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ABSTRACT: Studies have shown that chronic periodic fluid shifting upwards is not sensed as excessive fluid volume and excretion mechanisms are not activated. To determine if chronic periodic fluid and volume shifting upwards can affect muscle calcium (Ca(2+)) during hypokinesia (HK) we measured muscle Ca(2+) content, plasma Ca(2+) concentration, and Ca(2+) losses in urine and feces. Studies were conducted on 40 healthy male volunteers. They were divided into four equal groups: active control subjects (ACS), hypokinetic subjects (HKS), periodic fluid redistribution control subjects (PFRCS), and periodic fluid redistribution hypokinetic subjects (PFRHS). Plasma Ca(2+) level decreased (p < 0.05) in Ca(2+) repleted muscle, muscle Ca(2+) level increased (p < 0.05), and Ca(2+) losses in urine and feces decreased (p < 0.05) in the PFRHS group compared with the HKS group. Plasma Ca(2+) level increased (p < 0.05) in Ca(2+) deficient muscle, muscle Ca(2+) level decreased (p < 0.05), and Ca(2+) losses in urine and feces increased (p < 0.05) in the HKS group compared with their pre-experimental levels and the values in their respective control groups (ACS and PFRCS). This study shows that the muscle Ca(2+) content increases and Ca(2+) excretion decreases, suggesting the clinical potential of chronic periodic fluid and volume redistribution in treatment of muscle Ca(2+) deficiency.
The Journal of Physiological Sciences 03/2012; 62(3):233-9. · 1.61 Impact Factor
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ABSTRACT: The incompleteness of electrolyte utilization during hypokinesia and electrolyte supplementation is the defining factor of electrolyte metabolic changes, yet the effect of electrolyte supplementation and HK upon electrolyte utilization is poorly understood. To determine the influence of magnesium (Mg(2+)) supplementation and hypokinesia (diminished movement) on magnesium utilization, we investigated the use of Mg(2+) supplementation to establish its effect upon muscle Mg(2+) content and Mg2(2+) losses.
This study was conducted in 40 physically healthy male volunteers during a pre-experimental period of 30 d and an experimental period of 364 d. Subjects were equally divided into four groups: unsupplemented control subjects (UCSs), unsupplemented experimental subjects (UESs), supplemented control subjects (SCSs), and supplemented experimental subjects (SESs). A daily supplementation of 3.0 mmol of magnesium-chloride per kilogram of body weight was given to subjects in the SCS and SES groups.
Muscle Mg(2+) content decreased (P < 0.05) and plasma Mg(2+) concentration and Mg(2+) loss in urine and feces increased (P < 0.05) in the SES and UES groups compared with their pre-experimental levels and values in their respective control groups (SCS and UCS). Muscle Mg(2+) content decreased more (P < 0.05) and plasma Mg(2+) concentration and Mg(2+) loss in urine and feces increased more (P < 0.05) in the SES group than in the UES group.The muscle Mg(2+) content and plasma Mg(2+) level and Mg(2+) losses did not change in the control groups.
Daily Mg(2+) supplementation during prolonged hypokinesia decreases more muscle Mg(2+) content and Mg(2+)-deficient muscle increases more Mg(2+) loss in healthy subjects indicating lower Mg(2+) utilization with than without Mg(2+) supplementation.
Nutrition 04/2010; 26(11-12):1134-8. · 3.03 Impact Factor
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ABSTRACT: Microelement supplementation during Hypokinesia (HK; diminished movement) affects differently microelement metabolism from that of normal muscular activity. In view of the effect of trace element supplementation and HK upon microelement metabolism we investigated the effect of vanadium (V) supplements on tissue V content and V loss during HK.
Studies were performed on 240 male Wistar rats during a pre-experimental period of 9 days and an experimental period of 98 days. Rats were equally divided into four groups: unsupplemented control rats (UCR), unsupplemented experimental rats (UER), supplemented control rats (SCR) and supplemented experimental rats (SER). A daily supplementation of 0.8 μmol vanadium sulfate was given to the rats in the SCR and SER groups. Muscle V content, plasma V level and V loss was measured in the experimental and control groups of rats.
The gastrocnemius muscle and right femur bone V content decreased (p < 0.05), and plasma V level and urinary and fecal V loss increased (p < 0.05) in the SER and UER groups compared to their pre-experimental values and their respective control groups (SCR) and UCR). However, the tissue V content decreased more (p < 0.05) and plasma V level and V loss increased more (p < 0.05) in the SER group than in the UER group. The tissue V content and plasma V level and V loss did not change in the control groups of rats compared to the pre-experimental values.
It is concluded that during HK V supplementation decreases more tissue V content and increases more V loss and plasma V level in V deficient tissue indicating lower V utilization.
The Tokai journal of experimental and clinical medicine 01/2010; 35(1):40-5.
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ABSTRACT: To determine whether during hypokinesia (diminished movement) periodic physical exercise affects calcium (Ca(2+)) balance and Ca(2+) loss.
Studies were conducted on 30 physically healthy male volunteers during the preexperimental period of 30 days and the experimental period of 364 days. They were equally divided into three groups: active control subjects (ACS), hypokinetic subjects (HKS), and periodic training subjects (PTS). The ACS group ran an average distance of 9.3+/-1.2 km/d; the HKS group walked an average distance of 1.3+/-0.2 km/d; and PTS group walked and ran average distances of 1.3+/-0.2 km/d and 9.2+/-1.2 km/d for 5 and 2 days per week, respectively.
Serum Ca(2+) level, fecal and urine Ca(2+) loss, and Ca(2+) imbalance increased (P<0.05) in the PTS and HKS groups compared with their preexperimental levels and the values in their respective ACS group. The serum Ca(2+) concentration, urine and fecal Ca(2+) loss, and Ca(2+) imbalance increased more (P<0.05) in the PTS group than in the HKS group.
During hypokinesia, Ca(2+) imbalance is more evident with than without physical exercise and Ca(2+) loss is exacerbated more with higher than lower Ca(2+) imbalance.
Nutrition 10/2009; 25(10):1029-34. · 3.03 Impact Factor
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ABSTRACT: To determine the effect of potassium (K+) supplementation and hypokinesia (HK; diminished movement) on muscle K+ content and K+ loss.
Studies were conducted on 40 healthy male volunteers during a pre-experimental period of 30 days and an experimental-period of 364 days. Volunteers were equally divided into four groups: unsupplemented control subjects (UCS), unsupplemented experimental subjects (UES), supplemented control subjects (SCS), and supplemented experimental subjects (SES). A daily supplement of 1.17 mmol potassium-chloride (KCl) per kg body weight was given to the subjects in the SCS and SES groups.
Muscle K+ content decreased (P < 0.05), and plasma K+ concentration, and K+ loss in urine and feces increased (P < 0.05) in the SES and UES groups compared with their pre-experimental levels and the values in their respective control groups (SCS and UCS). Muscle K+ content decreased more (P < 0.05), and plasma K+ concentration and K+ loss in urine and feces increased more (P < 0.05) in the SES group than in the UES group.
Muscle K+ content is not decreased by the K+ deficient diet and K+ loss is not increased by the higher muscle K+ content in the body. Rather it is caused by the inability of the body to use K+ during HK and K+ supplementation.
Clinical and investigative medicine. Medecine clinique et experimentale 01/2009; 32(1):E34-42. · 1.15 Impact Factor
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ABSTRACT: We undertook this study to determine total calcium (Ca(2+)) loss in Ca(2+)-deficient tissue and tissue Ca(2+) loss with and without Ca(2+) supplementation during hypokinesia (HK; diminished movement).
Studies were conducted on 240 male Wistar rats during a pre-experimental period of 9 days and an experimental period of 98 days. Rats were equally divided into four groups: unsupplemented vivarium control rats (UVCR), unsupplemented hypokinetic rats (UHKR), supplemented vivarium control rats (SVCR), and supplemented hypokinetic rats (SHKR). Calcium supplementation of 2.6 mmol was given to animals in the SVCR and SHKR groups.
Gastrocnemius muscle and right femur bone Ca(2+) level reduced (p <0.05) and plasma Ca(2+) level, and urine and fecal Ca(2+) loss increased (p <0.05) in the SHKR and UHKR groups compared to their pre-experimental values and the values in their respective vivarium control groups (SVCR and UVCR). Muscle and bone Ca(2+) content decreased more (p <0.05), while plasma Ca(2+) level, and urine and fecal Ca(2+) loss increased more (p <0.05) in the SHKR group than in the UHKR group.
Tissue Ca(2+) deficiency during HK is more evident with than without Ca(2+) supplementation and Ca(2+) loss was exacerbated with higher than lower tissue Ca(2+) deficiency. This shows that tissue Ca(2+) deficiency does not result from the lower Ca(2+) content in the food consumed and the total bodily Ca(2+) loss is not caused by the higher tissue Ca(2+) content but due to the impossibility of the body to use Ca(2+) during prolonged HK.
Archives of Medical Research 08/2008; 39(5):496-502. · 1.88 Impact Factor
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ABSTRACT: We investigated the effect of hypokinesia (diminished movement) on muscle calcium (Ca(2+)) content with and without Ca(2+) supplementation and Ca(2+) loss with different muscle Ca(2+) deficiency; muscle Ca(2+) content, plasma Ca(2+) level, and Ca(2+) loss were measured.
Studies were performed in 40 physically healthy male volunteers during a pre-experimental period of 30 d and an experimental period of 364 d. Subjects in equal numbers were assigned to one of four groups: unsupplemented active control subjects (UACSs), unsupplemented hypokinetic subjects (UHKSs), supplemented active control subjects (SACSs), and supplemented hypokinetic subjects (SHKSs). A daily supplementation of 0.7 mmol of calcium lactate per kilogram of body weight was given to SACSs and SHKSs.
Muscle Ca(2+) content decreased, and plasma Ca(2+) concentration and Ca(2+) loss in urine and feces increased (P < 0.05) in the SHKS and UHKS groups compared with their pre-experimental values and the values in their respective active control groups (SACS and UACS). However, muscle Ca(2+) content decreased more, and plasma Ca(2+) concentration and Ca(2+) loss increased more (P < 0.05) in the SHKS group than in the UHKS group.
Muscle Ca(2+) deficiency is more evident when Ca(2+) intake is higher and Ca(2+) loss is more exacerbated with higher than with lower muscle Ca(2+) deficiency, indicating that muscle Ca(2+) deficiency during prolonged hypokinesia is due to an inability of the body to use Ca(2+) but not to a Ca(2+) shortage in the diet.
Nutrition 03/2008; 24(3):217-23. · 3.03 Impact Factor
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ABSTRACT: This study aimed to show that during hypokinesia (HK), phosphate (P(i)) imbalance increases more with higher than lower physical activity and that P(i) absorption reduces more with higher than lower P(i) imbalance in subjects with higher than lower muscular activity.
Studies were conducted on 30 healthy male subjects during 364 days of HK. They were equally divided in three groups: unrestricted active control subjects (UACS), continuously hypokinetic subjects (CHKS) and periodically hypokinetic subjects (PHKS). CHKS were kept under average walking distances of 0.5+/-0.2 km day(-1) PHKS were kept under average walking distances of 0.5+/-0.1 and running average distances of 8.7+/-1.2 km day(-l) for 5 days and 2 days per week, respectively. UACS were placed under average running distances of 8.7+/-1.2 km day(-l).
P(i) imbalance, serum, urine and fecal P(i) levels, and urine and serum calcium (Ca(2+)) levels increased significantly (p<0.05) and P(i) absorption, and serum intact parathyroid hormone (iPTH) and 1,25-dehydroxyvitamin D (1,25 (OH)(2) D(3)) levels decreased significantly (p<0.05) in CHKS and PHKS compared with their pre-HK values and their respective active control (UACS). However, the P(i) imbalance, serum, urine and fecal P(i) levels, and serum and urine Ca(2+) levels increased more significantly (p<0.05), and P(i) absorption and serum iPTH and 1,25 (OH)(2) D(3) levels decreased more significantly in PHKS than in CHKS.
Higher P(i) imbalance with higher than lower physical activity shows that the risk of higher P(i) imbalance is inversely related to the intensity of physical activity. Lower P(i) absorption with higher than lower P(i) imbalance shows that the risk of lower P(i) absorption is inversely related to magnitude of P(i) imbalance. In conclusion P(i) imbalance increases more with higher than lower physical activity and that P(i) absorption decreases more with higher than lower P(i) imbalance indicating that during HK the use of P(i) decreases more with higher than lower physical activity.
Clinical Biochemistry 04/2007; 40(7):460-6. · 2.08 Impact Factor
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ABSTRACT: To demonstrate the effect of sodium supplementation and hypokinesia (HK; diminished movement) on the total bodily sodium (Na+) loss and tissue Na+ deficiency, tissue Na+ content, plasma Na+ level and Na+ loss were measured. Studies were conducted on male Wistar rats during a pre-experimental and experimental period. Animals were equally divided into four groups: unsupplemented vivarium control rats (UVCR), unsupplemented hypokinetic rats (UHKR), supplemented vivarium control rats (SVCR) and supplemented hypokinetic rats (SHKR). A daily supplementation of 3.50 mEq sodium chloride (NaCl) was given to animals in the SVCR and SHKR groups. Gastrocnemius muscle and right femur bone Na+ level decreased (p<0.05), and plasma Na+ level and urine and fecal Na+ loss increased (p<0.05) in the SHKR and UHKR groups compared to their pre-experimental values and the values in their respective vivarium control groups (SVCR and UVCR). Muscle and bone Na+ content decreased more (p<0.05), and plasma Na+ level and urine and fecal Na+ loss increased more (p<0.05) in the SHKR group than in the UHKR group. It is concluded that tissue Na+ deficiency during HK is more evident when Na+ intake is higher and that the total bodily Na+ loss exacerbated more with higher than lower tissue Na+ deficiency. This shows that tissue Na+ deficiency is not the result of the lower Na+ content in the food consumed and that the total bodily Na+ loss is not caused by the higher tissue Na+ content but due to the impossibility of the body to use Na+ when animals are submitted to prolonged HK.
Physiological chemistry and physics and medical NMR 02/2007; 39(2):235-45.
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ABSTRACT: This study aims at showing that during hypokinesia (HK) tissue magnesium (Mg2+) content decreases more with higher Mg2+ intake than with lower Mg2+ intake and that Mg2+ loss increases more with higher than lower tissue Mg2+ depletion due to inability of the body to use Mg2+ during HK. Studies were conducted on male Wistar rats during a pre-HK period and a HK period. Rats were equally divided into four groups: unsupplemented vivarium control rats (UVCR), unsupplemented hypokinetic rats (UHKR), supplemented vivarium control rats (SVCR) and supplemented hypokinetic rats (SHKR). SVCR and SHKR consumed 42 mEq Mg2+ per day. The gastrocnemius muscle and right femur bone Mg2+ content decreased significantly, while plasma Mg2+ level and urine and fecal Mg2+ loss increased significantly in SHKR and UHKR compared with their pre-HK values and their respective vivarium controls (SVCR and UVCR). However, muscle and bone Mg2+ content decreased more significantly and plasma Mg2+ level, and urine and fecal Mg2+ loss increased more significantly in SHKR than in UHKR. The greater tissue Mg2+ loss with higher Mg2+ intake and the lower tissue Mg2+ loss with lower Mg2+ intake shows that the risk of higher tissue Mg2+ depletion is directly related to the magnitude of Mg2+ intake. The higher Mg2+ loss with higher tissue Mg2+ depletion and the lower Mg2+ loss with lower Mg2+ tissue depletion shows that the risk of greater Mg2+ loss is directly related to the magnitude of tissue Mg2+ depletion. It was concluded that tissue Mg2+ depletion increases more when the Mg2+ intake is higher and that Mg2+ loss increases more with higher than lower tissue Mg2+ depletion indicating that during prolonged HK the tissue Mg2+ depletion is not due to the Mg2+ shortage in food but to the inability of the body to use Mg2+.
Physiological chemistry and physics and medical NMR 02/2006; 38(2):93-104.
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ABSTRACT: The aim of this study was to determine that hypokinesia (restricted motor activity) could increase potassium (K+) losses with decreased tissue K+ content showing decreased K+ deposition. To this end, measurements were made of K+absorption, tissue K+ content, plasma K+ levels, fecal and urinary K+ excretion during and after hypokinesia (HK) with and without K+ supplementation. Studies conducted on male Wistar rats during a pre-hypokinetic period, a hypokinetic period and a post-hypokinetic period. Rats were equally divided into four groups: unsupplemented vivarium control rats (UVCR), unsupplemented hypokinetic rats (UHKR), supplemented vivarium control rats (SVCR) and supplemented hypokinetic rats (SHKR). SHKR and UHKR were kept in small individual cages which restricted their movements in all directions without hindering food and water consumption. SVCR and UVCR were housed in individual cages under vivarium control conditions. SVCR and SHKR consume daily 3.96 mEq potassium chloride (KCl) per day. Absorption of K+, and K+ levels in bone, muscle, plasma, urine and feces and PA levels did not change in SVCR and UVCR compared with their pre-HK levels. During HK, plasma, fecal and urinary K+ levels and plasma aldosterone (PA) levels increased significantly (p<0.05) with time, while K+ absorption, muscle and bone K+ content decreased significantly (p<0.05) with time in SHKR and UHKR compared with their pre-HK values and the values in their respective vivarium controls (SVCR and UVCR). During the initial 9-days of post-HK, K+ absorption increased significantly (p<0.05) and plasma K+ levels, fecal and urinary K+ losses and PA levels decreased significantly (p<0.05) and muscle and bone K+ content remained significantly (p<0.05) depressed in SHKR and UHKR compared with their pre-HK and their respective vivarium control values. During HK and post-HK periods, K+ absorption, bone and muscle K+ content, and K+ levels in plasma, urine and feces and PA levels were affected significantly (p<0.05) more in SHKR than in UHKR. By the 15th day of post-HK the values in SHKR and UHKR approach the control values. The higher K+ losses during HK with decreased tissue K+ levels shows decreased K+ deposition. The higher K+ loss with lower tissue K+ levels in SHKR than in UHKR shows that K+ deposition decreases more with K+ supplementation than without. Because SHKR had shown lower tissue K+ content and lost higher K+ amounts than UHKR it was concluded that the risk of decreased K+ deposition and tissue K+ depletion is inversely related to K+ intake, i.e., the higher K+ intake, the greater the risk for decreased K+ deposition, and the higher K+ losses and the greater the risk for tissue K+ depletion. The dissociation between tissue K+ depletion and K+ excretion indicates decreased K+ deposition as the principal mechanism of tissue K+ depletion during prolonged HK.
International journal of medical sciences 02/2005; 2(3):107-13. · 2.24 Impact Factor
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ABSTRACT: The objective of this study was to show that hypokinesia (diminished movement) could affect differently water and electrolyte content in muscles having minimum differences in their function and morphology. To this end, we studied water and electrolyte content in skeletal and cardiac muscles, fluid excretion, electrolyte absorption, and electrolyte levels in plasma, urine and feces of rats during prolonged hypokinesia (HK). Studies were conducted on one-hundred-twenty-six 13-weeks old male Wister rats during a pre-hypokinetic period and a hypokinesia period. Animals were equally divided into two groups: vivarium control rats (VCR) and hypokinetic rats (HKR). Hypokinetic animals were kept in small individual cages which restricted their movements in all directions without hindering food and water intake. Control rats were housed in individual cages under vivarium control conditions. Sodium (Na+) and potassium (K+) absorption, electrolyte and water content in cardiac muscles (right and left ventricle), thigh extensor (quadriceps femoris muscle) and long muscle of the back (biceps femoris muscle), urine volume, and electrolyte levels in plasma and urine and feces did not change in VCR when compared to their pre-hypokinetic levels. The absorption of Na+ and K+, water and electrolyte content in cardiac and skeletal muscles decreased significantly, while urine volume, plasma electrolyte levels and urine and fecal electrolyte excretion increased significantly in HKR compared with their pre-HK values and with their respective vivarium control (VCR). Water and electrolyte content decreased more significantly in skeletal than in cardiac muscles. Water and electrolyte levels decreased more in the thigh extensor and in the right ventricle than in the long muscle of the back, the left ventricle or the septum. Muscles suffering from higher water and electrolyte loss against the background of lower water and electrolyte content show lower water and electrolyte deposition. Lower electrolyte and water content in skeletal than in cardiac muscle shows that water and electrolyte content decreases more in skeletal than cardiac muscles. Skeletal muscle showed lower water and electrolyte content than cardiac muscle indicating that the risk for decreased muscle water and electrolyte content is inversely related to the muscle function and morphology, i.e., the more weight-bearing supporting function and morphology muscles have, the higher the risk for lower muscle water and electrolyte content. It was concluded that the greater muscle function and morphology, the lower electrolyte and water deposition, the higher water and electrolyte losses, and the lower water and electrolyte content.
Physiological chemistry and physics and medical NMR 02/2005; 37(2):127-40.
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ABSTRACT: Measuring calcium (Ca) absorption, Ca balance and Ca level in serum,feces and urine during HK (hypokinesia) with and without Ca loading, the aim of this study was to disclose if prolonged HK could reduce Ca deposition more with or without Ca load contributing to greater Ca imbalance. Studies were conducted during 30-days pre-HK and 364-days HK. Forty male normal volunteers 23.7+/-6.0 years of age were chosen as subjects. They were divided into four groups: unloaded active control subjects (UACS), unloaded hypokinetic subjects (UHKS), loaded active control subjects (LACS), loaded hypokinetic subjects (LHKS). All hypokinetic subjects were walking average distances of 0.5+/-0.2 km day(-1), and active control subjects were running average distances of 6.6+/-1.2 km day(-1). LACS and LHKS were loaded with 1.3 mmol calcium lactate/kg body wt. Before Ca load, fecal Ca loss, urinary Ca and phosphate (P) losses, Ca imbalance, serum ionized calcium (CaI), P and total Ca (Ca(t)) levels increased significantly. (P < 0.05) with time, and serum intact parathyroid hormone (iPTH), 1.25 dihydroxyvitamin D (1.25(OH)2D3) levels and Ca absorption, decreased significantly (P < 0.05) with time in LHKS and UHKS compared with their pre-HK values and their respective active controls (LACS and UACS). After Ca load, however, Ca absorption, serum iPTH and 1.25 (OH)2D3 levels decreased significantly (P < 0.05) more with time, while fecal Ca loss, urinary Ca and P excretion and Ca imbalance increased significantly (P < 0.05) more with time in LHKS than UHKS. Conversely, before and after Ca load, fecal Ca excretion, urinary P and Ca loss, serum CaI, P, Ca, iPTH and 1.25 (OH)2D3 levels, Ca absorption and Ca balance did not change in LACS and UACS compared with their pre-HK values. The greater Ca losses with than without Ca load have shown that the more Ca is consumed the more Ca is eliminated during HK and Ca imbalance. The significant increase of Ca loss with Ca imbalance demonstrated reduced Ca deposition. Dissociation between Ca loss and Ca imbalance demonstrated reduced Ca deposition as the mechanism of Ca imbalance development during HK.
International Urology and Nephrology 01/2004; 36(3):293-302. · 1.47 Impact Factor
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ABSTRACT: Measuring potassium (K+) absorption, and K+ levels in plasma, urine and feces during and after hypokinesia (HK) and K+ supplementation, the aim of this study was to determine if prolonged HK could depress K+ deposition significantly more with or without K+ supplementation. Studies were conducted during 30-days pre-HK, 364-days HK and 30-days post-HK. Forty male healthy volunteers 24.2+/-5.5 years of age were chosen as subjects. They were equally divided in four groups: unsupplemented active control subjects (UACS), unsupplemented hypokinetic subjects (UHKS), supplemented active control subjects (SACS), and supplemented hypokinetic subjects (SHKS). Hypokinetic subjects were walking average distances of 0.5+/-0.2 km day(-1). Active control subjects were running average distances of 5.8+/-1.2 km day(-1). Both SHKS and SACS consumed daily 2.17 mEq elemental potassium per kg body weight. Potassium absorption, fecal and urinary K+ excretion, sodium (Na+) loss, plasma K+ and Na+ level and plasma aldosterone (PA) level did not change in SACS and UACS compared with their pre-HK values. During HK, K+ absorption decreased significantly (P < 0.05) with time, and fecal and urinary K+ loss, urinary Na+ loss, plasma K+ and Na+ levels and PA level increased significantly (P < 0.05) with time in SHKS and UHKS compared with their pre-HK values and their respective active controls (SACS and UACS). During initial 15-days of post-HK, K+ absorption increased significantly (P < 0.05), fecal and urinary K+ excretion, urinary Na+ excretion and plasma K+ and Na+ levels and PA level decreased significantly (P < 0.05) in hypokinetic compared with active control subjects; by the 30th day they approached the control levels. During HK and post-HK, K+ absorption, fecal and urinary K+ losses, urinary Na+ excretion, plasma K+ and Na+ levels and PA level, changed significantly (P < 0.05) more in SHKS than UHKS. Decreased K+ losses during post-HK showed K+ depletion during HK. Decreased K+ absorption with K+ depletion during HK showed decreased K+ deposition. The greater K+ changes in SHKS than UHKS, during HK and post-HK, demonstrated that K+ deposition decreased more with than without K+ supplementation. It was concluded that dissociation between K+ absorption and K+ depletion showed decreased K+ deposition as the main mechanism for K+ depletion during HK.
International Urology and Nephrology 01/2004; 36(3):303-12. · 1.47 Impact Factor
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ABSTRACT: Measuring intercompartmental, blood and urinary biochemical parameters during acute bed rest (ABR) and rigorous bed rest (RBR) the aim of this work was to disclose if ABR or RBR could influence significantly more and significantly faster the body hydration level in normal subjects. Studies conducted during pre-bed rest (BR) period of 3-days and during 7-days period of ABR and RBR. Thirty normal male individuals 24.6 +/- 5.7 years of age were chosen as subjects. They were divided into three groups: unrestricted active control subjects (UACS), acute bed rested subjects (ABRS) and rigorous bed rested subjects (RBRS). Acute bed rested subjects confined abruptly to RBR, while they did not have any prior knowledge of the exact date and time when they would be subjected to RBR. RBRS were submitted to RBR in a predetermined date and time known to them right from the start of the study. UACS were not subjected to any form of BR. Fluid loss, urinary and plasma sodium (Na+) and potassium (K+), plasma osmolality, whole blood hematocrit (Hct) and hemoglobin (Hb), and total plasma protein level increased significantly (p < 0.05), while urinary osmolality, extracellular volume (ECV), plasma volume (PV), red cell volume (RCV), blood volume (BV), interstitial volume (IV) and fluid consumption decreased significantly (p < 0.05) in ABRS and RBRS compared with their pre-BR values and their control (UACS). However, the measured variables changed significantly (p < 0.05) more and significantly faster in ABRS than RBRS. Conversely, whole blood Hct and Hb levels, fluid consumption and fluid loss, urinary and plasma osmolality, urinary and plasma electrolytes, plasma protein, ECV, PV, RCV, BV and IV levels were not change in UACS compared with their pre-BR values. Significantly greater and significantly faster intercompartmental, blood and urinary biochemical changes were observed in ABRS than RBRS. Body hydration was affected significantly more and significantly faster in ABR than RBR. It was concluded, the more abruptly normal activity is restricted the smaller the body hydration in bed rested subject is, and probably in patients who are abruptly confined to RBR.
International Urology and Nephrology 01/2003; 35(4):457-65. · 1.47 Impact Factor
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ABSTRACT: Measuring fluid absorption and fluid homeostasis, the aim of this study was to establish if hypokinesia (HK) could depress fluid deposition and thus contribute to the development of fluid depletion. Studies were performed during 30 days pre-HK period and during 364 days HK period. Twenty healthy male individuals 24.0 +/- 6.6 years of age were chosen as subjects. They were equally divided into two groups: active control subjects (ACS) and hypokinetic subjects (HKS). All HKS were walking average distances of 0.7 +/- 0.2 km x day(-1) for 364 days, while all ACS were running average distances of 8.5 +/- 1.2 km x day(-1) for 364 days. Water imbalance, whole blood hemoglobin (Hb) and hematocrit (Hct), plasma protein, plasma osmolality, urinary and plasma sodium (Na+) and potassium (K+) levels and fluid loss increased significantly (p < 0.05), while fluid absorption, fluid consumption, glomerular filtration rate (GFR), and renal blood flow (RBF) reduced significantly (p < 0.05) in HKS compared with their pre-HK values and their respective active controls (ACS). Conversely, water balance, whole blood Hb and Hct, plasma protein, plasma osmolality, fluid absorption, GFR, RBF, urinary and plasma Na+ and K+ levels, fluid consumption and fluid loss did not change in ACS compared with their pre-HK control values. Significant increase of fluid loss with fluid imbalance may demonstrate decreased fluid deposition. Dissociation between fluid loss and fluid imbalance may demonstrate decreased fluid deposition as the mechanism of development of fluid depletion. It was concluded that fluid imbalance and the significant increase of Hb, Hct, plasma protein, plasma osmolality, urinary and plasma Na+ and K+ levels may demonstrate the presence of fluid depletion during prolonged HK in humans.
International Urology and Nephrology 01/2003; 35(2):153-9. · 1.47 Impact Factor
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ABSTRACT: Hypokinesia (diminished movement) induces phosphate (P) changes; however, it is not known if P change is greater in trained than untrained subjects. Measuring P balance and P retention during hypokinesia (HK) and P load, we studied if changes in P retention and P depletion were significantly (p<0.05) greater in trained than untrained subjects. Studies were done during a 30-d pre-HK period and a 364-d HK period. Forty male trained and untrained healthy individuals aged 24.5+/-5.4 yr were chosen as subjects. All volunteers were equally divided into four groups: trained ambulatory control subjects (TACS), trained hypokinetic subjects (THKS), untrained ambulatory control subjects (UACS), and untrained hypokinetic subjects (UHKS). All THKS and UHKS were limited to an average walking distance of 0.3 km/d, and TACS and UACS were on an average running distance of 9.8 and 1.8 km/d, respectively. Subjects took daily 12.7-mmol dicalcium-phosphate/kg body weight in the form of supplementation. Negative P balance, fecal P loss, urinary P and calcium (Ca) excretion, serum P, and total Ca (Cat) levels increased significantly (p<0.05), whereas P retention, serum 1,25-dihydroxyvitamin D [1,25 (OH)2D3] and intact parathyroid hormone (iPTH) level decreased significantly (p<0.05) in THKS and UHKS when compared with their pre-HK values and their respective ambulatory controls (TACS and UACS). However, P retention, P balance, serum, urinary, and fecal P, and serum hormone level changed significantly (p<0.05) more in THKS than UHKS. Retention of P, fecal P, urinary P and Ca loss, serum P and Cat level, P balance, 1,25(OH)2D3, and iPTH level change insignificantly (p>0.05) in TACS and UACS when compared with their pre-HK control values. It was concluded that significant negative P balance may indicate P depletion, whereas significant P loss in spite of negative P balance and P load may suggest P retention incapacity; however, P depletion was greater in THKS than UHKS. Clearly, P is wasted much more in THKS than UHKS.
Biological Trace Element Research 09/2002; 88(2):125-38. · 1.92 Impact Factor
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ABSTRACT: Bed rest (BR) induces significant urinary and blood electrolyte changes, but little is known about the effect of fluid and salt supplements (FSS) on catabolism, hydration and electrolytes. The aim was to measure the effect of FSS on catabolism, body hydration and electrolytes during BR. Studies were done during 7 days of a pre-bed rest period and during 30 days of a rigorous bed rest period. Thirty male athletes aged, 24.6 +/- 7.6 years were chosen as subjects. They were divided into three groups: unsupplemented ambulatory control subjects (UACS), unsupplemented bed rested subjects (UBRS) and supplemented bed rested subjects (SBRS). The UBRS and SBRS groups were kept under a rigorous bed rest regime for 30 days. The SBRS daily took 30 ml water per kg body weight and 0.1 sodium chloride per kg bodyweight. Plasma sodium (Na), potassium (K), calcium (Ca) and magnesium (Mg) levels, urinary Na, K, Ca and Mg excretion, plasma osmolality, plasma protein level, whole blood hemoglobin (Hb) and hematocrit (Hct) level increased significantly (p < or = 0.05), while plasma volume (PV), body weight, body fat, peak oxygen uptake, food and fluid intake decreased significantly (p < or = 0.05) in the UBRS group when compared with the SBRS and UACS groups. In contrast, plasma and urinary electrolytes, osmolality, protein level, whole blood Hct and Hb level decreased significantly (p < or = 0.05), while PV, fluid intake, body weight and peak oxygen uptake increased significantly (p < or = 0.05) in the SBRS group when compared with the UBRS group. The measured parameters did not change significantly in the UACS group when compared with their baseline control values. The data indicate that FSS stabilizes electrolytes and body hydration during BR, while BR alone induces significant changes in electrolytes and body hydration. We conclude that FSS may be used to prevent catabolism and normalize body hydration status and electrolyte values during BR.
Acta Astronautica 07/2002; 50(12):765-74. · 0.61 Impact Factor
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ABSTRACT: Rigorous bed rest (RBR) induces significant biochemical and circulatory changes. However, little is known about acute rigorous bed rest (ARBR). Measuring biochemical and circulatory variables during ARBR and RBR the aim of this study was to establish the significance of ARBR effect. Studies were done during 3 days of a pre-bed rest (BR) period and during 7 days of ARBR and RBR period. Thirty normal male individuals aged, 24.1 +/- 6.3 years were chosen as subjects. They were divided equally into three groups: 10 subjects placed under active control conditions served as unrestricted ambulatory control subjects (UACS), 10 subjects submitted to an acute rigorous bed rest served as acute rigorous bed rested subjects (ARBRS) and 10 subjects submitted to a rigorous bed rest served as rigorous bed rested subjects (RBRS). The UACS were maintained under an average running distance of 9.7 km day-1. For the ARBR effect simulation, ARBRS were submitted abruptly to BR for 7 days. They did not have any prior knowledge of the exact date and time when they would be asked to confine to RBR. For the RBR effect simulation, RBRS were subjected to BR for 7 days on a predetermined date and time known to them right away from the start of the study. Plasma renin activity (PRA), plasma cortisol (PC), plasma aldosterone (PA), plasma and urinary sodium (Na) and potassium (K) levels, heart rate (HR), cardiac output (CO), and arterial blood pressure (ABP) increased significantly, and urinary aldosterone (UA), stroke volume (SV) and plasma volume (PV) decreased significantly (p<0.05) in ARBRS and RBRS as compared with their pre-BR values and the values in UACS. Electrolyte, hormonal and hemodynamic responses were significantly (p<0.05) greater and occurred significantly faster (p<0.05) during ARBR than RBR. Parameters change insignificantly (p>0.05) in UACS compared with pre-BR control values. It was concluded that, the more abruptly muscular activity is restricted in experimental subjects while they are very active, the greater hemodynamic and biochemical change there is and probably in individuals whose muscular activity is abruptly terminated after an accident or sudden illness.
Acta Astronautica 07/2002; 50(11):713-20. · 0.61 Impact Factor
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ABSTRACT: Hypokinesia (diminished movement) induces significant magnesium (Mg) changes; however, little is known about Mg deposition and Mg depletion during HK. Measuring the Mg level in some tissues during HK and post-HK and Mg supplement, we aimed to establish Mg deposition and Mg depletion during prolonged HK. Studies were done on 408, 13-wk-old male Wistar rats (370-390 g) for a 15-d pre-HK period, a 98-d HK period, and a 15-d post-HK period. Rats were equally divided into four groups: unsupplemented vivarium control rats (UVCR), unsupplemented hypokinetic rats (UHKR), supplemented vivarium control rats (SVCR), and supplemented hypokinetic rats (SHKR). Both UHKR and SHKR were kept in small individual cages. The SVCR and SHKR took 53 mg Mg/d. During the HK period, plasma, urinary, and fecal Mg levels increased significantly (p < or = 0.05), whereas during the post-HK period Mg deposition, muscle and bone Mg content decreased significantly (p < or = 0.05) in UHKR and SHKR when compared with their pre-HK values and their respective vivarium controls (UVCR and SVCR). During the initial days of the post-HK period, plasma, urinary, and fecal Mg levels decreased significantly (p < or = 0.05), whereas during the post-HK period Mg deposition, muscle and bone Mg content remained significantly (p < or = 0.05) depressed in UHKR and SHKR when compared with UVCR and SVCR, respectively. However, during the HK period and post-HK period Mg deposition, bone, muscle, plasma, urinary, and fecal Mg levels changed significantly (p < or = 0.05) more in SHKR than UHKR. By contrast, during the HK period and post-HK period. Mg deposition, muscle, bone, plasma, urinary, and fecal Mg values change insignificantly (p > 0.05) in UVCR and SVCR when compared with their pre-HK values. It was concluded that reduced muscle, bone, plasma, urinary, and fecal Mg during post-HK and Mg supplement may demonstrate Mg depletion, whereas higher Mg loss during HK despite reduced muscle and bone Mg and Mg depletion might demonstrate Mg deposition incapacity during HK.
Biological Trace Element Research 06/2002; 86(3):203-16. · 1.92 Impact Factor
