Dehydration-induced vasopressin secretion in humans: involvement of the histaminergic system.
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In rats, the hypothalamic neurotransmitter histamine participates in regulation of vasopressin secretion and seems to be of physiological importance, because blockade of the histaminergic system reduces dehydration-induced vasopressin secretion. We investigated whether histamine is also involved in regulation of vasopressin secretion during dehydration in humans. We found that 40 h of dehydration gradually increased plasma osmolality by 10 mosmol/kg and induced a fourfold increase in vasopressin levels. Pretreatment with the H(2)-receptor antagonists cimetidine or ranitidine significantly reduced the dehydration-induced increase in vasopressin levels approximately 40% after 34 and 37 h of dehydration, whereas this was not the case with the H(1)-receptor antagonist mepyramine. Dehydration reduced aldosterone secretion by approximately 50%. This effect of dehydration was reduced by both H(1)- and H(2)-receptor blockade after 16 and/or 34 h of dehydration. We conclude that vasopressin secretion in response to dehydration in humans is under the regulatory influence of histamine and that the effect seems to be mediated via H(2)-receptors. In addition, the regulation of aldosterone secretion during dehydration also seems to involve the histaminergic system via H(1) and H(2) receptors. (+info)
Prolonged exercise after diuretic-induced hypohydration: effects on substrate turnover and oxidation.
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To determine the influence of a diuretic-induced reduction in plasma volume (PV) on substrate turnover and oxidation, 10 healthy young males were studied during 60 min of cycling exercise at 61% peak oxygen uptake on two separate occasions > or =1 wk apart. Exercise was performed under control conditions (CON; placebo), and after 4 days of diuretic administration (DIU; Novotriamazide; 100 mg triamterene and 50 mg hydrochlorothiazide). DIU resulted in a calculated reduction of PV by 14.6 +/- 3.3% (P < 0.05). Rates of glucose appearance (R(a)) and disappearance (R(d)) and glycerol R(a) were determined by using primed constant infusions of [6,6-(2)H]glucose and [(2)H(5)]glycerol, respectively. No differences in oxygen uptake during exercise were observed between trials. Main effects for condition (P < 0.05) were observed for plasma glucose and glycerol, such that the values observed for DIU were higher than for CON. No differences were observed in plasma lactate and serum free fatty acid concentrations either at rest or during exercise. Hypohydration led to lower (P < 0.05) glucose R(a) and R(d) at rest and at 15 and 30 min of exercise, but by 60 min, the effects were reversed (P < 0. 05). Hypohydration had no effect on rates of whole body lipolysis or total carbohydrate or fat oxidation. A main effect for condition (P < 0.05) was observed for plasma glucagon concentrations such that larger values were observed for DIU than for CON. A similar decline in plasma insulin occurred with exercise in both conditions. These results indicate that diuretic-induced reductions in PV decreases glucose kinetics during moderate-intensity dynamic exercise in the absence of changes in total carbohydrate and fat oxidation. The specific effect on glucose kinetics depends on the duration of the exercise. (+info)
Effects of alloxan diabetes, anti-insulin serum diabetes, and non-diabetic dehydration on brain carbohydrate and energy metabolism in young mice.
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Alloxan-induced diabetes of 4 days duration produced metabolite changes in brain compatible with severe reduction in cerebral metabolism (phosphocreatine increased 70%), and reduced phosphofructokinase activity (fructose diphosphate levels fell 38%). There was a 56% reduction in brain lactate concentration, but pyruvate levels were unchanged. In 5 of 23 animals, brain glycogen levels increased; in the remainder blycogen levels decreased. Brain fructose concentration, 0.4 mmol/kg, was only 1/30 of the glucose concentration. The alloxan-treated animals were also severely dehydrated. Therefore, to determine the casual relation of insulin deficiency to these findings, the effects of chronic dehydration and acute insulin deficiency were investigated. Findings in the brains of severely dehydrated animals (water deprivation and mannitol injections for 4 days) were almost identical with those seen after alloxan treatment. The exceptions were that, in the dehydrated mice, reductions in lactate and pyruvate were proportional, and glycogen levels were consistently reduced. In acute diabetes (6 to 24 hours after repeated anti-insulin serum injections) P-creatine, fructose diphosphate, and lactate levels were normal. Pyruvate levels were normal at 6 hours, but increased 39% by 12 to 24 hours; glycogen was 36% higher at 6 hours and 63% at 12 to 24 hours. Insulin (and glucose) appeared to be specific in correcting the metabolic abnormalities found in the brains of animals with alloxan-induced diabetes. At 4 and one half hours after treatment with insulin and glucose, glucose 6-phosphate levels fell 25%, fructose diphosphate increased 28%, and lactate and the lactate to pyruvate ratio returned to normal; glycogen increased 50%. However, the treatment also had a dramatic clinical effect. Since animals gained 8 to 27% of body weight during therapy, at least some of the improvements in metabolite levels could be related to rehydration. (+info)
Impaired solute accumulation in inner medulla of Clcnk1-/- mice kidney.
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The CLC-K1 chloride channel is a kidney-specific CLC chloride channel expressed in the thin ascending limb of Henle's loop (tAL). Recently, we determined that Clcnk1-/- mice show nephrogenic diabetes insipidus (NDI). To investigate the pathogenesis of impaired urinary concentrating ability, we analyzed renal functions of Clcnk1-/- mice in more detail. The osmolar clearance-to-creatinine clearance ratio was not significantly different between Clcnk1+/- and Clcnk1+/+ mice. Fractional excretion of sodium, chloride, and urea was also not significantly affected in Clcnk1-/- mice. These results indicate that the polyuria observed in Clcnk1-/- mice was water diuresis and not osmotic diuresis. The papillary osmolarity in Clcnk1-/- mice was significantly lower than that in Clcnk1+/+ mice under a hydrated condition, and it did not increase even after water deprivation. Sodium and chloride contents in the inner medulla in Clcnk1-/- mice were at about one-half the levels observed in Clcnk1+/+ mice. Furthermore, the accumulation of urea was also impaired in Clcnk1-/- mice, suggesting that the overall countercurrent system was impaired by a defect of its single component, chloride transport in the tAL. The aldose reductase mRNA abundance in Clcnk1-/- mice was decreased, further evincing that inner medullary tonicity is decreased in Clcnk1-/- mice. We concluded that NDI in Clcnk1-/- mice resulted from an impairment in the generation of inner medullary hypertonicity by a dysfunction of the countercurrent systems. (+info)
Effect of increased peritubule protein concentration on proximal tubule reabsorption in the presence and absence of extracellular volume expansion.
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The effect of increased peritubule capillary oncotic pressure on sodium reabsorption by the proximal tubule of the dog was investistigated after extracellular volume expansion (ECVE) with Ringer's solution or during continued hydropenia. Control measurements were made after ECVE or during hydropenia and again during renal arterial infusion with hyperoncotic albumin solution. Absolute reabsorption by the proximal tubule was calculated from fractional reabsorption and single nephron filtration rates as determined by micropuncture. Direct measurements of efferent arteriole protein were used to determine efferent arteriolar oncotic pressure. Albumin infused into the renal artery after ECVE significantly increased efferent oncotic pressure by 17.6 plus or minus 5.3 mm Hg. Fractional and absolute reabsorption by the proximal tubule increased from 20 plus or minus 6 to 37 plus or minus 5% and from 22 plus or minus 6 to 36 plus or minus 7 nl/min, respectively. During hydropenia, the albumin infusion significantly increased efferent oncotic pressure by 15.0 plus or minus 4.4 mm Hg. However, in contrast to the effect seen during ECVE, neither fractional nor absolute reabsorption was changed, delta equals 0.3 plus or minus 1.5% and 3 plus or minus 5 nl/min, respectively. Single nephron filtration rates were not significantly different between the groups and were unchanged by the albumin infusion. Peritubule capillary hydrostatic pressures, measured with a null-servo device, were not changed by the albumin infusion in either group. Renal interstitial hydrostatic pressure, measured from chronically implanted polyethylene capsules, was decreased significantly from 7.2 plus or minus 0.9 to 3.4 plus or minus 0.6 mm Hg in the hydropenic group and from 0.6 plus or minus 0.6 to 4.8 plus or minus 0.7 mm Hg in the Ringer's expanded group. In the hydropenic group, the increase in efferent oncotic pressure was nearly compensated for by changes in interstitial forces so that the calculated net force for capillary uptake was almost unchanged, 17.8 mm Hg before vs. 21.4 mm Hg during the albumin infusion. The increased efferent oncotic pressure in the Ringer's expanded group was not compensated, so that the calculated net force for uptake was increased, 11.9 mm Hg before to 22.2 mm Hg during the albumin infusion. Thus, while the increase in efferent oncotic pressure during albumin infusion was not significantly different between the groups, absolute and fractional reabsorptions were increased only in the animals in which the extracellular volume was expanded. The results suggest that ECVE alters the effect of increased peritubule oncotic pressure on sodium reabsorption by the proximal tubule. (+info)
Effects of marked hyperthermia with and without dehydration on VO(2) kinetics during intense exercise.
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This study determined whether marked hyperthermia alone or in combination with dehydration reduces the initial rate of rise in O(2) consumption (VO(2) on-kinetics) and the maximal rate of O(2) uptake (VO(2 max)) during intense cycling exercise. Six endurance-trained male cyclists completed four maximal cycle ergometer exercise tests (402 +/- 4 W) when euhydrated or dehydrated (4% body wt) with normal (starting esophageal temperature, 37.5 +/- 0.2 degrees C; mean skin temperature, approximately 31 degrees C) or elevated (+1 and +6 degrees C, respectively) thermal strain. In the euhydrated and normal condition, subjects reached VO(2 max) (4.7 +/- 0.2 l/min) in 228 +/- 34 s, with a mean response time of 42 +/- 2 s, and fatigued after 353 +/- 39 s. Hyperthermia alone or in combination with dehydration reduced mean response time (17-23%), VO(2 max) (16%), and performance time (51-53%) (all P < 0.01) but did not alter the absolute response time (i.e., the time to reach 63% response in the control trial, 3.2 +/- 0.1 l/min, 42 s). Reduction in VO(2 max) was accompanied by proportional decline in O(2) pulse and significantly elevated maximal heart rate (195 vs. 190 beats/min for hyperthermia vs. normal). Preventing hyperthermia in dehydrated subjects restored VO(2 max) and performance time by 65 and 50%, respectively. These results demonstrate that impaired high-intensity exercise performance with marked skin and internal body hyperthermia alone or in combination with dehydration is not associated with a diminished rate of rise in VO(2) but decreased VO(2 max). (+info)
Upregulation of the secretory-type Na(+)/K(+)/2Cl(-)-cotransporter in the kidney by metabolic acidosis and dehydration in rats.
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The functional role and mechanisms of regulation of the Na(+)/K(+)/2Cl(-)-cotransporter NKCC1 in the kidney have not yet been clarified. NKCC1 mRNA and protein expression in control rats, rats with dehydration (2 d), and rats with metabolic acidosis (NH(4)Cl in the food for 6 to 7 d) was examined using reverse transcription-PCR and Western blotting. In contrast to the abundant NKCC1 mRNA expression in the terminal inner medullary collecting ducts in mice, expression was found to be most abundant in the outer medullary collecting ducts (OMCD) in rats. Dehydration and metabolic acidosis increased NKCC1 mRNA expression three- to fivefold not only in the OMCD but also in the cortical collecting ducts and inner medullary collecting ducts. Dehydration and metabolic acidosis increased NKCC1 protein expression twofold in the membrane fraction from the outer medulla. NKCC1 protein expression was observed not in the microdissected medullary thick ascending limbs but in the OMCD, and it was stimulated twofold by dehydration and metabolic acidosis. Incubation of OMCD in low-pH medium increased NKCC1 mRNA expression. In summary, NKCC1 mRNA and protein expression is upregulated with dehydration and metabolic acidosis. NKCC1 may play an important role in adaptation to these physiologic conditions. Low pH and possibly hypertonicity stimulate NKCC1 mRNA expression in OMCD. (+info)
The etiologies, pathophysiology, and alternative/complementary treatment of asthma.
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A chronic inflammatory disorder of the respiratory airways, asthma is characterized by bronchial airway inflammation resulting in increased mucus production and airway hyper-responsiveness. The resultant symptomatology includes episodes of wheezing, coughing, and shortness of breath. Asthma is a multifactorial disease process with genetic, allergic, environmental, infectious, emotional, and nutritional components. The underlying pathophysiology of asthma is airway inflammation. The underlying process driving and maintaining the asthmatic inflammatory process appears to be an abnormal or inadequately regulated CD4+ T-cell immune response. The T-helper 2 (Th2) subset produces cytokines including interleukin-4 (IL-4), IL-5, IL-6, IL-9, IL-10, and IL-13, which stimulate the growth, differentiation, and recruitment of mast cells, basophils, eosinophils, and B-cells, all of which are involved in humoral immunity, inflammation, and the allergic response. In asthma, this arm of the immune response is overactive, while Th1 activity, generally corresponding more to cell-mediated immunity, is dampened. It is not yet known why asthmatics have this out-of-balance immune activity, but genetics, viruses, fungi, heavy metals, nutrition, and pollution all can be contributors. A plant lipid preparation containing sterols and sterolins has been shown to dampen Th2 activity. Antioxidant nutrients, especially vitamins C and E, selenium, and zinc appear to be necessary in asthma treatment. Vitamins B6 and B12 also may be helpful. Omega-3 fatty acids from fish, the flavonoid quercetin, and botanicals Tylophora asthmatica, Boswellia serrata and Petasites hybridus address the inflammatory component. Physical modalities, including yoga, massage, biofeedback, acupuncture, and chiropractic can also be of help. (+info)