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Query: UMLS:C0020538 (hypertension)
 170,190 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

This study confirmed again that high protein diet feeding decreased the incidence of stroke, and high fish protein diet did attenuate severe hypertension but high soybean protein diet did not affect the hypertension. Dietary amino acid analyses indicated that increases in total amino acids, essential amino acids and nonpolar amino acids but not acid or basic amino acids were significantly related to the reduction of stroke incidence. Among essential amino acids, lysine, threonine, isoleucine, and leucine contents were inversely related to stroke incidence, and methionine content was significantly related to the dietary antihypertensive effect of high protein diets. The prophylactic effect of high protein diets may be ascribed to some amino acid constituent.
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PMID:Prophylactic trials for stroke in stroke-prone SHR. (3) Amino acid analysis of various diets and their prophylactic effect. 56 25

Hypertension in spontaneously hypertensive rats (SHR) develops initially without any obvious organic lesions, and mainly with hemodynamic alteration due to increased peripheral vascular resistance. It is then followed later by various cardiovascular complications such as stroke. These facts indicate that this spontaneous hypertension is very similar to essential hypertension in man. Studies on the pathogenic mechanisms of spontaneous hypertension up to the present have revealed the following points. (1) This hypertension is genetically transmitted to the offspring in an additive mode by a relatively small number of major genes; (2) Environmental factors such as stress and salt-loading accelerate the hypertension; (3) Parabiosis between SHR and normotensive rats offered no positive evidence indicating the involvement of any strong humoral factors; (4) Assays on adrenal and thyroid hormones have suggested that this hypertension is not a simple endocrine hypertension; (5) The destruction of the central nervous system or sympathectomy on blood pressure or peripheral vascular resistance, as well as the recording of spontaneous sympathetic discharge, etc. have indicated the positive involvement of the autonomic nervous system in the development of this hypertension; (6) Changes in the enzyme activities of the central nervous system and in the central responses to various candidates of central neurotransmitters suggested that 'noradrenergic inhibitory mechanisms for blood pressure regulation in the brainstem' (Yamori, Lovenberg and Sjoerdsma, 1970) might be insufficient and result in the initial enhancement of peripheral vasomotor tone causing labile hypertension; (7) Noradrenalin turnover study of the heart and hindlimb perfusion experiments indicated that the neural factor was mainly involved in the development or the early stage of hypertension; this finding was further supported by the increased noradrenalin level or dopamine-beta-hydroxylase activity in the blood; (8) Histometrical studies indicated that the structural component of the peripheral vascular resistance stabilized the hypertension; (9) The initial neurogenic factors and successive involvement of nonneurogenic factors are relayed by the acceleration of protein metabolism of the vascular wall ('adaptive metabolic change', Yamori, 1974). This acceleration is commonly detected by amino acid incorporation study in both spontaneous and other experimental hypertension; (10) Increased lysine incorporation into the noncollagenous protein of the mesenteric arteries detected in the prehypertensive SHR was experimentally confirmed to be influenced by neural innervation. This confirmation indicated the importance of such a trophic effect of the nervous system on the structural alteration of blood vessels in the development of hypertension (neurovascular linkage, Yamori, 1975)...
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PMID:Pathogenesis of spontaneous hypertension as a model for essential hypertension. 87 Jul 22

Turnover of noradrenaline (NA) and dopamine (DA) in some regions of the rat brain was determined after 1 and 3 weeks of daily injections of lysine vasopressin (LVP) and 2 weeks after the termination of 28-day LVP injections. Disappearance of 3H-DA was estimated in the hemispheres, brain stem and striatum and of 3H-NA in the hemispheres and brain stem after intraventricular injection of 3H-tyrosine. A significant acceleration of 3H-NA disappearance from the hemispheres was found in all the experimental animals and from the brain stem 3 weeks after LVP adminstration and 2 weeks after its withdrawal. No marked changes in dopamine turnover in the examined regions of the rat brain were found. Since prolonged vasopressin administration produces hypertension in the rat it seems likely that central NA, but not DA, plays a role in the vasopressin-induced hypertension.
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PMID:Turnover of catecholamines in some regions of the rat brain during prolonged vasopressin administration and after its withdrawal. 94 87

Young spontaneously hypertensive rats (SHR) were either treated with hydralazine or hexamethonium or splanchnicotomized, so that the development of hypertension was effectively arrested for two weeks. The rate of incorporation of 3H-lysine into non-collagenous proteins in vivo of the heart, aorta and mesenteric arteries was determined in the treated SHR, as well as control SHR and normal Wistar/Kyoto (WK) rats. The lysine incorporation into the non-collagenous protein of mesenteric arteries was increased in 8-week-old SHR as compared with WK rats. Teh elevated lysine incorporation in the SHR was abolished by treatment with hexamethonium or by splanchnicotomy, but was not affected by treatment with hydralazine. It is suggested that sympathetic innervation is important fot the increased synthesis of vascular non-collagenous protein during the early hypertensive phase in the SHR.
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PMID:Effect of antihypertensive therapy on lysine incorporation into vascular protein of the spontaneously hypertensive rat. 95 48

Cardiac stress produced by hypertension or excess volume loading results in different types of hypertrophy. Elevated left ventricular pressure rapidly results in increased myocardial protein synthesis in vivo and in vitro, but such rapid alterations are not consistently seen in volume loading. The difference in response is difficult to clarify since it is not possible to effect alterations in left ventricular pressure or perfusion without profoundly affecting coronary perfusion. The present study describes cardiac protein synthesis in the right ventricle of the young guinea pig heart in vitro by utilizing a perfusion model in which the right ventricle could be stressed by elevations of pressure or volume loading in the presence of constant and restricted coronary perfusion. With coronary flow maintained at 4 ml/min per heart equivalent to 25 ml/min/g dry wt, an increase in right ventricular pressure from normal levels of 3 mm Hg to 11 mm Hg resulted in a 60 percent increase of myocardial incorporation of (14C)lysine into protein. However, with further increases of right ventricular pressure to 22 mm Hg, protein synthesis dropped back to normal levels. The falloff in protein synthesis was not due to decreased contractility, alterations in intracellular lysine pool specific activity, or alterations in distribution of coronary flow. a 60 percent increase in coronary perfusion was again associated with a similar response of protein synthesis to progressive elevations of pressure despite a rise in the ATP levels and a fall in lactate production. Thus, a deficiency of O2 did not entirely explain the decline of protein synthesis with maximal pressures. At all levels of coronary perfusion, volume loading for 3 h did not result in increased protein incorporation of (14C)lysine. The studies support a relationship between ventricular pressure and protein synthesis unrelated to coronary flow per se. A pressure receptor triggering protein synthesis within the ventricular wall is postulated. Such a relationship is not apparent in short-term volume loading in vitro.
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PMID:The effect of pressure or flow stress on right ventricular protein synthesis in the face of constant and restricted coronary perfusion. 110 73

Keeping in mind the vasodilator action of prostaglandins, the control that they exercise over the vascular supply of kidneys and the sympathetic activity, research was conducted in order to establish the effect of arachidonic acid, the precursor of PGE2, on experimental hypertension in the rat. The experimental hypertension was induced by unilateral nephrectomy, followed by the administration of DOCA and the elevated sodium diet. The treatment was short in one group, long in the other, and both groups were compared to a control hypertensive group which received no treatment at all. Arachidonic acid worsened the experimental hypertension by 37% in the long treatment, and by 25% in the short treatment. The administration of lysine-acetylsalicylate diminished this hypertension. A non-saturated acid, oleic acid, which is not involved in prostaglandin synthesis, has no action. The authors would like to emphasize that in one of the previous experiments, L-tyrosine, the precursor of catecholamines, diminished the experimental hypertension in the rat, and also that L-DOPA and IMAO (MAOI) have comparable effects. It seems, therefore, that the depression of the central catecholaminergic activity, which is supposed to be the action of arachidonic acid via an increase in the PGE2 synthesis, appears to increase hypertension. It is noteworthy that the medial forebrain bundle (MFB) is catecholaminergic and that the periventricular system (PVS) is cholinergic. Thus hypertension may represent the peripheral vascular response to anguish which results from the activation of PVS and from the depression of MFB.
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PMID:The action of arachidonic acid on experimental hypertension in the rat. 112 60

Cardiac stress produced by hypertension or excess volume loading results in different types of hypertrophy. Elevated left ventricular pressure rapidly results in increased myocardial protein synthesis in vivo and in vitro, but such rapid alterations are not consistently seen in volume loading. The difference in response is difficult to clarify since it is not possible to effect alterations in left ventricular pressure or perfusion without profoundly affecting coronary perfusion. The present study describes cardiac protein synthesis in the right ventricle of the young guinea pig heart in vitro utilizing a perfusion model in which the right ventricle could be stressed by elevations of pressure or volume loading in the presence of constant and restricted coronary perfusion. With coronary flow maintained at 25 ml/min/g dry wt, an increase in right ventricular pressure from normal levels of 3 mm Hg to 11 mm Hg resulted in a 60% increase of myocardial incorporation of lysine-14 C into protein. However, with further increases of right ventricular pressure to 22 mm Hg, protein synthesis dropped back to normal levels. The fall-off in protein synthesis was not due to decreased contractility, alterations in intracellular lysine pool specific activity, or alterations in total coronary flow or pressure. A 60% increase in coronary perfusion was associated with a similar response of protein synthesis to progressive elevations of pressure. Since the ATP levels rose and lactate production fell, a deficiency of O2 did not entirely explain the decline of protein synthesis with maximal pressures. At all levels of coronary perfusion, volume loading for 3 hr did not result in increased protein incorporation of lysine-14 C. The studies indicate a relationship between ventricular pressure and protein synthesis unrelated to coronary flow per se and suggest a pressure receptor triggering protein synthesis within the ventricular wall. Such a relationship is not apparent in short term volume loading in vitro.
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PMID:Pressure versus flow stress: the response of cardiac protein synthesis. 121 44

Left ventricular hypertrophy (LVH) is a common condition and a powerful independent risk factor for coronary heart disease, congestive heart failure, and other cardiac morbidity. It is associated with the male sex and advancing age. Its most common cause is hypertension, and many antihypertensive agents induce regression of LVH. Angiotensin-converting enzyme (ACE) inhibitors have been shown to reverse LVH by a mechanism as yet unknown. Reduction in afterload and other hemodynamic abnormalities by reduction of blood pressure is clearly a factor, but ACE inhibitors also block adrenergic action and other sympathetic nervous system influences, and the reduction in angiotensin II produces many effects. By inhibiting this potent vasoconstrictor and suppressing its degradation of the powerful vasodilator bradykinin, and by promoting sodium and water excretion, ACE inhibitors contribute to the restoration of normal ventricular function. Angiotensin II promotes protein synthesis in myocardial myocytes, and blocking this action may arrest the hypertrophic process. To determine the effect of angiotensin II on LVH and normalization of LV function, a study is now underway evaluating the effects of lisinopril, a new lysine analog of enalapril, and a diuretic agent in the treatment of hypertension LVH.
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PMID:ACE inhibitors and regression of left ventricular hypertrophy. 132 1

The minimum degree of renal arterial stenosis needed to cause hypertension was identified by renal arterial angiography of anesthetized dogs. The effects of renal nerves and prostanoids on the critical stenosis were also examined. The left renal artery was constricted concentrically by a radiolucent constrictor device, and the stenosis of the artery was evaluated by cineangiography with the kidney either innervated or denervated. At this time, renal blood flow, renal perfusion pressure, and systemic blood pressure were serially monitored. In another group of dogs, renal venous and aortic blood samples were taken as the stenosis increased; these were assayed for prostaglandin E2 and plasma renin activity. The same experiments were done again after treatment with a cyclooxygenase inhibitor, aspirin DL-lysine (54 mg/kg). With the kidney either innervated or denervated, systemic blood pressure began to increase when the stenosis was more than 70% of the diameter of the renal artery; the renal blood flow decreased when the stenosis was more than 75% of the diameter. Aspirin treatment attenuated the increase in blood pressure but did not affect the autoregulation of the renal blood flow when stenosis was 70% or less. Prostaglandin E2 production increased in the stenotic kidney when the stenosis was more than 70%; aspirin inhibited prostaglandin synthesis and suppressed the stimulation of renin release. These results suggest that whether there is innervation or not, the critical degree of renal arterial stenosis that causes hypertension is more than about 70% of the diameter in the presence of renal prostaglandins; in their absence, the critical point above which hypertension occurs is 75% or more.
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PMID:Critical degree of renal arterial stenosis that causes hypertension in dogs. 147 71

The effects on blood pressure and the development of cardiac hypertrophy of sodium chloride (regular salt) and a novel potassium-, magnesium-, and l-lysine-enriched salt alternative, which in a previous study prolonged the life span of hypertensive rats nearly threefold as compared with the animals receiving regular salt, were compared both in spontaneously hypertensive rats and their hypertension-resistant genetic controls. In particular, the possible protective effect of increased intakes of potassium, magnesium, and l-lysine during a high intake of sodium chloride was examined. Therefore, the salt alternative was added at 1.75 times higher levels to produce the same dietary levels of sodium chloride in the regular salt and the salt alternative groups. Regular salt produced a remarkable left ventricular hypertrophy in both rat strains, but as compared with the respective control groups, it induced an increase of blood pressure only in the spontaneously hypertensive rats. The salt alternative did not induce a rise in blood pressure in either of the rat strains, nor did it produce left ventricular hypertrophy in the hypertension-resistant rats and, in the spontaneously hypertensive animals, significantly less hypertrophy than regular salt. The salt alternative appeared to prevent the sodium chloride-induced volume load since plasma levels of atrial natriuretic peptide were increased in the regular salt groups but remained normal in the salt alternative groups. Therefore, potassium, magnesium, and/or l-lysine of the salt alternative produced a powerful protection against the harmful effects of sodium chloride.
Hypertension 1992 Jun
PMID:Beneficial effects of a potassium- and magnesium-enriched salt alternative. 153 13


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