The American journal of physiology
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Regulation of brain water and electrolytes during acute hyperosmolal states has been studied in anesthetized rats. Rats were injected intravenously or intraperitoneally with hypertonic NaCl, mannitol, or sucrose (hyperosmolal series) or with isotonic NaCl (isosmolal controls). Terminal plasma osmolality varied from 290 to 385 mosmol/kg and the experimental duration from 15 to 120 min. ⋯ This gain was sufficient to account quantitatively for tissue volume regulation at 120 min of hypernatremia but not at shorter times or during mannitol- or sucrose-induced hyperosmolality. Water loss and electrolyte uptake occur simultaneously, over 30 min, which limits the degree of brain shrinkage. Results of this analysis of the time course and magnitude of tissue electrolyte gain during acute hyperosmolality form the basis for the following two studies of the volume regulatory influx of electrolyte from plasma and CSF, respectively.
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Adult male Sprague-Dawley rats were divided into three groups and fed diets containing either 10, 20, or 40% protein for 56 days. Half of the rats in each dietary condition were given a 32% sucrose solution plus the standard diet and water. Sucrose intake varied directly as a function of dietary protein levels. ⋯ Rats fed the 40% protein diet and sucrose did not exhibit overeating, excess weight gain, or increased feed efficiency relative to animals fed the 40% diet alone. Animals given sucrose had more interscapular brown adipose tissue (IBAT) and a greater metabolic potential for thermogenesis in IBAT as determined by GDP binding in mitochondria than rats not fed sucrose. These results demonstrate that dietary protein is important in the development of sucrose-induced obesity and that increases in IBAT mass and activity can occur concomitant with increased feed efficiency.
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The mechanisms responsible for maintenance of the high-output state associated with thyrotoxicosis have been investigated by measurement of cardiac-function curves and venous compliance during ganglionic blockade with trimethaphan. Thirteen calves were injected daily with L-thyroxine (200 micrograms/kg) for 12-14 days. Thyroxine treatment increased heart rate (70%), left ventricular systolic pressure (22%), cardiac output (120%), left ventricular maximum rate of pressure development (dP/dt) (56%), and total blood volume (18%) and decreased systemic vascular resistance (39%). ⋯ Unstressed vascular volume was increased from 52.3 +/- 1.1 to 67.1 +/- 0.9 ml/kg. Thus the elevated cardiac output and new cardiac-function curve in thyrotoxicosis are associated with a combination of increased inotropic state, increased blood volume, and decreased venous compliance. These effects are not the result of autonomic influences and may represent direct actions of thyroid hormone on the heart and peripheral venous circulation.
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Comparative Study
Hemodynamic effects of vasopressin compared with angiotensin II in conscious rats.
The mechanisms whereby arginine vasopressin influences hemodynamic and autonomic function were investigated in conscious rats. In normal rats, 60-min intravenous infusions produced dose-related increases of arterial pressure and total peripheral resistance with marked decreases of both heart rate and cardiac output. Cholinergic blockade with methscopolamine attenuated the bradycardia at higher doses of vasopressin, whereby the fall of cardiac output was not affected. beta-Adrenergic blockade with atenolol attenuated the fall of heart rate seen with lower doses of vasopressin but did not prevent the fall of cardiac output. ⋯ Peripheral resistance increased in the normal rats, whereas the related decreases in cardiac output and heart rate were only 30% of the responses seen with equipressor doses of vasopressin. Ganglionic blockade increased pressor activity only two- to eightfold compared with the 60-fold increase observed with vasopressin. We conclude that vasopressin is a more potent vasoconstrictor than angiotensin II, decreases cardiac output independent of neural mechanisms, and results in withdrawal of sympathetic vascular tone to buffer rises of arterial pressure.
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A volume-resuscitated porcine endotoxin shock model was used to evaluate the effect on organ blood flow of increasing systemic arterial blood pressure with vasopressors. Administration of 0.05-0.2 mg/kg of Escherichia coli endotoxin (E) reduced mean arterial blood pressure (MAP) to 50 mmHg, decreased systemic vascular resistance to 50% of control, and did not change cardiac output or heart rate. Blood flow to brain, kidney, spleen, and skeletal muscle was reduced during endotoxin shock, but blood flow to left ventricle, small and large intestine, and stomach remained at pre-endotoxin levels throughout the study period. ⋯ Kidney, splanchnic, and skeletal muscle blood flow did not change with vasopressor administration. The dose of norepinephrine required to increase MAP by 20-25 mmHg during E shock was 30 times the dose required for a similar increase in MAP in animals not receiving E. We conclude that hypotension in the fluid resuscitated porcine E shock model is primarily the result of peripheral vasodilatation, that the vascular response to vasoconstrictors in this model is markedly attenuated following E administration, that blood pressure elevation with norepinephrine, dopamine, and phenylephrine neither decreases blood flow to any organ nor increases blood flow to organs with reduced flow, and that norepinephrine, dopamine, and phenylephrine affect regional blood flow similarly in this model.