously under an average of 2.7 km/d for the duration of the study. Prior to exposure to HK, the two groups of volunteers were on the same exercise regime as the control group. During a 60-d preexperimental period and during the remainder of the study, water-loading tests with a water load of 20 mL/kg body wt/min were performed, and urinary and plasma electrolytes (sodium, potassium, calcium, and magnesium) were measured. In the SHS group, urinary excretion of electrolytes and plasma electrolyte content decreased, while in the UHS these values increased after water loading tests and during HK. Based on the obtained data, it is concluded that chronic hyperhydration may be used to prevent or minimize urinary and plasma electrolyte changes in endurance-trained volunteers after water-loading tests and during prolonged restriction of muscular activity.

Potassium changes in trained subjects after potassium loading and during restriction of muscular activity and chronic hyperhydration.

The objective of this investigation was to determine whether urinary and plasma potassium changes developed during prolonged hypokinesia (HK) (decreased number of km/d) in endurance-trained subjects could be minimized or reversed with a daily intake of fluid and salt supplementation (FSS). The studies were performed on 30 endurance-trained male volunteers aged 23-26 yr with an average peak oxygen uptake of 65 mL/kg min during 364 d of HK. All volunteers were on an average of 13.8 km/d prior to their exposure to HK. All volunteers were randomly divided into three groups: 10 volunteers were placed continuously under an average of 14.0 km/d (control subjects), 10 volunteers were subjected continuously to an average of 2.7 km/d (unsupplemented hypokinetic subjects), and 10 volunteers were submitted continuously to an average of 2.7 km/d, and consumed daily an additional amount of 0.1 g sodium chloride (NaCl)/kg body wt and 30 mL water/kg body wt (supplemented hypokinetic subjects). During the prehypokinetic period of 60 d and during the hypokinetic period of 364 d, potassium loading tests were performed with 1.5-1.7 mEq potassium chloride/kg body wt, and potassium, sodium, and chloride excretion in urine and potassium, sodium, and chloride in plasma were determined. In the unsupplemented hypokinetic volunteers, urinary excretion of electrolytes and concentrations of electrolytes in plasma increased significantly as compared to the control and supplemented hypokinetic groups of volunteers. It was concluded that daily intake of fluid and salt supplementation had a favorable effect on regulation of urinary and plasma potassium changes in trained subjects during prolonged HK.

Effect of daily hyperhydration on fluid-electrolyte changes in endurance-trained volunteers during prolonged restriction of muscular activity.

The aim of this investigation was to evaluate the effect of a daily intake of fluid and salt supplementation on fluid and electrolyte losses in endurance-trained volunteers during prolonged restriction of muscular activity (hypokinesia). The studies were performed on 30 long-distance runners aged 23-26 who had a peak oxygen uptake of 65.5 mL/kg/min and had taken 13.8 km/d on average prior to their participation in the study. The volunteers were divided into three groups: The volunteers in the first group were placed under normal ambulatory conditions (control subjects), the second group of volunteers subjected to hypokinesia alone (hypokinetic subjects), and the third group of volunteers was submitted to HK and consumed daily 0.1 g sodium chloride (NaCl)/kg body wt and 26 mL water/kg body wt (hyperhydrated subjects). The second and third group of volunteers were kept under an average of 2.7 km/d for 364 d. During the pre-experimental period of 60 d and during the experimental period of 364 d sodium, potassium, calcium, and magnesium in urine and plasma were determined. Blood was also assayed for osmolality, hemoglobin, hematocrit, plasma volume, plasma renin activity and plasma aldosterone. Mean arterial blood pressure was also determined. In the hyperhydrated volunteers plasma volume and arterial blood pressure increased, whereas plasma osmolality, plasma renin activity, plasma aldosterone, hematocrit, hemoglobin concentration, and urinary excretion and concentrations of electrolytes in plasma decreased. In the hypokinetic volunteers, plasma volume and arterial blood pressure decreased significantly, whereas hematocrit values, hemoglobin concentration, plasma osmolality, plasma renin activity, plasma aldosterone, and electrolytes in urine and plasma increased significantly during the experimental period. It was concluded that chronic hyperhydration may be used in minimizing fluid and electrolyte losses in endurance-trained volunteers during prolonged restriction of muscular activity.

Effect of potassium and calcium loading on healthy subjects under hypokinesia and physical exercise with fluid and salt supplements.

The objective of this investigation was to determine the acute responses to the electrolyte challenges under hypokinesia and physical exercise (PE) of different intensities with fluid and salt supplementation (FSS). The studies were performed on 12 physically healthy male volunteers aged 19-24 years under 364 days of hypokinesia (decreased number of steps per day) with a set of PE with FSS. The volunteers were divided into two equal groups. The first group was subjected to a set of intensive PE and the second group was submitted to a set of moderate PE. Both groups of subjects consumed daily water and salt supplements that aimed to increase the body hydration level. For simulation of the hypokinetic effect all subjects were kept under an average of 3000 steps per day. Functional tests with a potassium chloride (KCl) and calcium lactate (Cal) load were performed during the hypokinetic period of 364 days and the 60-day, prehypokinetic period that served as control, while both groups of subjects consumed daily calcium and potassium supplements. The concentration of electrolyte and hormone levels in the blood and their excretion rate in urine were determined. Renal excretion of calcium and potassium and the blood concentration thereof increased markedly in both groups of subjects. With the potassium chloride load tests the increased potassium excretion was accompanied by higher aldosterone and insulin blood levels, and with the calcium lactate load tests the increased calcium excretion was accompanied by a decreased parathyroid content in the blood. FSS and PE, regardless of intensity, failed to attenuate calcium and potassium losses. Additional intake of KCl and Cal also failed to normalize potassium and calcium abnormalities. It was concluded that during the KCl and Cal loading tests, the increased losses of potassium and calcium in the hypokinetic subjects were due to the inability of their bodies to retain these electrolytes, and that electrolyte abnormalities could not be reversed by PE or rehydration in individuals subjected to prolonged restriction of motor activity.

Phosphate-loading test influences on endurance-trained volunteers during restriction of muscular activity and chronic hyperhydration.

The purpose of this investigation was to determine whether negative phosphate balance, which is developed during hypokinesia (a decreased number of walking steps/d) could be reversed with daily supplementation with phosphate, fluid, and salt (FSS). The studies on hypokinesia (HK) were performed for 364 d on 30 endurance-trained male volunteers in the age range of 23-26 yr, with an average maximum oxygen uptake, MOU, of 65 mL/kg min. All subjects were divided into three equal groups: Ten volunteers were placed on a continuous regime of exercise of 14.4 km/d at 10,000 steps/d and served as controls. Ten volunteers were subject to continuous HK without FSS and were considered as the hypokinetic subjects (HS). The remaining subjects were under continuous HK and FSS and were considered as the hypokinetic, hyperhydrated subjects (HHS). The three groups were on a diet that averaged 2620 cal/d and contained 1.7 g calcium, 1.6 g phosphate, and 5.6 g sodium chloride. For simulation of the hypokinetic effect, the HS and HHS groups were kept continuously under 2.9 km/d (3000 walking steps/d) for the duration of the study. Prior to exposure to HK, all volunteers were on the same exercise regime as the controls. During a 60-d pre-HK period and during the remainder of the study, phosphate-loading tests, urinary and plasma phosphate concentrations were performed in all subjects. In the HHS group, plasma phosphate concentration and urinary excretion of phosphate were decreased, while in the HS group these values increased after phosphate loading. Based on our results, we concluded that chronic hyperhydration and phosphate supplementation may be used to minimize phosphate losses in endurance-trained volunteers during prolonged restriction of muscular activity.

Blood plasma concentrations of microelements in endurance trained volunteers during hypokinesia and chronic hyperhydration.

The objective of this investigation was to determine the effect of a daily intake of fluid and salt supplementation (FSS) in preventing the development of changes in blood plasma concentrations of microelements that occur during prolonged restriction of muscular activity (hypokinesia). The studies were performed on 30 endurance trained male volunteers aged 23-26 yr with an average maximum oxygen uptake 64 mL/kg/min during 364 d of hypokinesia (HK). They were divided into three equal groups: Ten volunteers were placed continuously under an average of 10,000 running steps/d (control subjects), ten volunteers were subjected continuously to HK without the use of FSS (hypokinetic subjects), and ten volunteers were submitted continuously to HK and consumed daily FSS in very small divided doses (hyperhydrated subjects). For the simulation of the hypokinetic effect, the hypokinetic and hyperhydrated endurance trained male volunteers were kept continuously under an average of 3000 walking steps/d for 364 d. Prior to their exposure to HK, all volunteers were on an average of 10,000 running steps/p d. During the prehypokinetic period of 60 d and during the hypokinetic period of 364 d were determined the concentrations of calcium, magnesium, manganese, lead, iron, copper, tin, nickel, zinc, and cobalamine in blood plasma of endurance trained volunteers. During the hypokinetic period blood plasma concentrations of microelements decreased in hyperhydrated volunteers, whereas in hypokinetic volunteers increased significantly. The differences between the hyperhydrated and hypokinetic volunteers were significant with respect to their concentrations of microelements in blood plasma. It was concluded that chronic hyperhydration may be used to normalized blood plasma concentrations of microelements in endurance trained volunteers during prolonged restriction of muscular activity.

Fluid electrolyte excretion during different hypokinetic body positions of trained subjects.

The aim of this study was to evaluate the effect of different body positions on renal excretion of fluid and electrolytes after exposure to 364 days of decreased number of steps per day (hypokinesia, HK). The studies were performed on 18 endurance trained male volunteers aged 19-24 years who had an average of VO2max 67 ml/kg body/min. All volunteers were divided into three equal groups: the 1st group subjected to 12 h orthostatic position (OP) and 12 h clinostatic position (CP)/day, the 2nd group exposed to 8 h orthostatic position and 14 h clinostatic position/day, and the 3rd group submitted to 10 h orthostatic position and 16 h clinostatic position/day for 364 days. For the simulation of the hypokinetic effect all volunteers were kept under an average of 3000 steps/day for 364 days. Diuresis and the concentrations of sodium, potassium, chloride, calcium and magnesium as well as excretion of creatine were determined in 24-h urine samples. By the end of the hypokinetic period all volunteers, regardless of their body position during HK, manifested a significant increase in renal excretion of fluid and electrolytes as compared to prehypokinetic period values. It was concluded that prolonged restriction of motor activity induced a significant increase in renal excretion of fluid and electrolytes in endurance trained subjects regardless to their body position and duration thereof per day.

Calcium loading and renal function in trained subjects during restriction of muscular activity and chronic hyperhydration.

It was suggested that negative calcium balance is not based on the shortage of calcium in the diet, but on the decreased tissular capacity of the body to retain calcium during hypokinesia (decreased muscular activity), and that chronic hyperhydration may be used to normalize calcium balance. To evaluate this hypothesis studies were performed on 30 long distance runners aged 23-26 yr, with an average maximum oxygen uptake 65 mL/kg/min during 364 d of hypokinesia (HK). All volunteers were divided into three equal groups: Ten volunteers were placed continuously under an average of 14.9 km/d (control subjects), ten volunteers were subjected continuously to HK (hypokinetic subjects), and ten volunteers were submitted continuously to HK with daily consumption of an additional amount of 26 mL water/kg body wt and 0.16 g sodium chloride (NaCl)/kg body wt (hyperhydrated subjects). For the simulation of the hypokinetic effect, the hypokinetic and hyperhydrated volunteers were kept under an average of 2.7 km/day for 364 d. During the prehypokinetic period and hypokinetic period calcium lactate loading tests (0.55 mEq/kg body wt) were performed. Urinary and blood electrolytes (sodium, ionized calcium, total calcium, magnesium, and phosphate) and blood parathyroid hormone (PTH) were determined. Urinary electrolytes and concentrations in blood thereof decreased in the hyperhydrated and increased significantly in the hypokinetic volunteers. Blood parathyroid hormone content increased in the hyperhydrated and decreased in the hypokinetic volunteers. After calcium lactate loading tests, the hypokinetic volunteers displayed a faster excretion of calcium and a decreased blood PTH content as compared to the control and hyperhydrated groups of volunteers. It was concluded that calcium deficiency during HK is associated with decreased tissular capacity of the body to retain calcium, whereas chronic hyperhydration may be used to prevent calcium deficiency in endurance trained volunteers during prolonged restriction of muscular activity.

Mechanisms of osteoporosis development during prolonged restriction of motor activity in dog.

The pattern in the mechanisms of osteoporosis development during prolonged motor activity restriction (hypokinesia) in animals has been studied. Twenty-four male dogs with initial body weights of 6.8 to 8.9 kg were divided into two equal groups: the 1st group were placed under ordinary vivarium conditions and served as control and the 2nd group were subjected to pure hypokinesia (HK) without any form of physical exercise and served as experimental animals. They were kept for 364 days in small individual wooden cages which restricted their movements without hindering food and water intake. Animals of each group were decapitated on the 120th, 240th and 360th day of the hypokinetic period and bones were x-rayed, histological specimens were examined, mineralization or organic bone was measured, microroentgenographic analysis was performed and calculation was made of calcium, phosphorus, potassium and sodium. By the 120th and 240th day of the hypokinetic period bone resorption increased significantly, while by the 360th day it decreased significantly. The mature bone microstructures manifested a higher degree of mineralization, whereas the young bone microstructures exhibited a lower degree of mineralization. In bone, calcium content decreased, that of potassium increased, while sodium and phosphorus content remained unchanged. It was concluded that the development of osteoporosis in osseous tissues during prolonged restriction of motor activity of animals is associated not only to quantitative changes, which consist of a reduction of bone mass, but qualitative changes as well.

Urinary excretion of microelements in endurance-trained volunteers during restriction of muscular activity and chronic rehydration.

The objective of this investigation was to determine the effect of daily intake of fluid and salt supplementation (FSS) on increased urinary losses of microelements that developed during hypokinesia (decreased number of walking steps/d). The studies were performed on 30 endurance-trained male volunteers aged 23-26 yr, with an averaged maximum oxygen uptake of 65 mL/kg/min during 364 d of hypokinesia (HK). All volunteers were divided into three equal groups: Ten volunteers were placed continuously under an average of 10,000 running steps/d (14.2 km/d) (control subjects), ten volunteers subjected continuously to HK without the use of FSS (hypokinetic subjects), and ten volunteers were continuously submitted to HK and consumed daily FSS (hyperhydrated subjects). For the simulation of the hypokinetic effect the hypokinetic and hyperhydrated volunteers were kept under an average of 3,000 walking steps/d (2.7 km/d) for 364 d. Prior to their exposure to HK the volunteers were on an average of 10,000 running steps/d (14.2 km/d). During the prehypokinetic period of 60 d and during the hypokinetic period of 364 d were determined renal excretion of microelements responses of endurance-trained volunteers. In the hyperhydrated volunteers urinary excretion of iron, zinc, copper, manganese, cobalt, nickel, lead, tin, chromium, aluminum, molybdenum, and vanadium decreased, whereas in the hypokinetic volunteers it increased significantly. It was concluded that chronic hyperhydration may be used to attenuate urinary excretion of microelements in endurance-trained volunteers during prolonged restriction of muscular activity.

Plasma trace elements concentrations in trained subjects after exposure to hypokinesia and daily hyperhydration.

The objective of this investigation was to evaluate the effect of a daily intake of fluid and salt supplementation (FSS) on blood plasma trace elements concentrations in physically healthy volunteers after exposure to 364 d of hypokinesia (decreased number of steps per day). The studies were performed after exposure to 364 d of Hypokinesia (HK) on 30 long-distance runners of volunteers who had a VO2 max 67 mL/kg/min and were ranging in the age of 19-24 yrs. Prior to their exposure to HK all volunteers were on an average of 10,000 steps/d. For the simulation of the hypokinetic effect the volunteers were kept under an average of 3000 steps/d. All volunteers were divided into three equal groups. The first group of volunteers subjected to HK and received daily FSS (water 26 mL/kg body wt and sodium chloride 0.16 g/kg body wt.), the second groups of volunteers submitted only to HK, and the third group of volunteers underwent a normal ambulatory life and served as control. The content of manganese, calcium, magnesium, iron, lead, copper, tin, nickel, zinc and cobalamine were determined in blood plasma of volunteers. By the end of the hypokinetic period the blood plasma concentration of microelements increased significantly in the hypokinetic subjects (second group), whereas in the hyperhydrated subjects (first group) decreased. It was concluded that prolonged restriction of motor activity induced significant increases in blood trace elements concentrations whereas daily hyperhydration had a normalizing effect on their concentration in blood plasma. This indicates that daily hyperhydration may be used to normalize blood plasma concentrations of micro-elements in physically healthy volunteers subjected to prolonged restriction of motor activity.

Bone mineralization and plasma concentrations of electrolytes in healthy subjects after exposure to hypokinesia and hyperhydration.

The objective of this investigation was to determine bone mineralization and concentrations of electrolytes in blood plasma of physically conditioned volunteers after exposure to hypokinesia (decreased number of steps/day) and daily hyperhydration. The studies were performed on 30 physically conditioned volunteers (mean VO2 max 67 ml/kg-1 x min-1 age range 19-24 years) after exposure to 364 days of hypokinesia (HK). Prior to their exposure to HK all volunteers were long-distance runners who covered on average 10,000 steps per day. All subjects were divided into three equal groups: the 1st group was subjected to HK and consumed daily fluid and salt supplements (water 26 ml/kg body weight and sodium chloride 0.16 g/kg body weight), the 2nd group submitted to pure HK, and the 3rd group continued to engage in long-distance running and served as control. For the hypokinetic effect the 1st and 2nd group of volunteers were restricted to an average of 1000 steps/day. After exposure to HK the changes in bone mineralization and blood plasma concentrations of magnesium and calcium were determined. In hyperhydrated volunteers bone mineralization increased and content of electrolytes in blood plasma decreased, while in hypokinetic volunteers the electrolyte levels increased significantly and bone mineralization decreased significantly. It was concluded that daily fluid an salt supplementation may be used to attenuate changes in bone mineralization and blood plasma concentrations of electrolytes induced by prolonged restriction of motor activity of highly trained athletes.

Blood biochemical changes in trained subjects during prolonged restriction of physical activity and chronic hyperhydration.

The objective of this investigation was to determine the effect of daily fluid and salt supplementation on biochemical changes in the serum of endurance trained athletes after exposure to hypokinesia (decreased number of steps from 15,000 to 1000 steps/day). The studies were performed after exposure to 364 days of hypokinesia on 18 long-distance runners aged 19-24 years who had a V02 max of 67.5 ml/kg/min. The volunteers were divided into three equal groups: The 1st group underwent a normal ambulatory life (control subjects), the 2nd group was placed under continuous restriction of motor activity, and the 3rd group was kept under continuous restriction of motor activity whilst consuming daily supplements of 26 ml water/kg body weight and 0.16 g sodium chloride/kg body weight. For hypokinesia the number of steps taken per day by the volunteers in groups 2 and 3 were restricted to an average of 1000. During the hypokinetic period of 364 days and posthypokinetic period of 30 days urea, glucose, acid-soluble phosphorus, inorganic phosphorus, cholesterol (low-density and high-density lipoprotein) and phospholipids were measured at predetermined intervals. During the hypokinetic period in hyperhydrated volunteers urea, cholesterol, phospholipids, inorganic phosphorus and acid soluble phosphorus decreased, while glucose increased. In hypokinetic volunteers a significant increase in urea, cholesterol, phospholipids, inorganic phosphorus and acid soluble phosphorus, and a significant decrease in glucose was demonstrated. During the posthypokinetic period these biochemical changes normalized in both hypokinetic and hyperhydrated volunteers. It is concluded that daily fluid and salt supplementation may effectively counteract changes in blood biochemistry in endurance trained subjects during prolonged restriction of physical activity.

Blood serum biochemical changes in physically conditioned and unconditioned subjects during bed rest and chronic hyperhydration.

1. It has been suggested that prolonged exposure to a rigorous bed rest regimen (hypokinesia) may induce greater serum carbohydrate and electrolyte changes in physically conditioned than unconditional subjects and that chronic hyperhydration may normalize or attenuate the development of these biochemical alterations in physically conditioned subjects. 2. Serum carbohydrate and electrolyte changes were determined in 18 physically healthy male volunteers aged 19-24 years during 30 days of a rigorous bed rest regimen. The subjects were divided into three equal groups. The first group consisted of six unconditioned subjects with VO2 max of 44 mL/kg bodyweight/min, the second group consisted of six conditioned subjects with VO2 max of 69 mL/kg bodyweight/min and the third group consisted of six conditioned subjects with VO2 max of 69 mL/kg bodyweight/min who consumed daily an additional amount of 26 mL water/kg bodyweight and 0.10 mg sodium chloride/kg bodyweight. 3. For the simulation of the hypokinetic effect all volunteers were kept under a rigorous bed rest regimen for 30 days. During the prehypokinetic period of 15 days and during the bed rest period of 30 days the concentrations of cortisol, aldosterone, testosterone, triiodothyronine (T3), thyroxine (total; T4), glucose, potassium, sodium and chloride were determined in blood serum of volunteers. 4. During the bed rest period of 30 days serum carbohydrate and electrolyte changes were more pronounced in physically conditioned than unconditioned hypokinetic subjects. In physically conditioned hyperhydrated subjects serum carbohydrate and electrolyte changes were less pronounced than in physically conditioned and unconditioned hypokinetic subjects.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of hyperhydration on bone mineralization in physically healthy subjects after prolonged restriction of motor activity.

The objective of this investigation was to evaluate the effect of a daily intake of fluid and salt supplementation (FSS) on bone mineralization in physically healthy male volunteers after exposure to hypokinesia (decreased number of steps taken/day) over a period of 364 days. The studies were performed after exposure to 364 days of hypokinesia (HK) on 18 physically healthy male volunteers who had an average VO2max of 65 ml/kg/min and were aged between 19 and 24 years. For the simulation of the hypokinetic effect the volunteers were kept under an average of 1000 steps/day. The subjects were divided into three equal groups of 6: 6 underwent a normal ambulatory life (control group), 6 were placed under HK (hypokinetic group) and the remaining 6 were subjected to HK and consumed a daily FSS (water 26 ml/kg body wt and NaCl 0.10 mg/kg body wt) (hyperhydrated group). The density of the ulnar, radius, tibia, fibular, lumbar vertebrae and calcenous was measured. Calcium and phosphorus changes, plasma volume, blood pressure and body weight were determined. Calcium content in the examined skeletal bones decreased more in the hypokinetic subjects than in the hyperhydrated subjects. Urinary calcium and phosphorus losses were more pronounced in hypokinetic than hyperhydrated subjects. Plasma volume and body weight increased in hyperhydrated subjects, while it decreased in hypokinetic subjects. It was concluded that a daily intake of FSS may be used to neutralize bone demineralization in physically healthy subjects during prolonged restriction of motor activity.

Fluid electrolyte and hormonal changes in conditioned and unconditioned men under hypokinesia.

It has been suggested that hypokinesia (diminished muscular activity) may induce more changes in fluid electrolyte metabolism and hormonal concentration of blood plasma in conditioned than unconditioned men. Thus, the objective of this investigation was to determine the effect of 7 days of hypokinesis (HK) on fluid-electrolyte excretion and hormonal content of blood in 12 physically healthy men aged 19-23 years. They were divided into two equal groups according to their physical conditioning. For the simulation of the hypokinetic effect the men were kept under a rigorous bed rest regime. During the background period (BGP), that is prior to the exposure to HK, and under HK, the rate of elimination of fluid, sodium and potassium, and the content of blood plasma aldosterone and cortisol was measured. The amount of excretion of fluid and electrolytes increased while blood plasma aldosterone content decreased. In the conditioned men, a greater excretion of fluid and electrolytes and a greater reduction of plasma aldosterone concentration was observed. It was concluded that hypokinesia induced substantial changes in fluid-electrolyte excretion and hormonal content of blood plasma in both conditioned and unconditioned men.