EC:3.4.23.15 - FACTA Search

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Query: EC:3.4.23.15 (renin)
35,795 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Malignant hypertension with severe hyponatraemia, hypokalaemia, depletion of sodium and potassium, and elevated blood levels of renin, angiotensin I, angiotensin II, aldosterone, and arginine vasopressin developed in a woman with renal-artery occlusion. Plasma angiotensin II was disproportionately high in relation to exchangeable sodium. Captopril, by inhibiting conversion of angiotensin I to angiotensin II, further elevated the blood levels of renin and angiotensin I but corrected all other abnormalities. Unilateral nephrectomy was subsequently curative.
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PMID:Hyponatraemic hypertensive syndrome with renal-artery occlusion corrected by captopril. 9 Feb 71

Release of arginine vasopressin (AVP) from rat neurohypophysis in in vitro studies is significantly augmented by the addition of angiotensin (A-II), and in in vivo studies in dogs renin and A-II were found to stimulate secretion of AVP. Both these results suggest the existence of a direct relationship between the salt regulating renin-angiotensin-aldosterone system and the water controlling AVP system. To evaluate whether such observations apply also in man a sensitive double antibody radioimmunoassay for AVP was developed [17, 18]. Basal plasma levels of AVP in recumbent humans without salt and fluid restriction at room temperature were 3.4 plus or minus 2.2 pg/ml, and 30 min after the onset of an A-II infusion at a concentration of 3-30 ng/min-kg, a significant increase of AVP was found. Maximum measurements were 2-5 times basal levels which returned to normal within 90 min. During the A-II infusion one also noted a 20 mm Hg rise in blood pressure, accompanied by a significant decrease in plasma renin activity. During the same period serum osmolality and serum sodium concentration did not change. Elevation of blood pressure by norepinephrine was not followed by any detectable change of plasma AVP levels, thus excluding a nonspecific blood pressure effect.
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PMID:Angiotensin stimulated AVP-release in humans. 23 67

1. The role of vasopressin in blood pressure control and in the pathogenesis of one-kidney Goldblatt hypertension in the conscious dog was investigated. 2. Infusion of synthetic arginine vasopressin to elevate plasma levels approximately five-fold caused bradycardia in normal dogs and increase in mean arterial blood pressure in dogs with pharmacological autonomic blockade. 3. A similar degree of elevation of plasma vasopressin concentration was observed after mild non-hypotensive haemorrhage. 4. Renal artery constriction in unilaterally-nephrectomized dogs caused a rise in plasma renin activity and only a doubling of plasma vasopressin concentration, but a marked rise in mean arterial blood pressure. 5. Vasopressin may play a role in normal cardiovascular homeostatic responses, but its role in the pathogenesis of this form of hypertension is unlikely to be significant.
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PMID:The role of vasopressin in blood pressure control and in experimental hypertension. 28 63

Water balance is tightly regulated within a tolerance of less than 1 percent by a physiologic control system located in the hypothalamus. Body water homeostasis is achieved by balancing renal and nonrenal water losses with appropriate water intake. The major stimulus to thirst is increased osmolality of body fluids as perceived by osmoreceptors in the anteroventral hypothalamus. Hypovolemia also has an important effect on thirst which is mediated by arterial baroreceptors and by the renin-angiotensin system. Renal water loss is determined by the circulating level of the antidiuretic hormone, arginine vasopressin (AVP). AVP is synthesized in specialized neurosecretory cells located in the supraoptic and paraventricular nuclei in the hypothalamus and is transported in neurosecretory granules down elongated axons to the posterior pituitary. Depolarization of the neurosecretory neurons results in the exocytosis of the granules and the release of AVP and its carrier protein (neurophysin) into the circulation. AVP is secreted in response to a wide variety of stimuli. Change in body fluid osmolality is the most potent factor affecting AVP secretion, but hypovolemia, the renin-angiotensin system, hypoxia, hypercapnia, hyperthermia and pain also have important effects. Many drugs have been shown to stimulate the release of AVP as well. Small changes in plasma AVP concentration of from 0.5 to 4 muU per ml have major effects on urine osmolality and renal water handling.
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PMID:The clinical physiology of water metabolism. Part I: The physiologic regulation of arginine vasopressin secretion and thirst. 39 80

Uninephrectomized adult female dogs with chronic indwelling catheters were maintained on a low sodium diet and studied without anesthesia. Following hydration with 3% dextrose, an intravenous infusion of either arginine vasopressin (AVP) or of 1-desamino-8-D-arginine vasopressin (DDAVP) was begun. The dose was calculated to achieve a near maximal physiological plasma concentration of AVP, or an equimolar concentration of DDAVP. Both AVP and DDAVP increased urinary osmolality from less than 60 to over 800 mosmol/kg H2O within 1 h. AVP infusion increased mean arterial pressure and renal electrolyte excretion and decreased heart rate and plasma renin activity (PRA), while DDAVP was without effect on these parameters. AVP infused into the renal artery at doses which did not alter systemic pressure and heart rate caused kaliuresis and reduced PRA. We conclude that the AVP-induced inhibition of renin secretion and increase in renal electrolyte excretion are not secondary to increased tubular permeability to water, but must represent a more specific action of AVP which is not shared by DDAVP.
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PMID:Effects of AVP and DDAVP on plasma renin activity and electrolyte excretion in conscious dogs. 43 55

The effect of ethanol intoxication and hangover on plasma renin activity (PRA), plasma aldosterone (PA) and plasma cortisol (PC) concentrations was studied in 7 healthy supine men in controlled clinical conditions during 18 h beginning at 6 p.m. Large individual variation was observed in the response of PRA, PA and PC to ethanol. Following ethanol, stimulation of PRA was observed at the 14th and the 16th hour (P less than 0.05), of PA at the 4th and the 6th hour (P less than 0.01 and P less than 0.05, respectively) and of PC at the 4th and the 14th hour (P less than 0.01 and P less than 0.05, respectively). Ethanol ingestion suppressed PC during the first hour (P less than 0.02). Water ingestion at 8 a.m. suppressed PA between the 14th and the 16th hour (8-10 a.m.) in control and ethanol experiment (P less than 0.01 and P less than 0.005, respectively). There was a dissociation between PRA and PA, but intra-individually PRA and PA correlated fairly or well. Plasma arginine vasopressin (AVP) and PC were also significantly correlated. The results suggest that changes in PA and PC as well as the dissociation of PRA and PA after ethanol ingestion might be partly related to dehydration and to the increased secretion of hypothalamic and pituitary hormones as well as to sodium and potassium balance. There was a biphasic effect of ethanol, including an inital suppression of PC and a subsequent increase of PC, PRA and PA. Upright posture appears to exaggerate the stimulating effect of ethanol on PRA, PA and PC.
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PMID:Renin, aldosterone and cortisol during ethanol intoxication and hangover. 46 81

Physiological levels of arginine vasopressin (AVP) were continuously infused 24 h/day into six dogs for periods ranging from 7 to 34 days. The acute and chronic responses of the mean arterial pressure (MAP), body fluid volumes, renal function indices, plasma electrolyte concentrations, plasma renin activity, and urinary electrolyte and water excretion rates were measured. MAP was unaffected acutely but rose significantly to a peak on day 9 before declining toward control. MAP was significantly and positively correlated with the plasma volume, but had a diphasic correlation with the plasma sodium concentration and the change in total body sodium. The plasma sodium concentration reached a relatively stable plateau that was maintained in spite of large changes in total body water. We conclude that AVP produces only a transient hypervolemic hypertension; that AVP is a natriuretic agent, either directly or indirectly, both acutely and chronically; and that chronically it is a more potent controller of the plasma sodium concentration than of the total body water except in extreme cases.
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PMID:Acute and chronic effects of vasopressin on blood pressure, electrolytes, and fluid volumes. 47 64

A 33-year-old man is described with hyperkalaemia, hypertension and acidosis. The blood pressure was 160 to 200 mmHg systolic and 90 to 110 mmHg diastolic and the plasma potassium was between 6.0 and 7.0 mmole per litre. There was no renal disease and creatinine clearance was 103 ml per minute. Plasma renin activity was low and plasma aldosterone was at the lower limit of normal. Sodium deprivation or oral frusemide had little effect on blood pressure, plasma potassium, renin, aldosterone or arginine vasopressin. However, bendrofluazide caused a rapid fall of blood pressure and plasma potassium, and rise of plasma renin, aldosterone and plasma arginine vasopressin. Hypertension and hyperkalaemia is rare in the absence of renal failure. Four similar patients reported previously are reviewed. We suggest that our patient, and perhaps some of those reported earlier had primary abnormality of renal tubular function with impaired secretion of potassium and excessive tubular reabsorption of sodium. The plasma renin activity could be due to volume expansion and the low plasma aldosterone was probably caused by the antagonistic effects of low renin depressing synthesis and hyperkalaemia increasing it. A minor similar tubular abnormality might be the explanation in some of the patients with essential hypertension who have low plasma renin activity.
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PMID:Hypertension and hyperkalaemia responding to bendrofluazide. 50 50

Male Sprague-Dawley rats with unilateral renal artery stenosis and a contralateral untouched kidney develop a malignant hypertension (MH) which is characterized by high blood pressures, sodium and water depletion, and subsequent activation of the renin-angiotensin system. In the present studies we found plasma arginine vasopressin (AVP) concentrations-3-fold higher than those in rats with benign renal hypertension, and 4- to 5-fold higher than those in normotensive control rats. Analysis of individual values showed considerable scatter; about 50% of the values fell in the range of benign hypertensive or control rats. When a specific AVP antiserum was injected, iv, into eight conscious unrestrained MH rats, BP transiently fell toward control values in four; in one, BP fell by only 10 mm Hg, and three other MH rats showed no response. In the same rats, injection of a specific angiotensin II antiserum always induced a transient fall in BP. On the basis of these and previously reported observations, we conclude that, subsequent to sodium and water loss and activation of the renin-angiotensin system, vasopressin release is stimulated in a significant number of MH rats and that, in these rats, vasopressin may cause significant systemic vasoconstriction. Thereby vasopressin may contribute to the development of malignant renal hypertension in rats.
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PMID:Plasma vasopressin concentrations and effects of vasopressin antiserum on blood pressure in rats with malignant two-kidney Goldblatt hypertension. 61 98

Normal Long-Evans rats (LE) exhibited diurnal variations of plasma arginine vasopressin (AVP) concentrations with peak values at 10 A.M. and minimum values at 1 P.M. Brattleboro rats heterozygous for hypothalamic diabetes insipidus (DI) had significantly reduced plasma AVP concentrations and increased plasma osmolalities when compared with LE rats. By prolonged injection of 100 mU/day of vasopressin tannate (VPT) into Brattleboro rats homozygous for DI, plasma AVP concentrations close to those of LE rats were achieved. Potassium was retained for 7 days until escape of vasopressin-induced potassium retention occurred. When 500 mU VPT were injected into DI rats, high plasma AVP levels were induced. Potassium was retained for 2-3 days. After initial sodium retention, periods of natriuresis occurred. During treatment with 100 mU VPT/day most of the alterations present in DI rats were corrected, which included increased water turnover and external water loss, increased hematocrit and plasma sodium concentrations (but not increased plasma osmolalities), hypokalemia, increased activity of the renin-angiotensin system, and reduced adrenocortical function.
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PMID:Effects of prolonged vasopressin treatment in Brattleboro rats with diabetes insipidus. 62 99

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