UMLS:C0020538 - FACTA Search

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

It is shown that following a one-time intravenous administration to rats of ethyron, epinephrine and pituitrin (in doses causing hypertension) the amount of the blood plasma kininogen is more than halved with concurrently increasing caseinolysis. A two-day long introduction of these substances activates prekallicrein and brings down the level of the kallicrein inhibitors, whereas a 10 and 20-day coursewise administration of these compounds intensifies the synthesis of some components in the kallicrein-kinine system.
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PMID:[Influence of hypertensive substances on the kallikrein-kinin system of the blood]. 5 68

To block renin activity, a nonapeptide converting-enzyme inhibitor was given to 65 seated hypertensive patients. Depressor responses occurred only when control plasma renin activity exceeded 2 ng of angiotensin I per milliliter per hour and correlated directly in amplitude with control plasma renin activity and with induced increments in activity (P less than 0.001 for both). Depressor responses, like renin activity, were characteristic for renin subgroups as defined by renin-sodium profiling. Before and after sodium deprivation, the nonapeptide reduced diastolic pressure in all patients with high renin (by 17.3 and 19.8 per cent) and most patients with normal renin (by 9.1 and 17.7 per cent). Low-renin patients remained unresponsive. This enzyme blockade may cause bradykinin accumulation. But if, as seems likely, depressor responses are due to blockade of angiotensin II formation, the results indicate that, irrespective of sodium balance, measurements of plasma renin activity reflect its contribution to blood-pressure maintenance. The results suggest broad participation of the renin system in common forms of hypertension.
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PMID:Possible role of renin in hypertension as suggested by renin-sodium profiling and inhibition of converting enzyme. 19 May 37

A hypothetical model of the active site of angiotensin-converting enzyme, based on known chemical and kinetic properties of the enzyme, has enabled us to design a new class of potent and specific inhibitors. These compounds, carboxyalkanoyl and mercaptoalkanoyl derivatives of proline, inhibit the contractile response of guinea pig ileal strip to angiotensin I and augment its response to bradykinin. When administered orally to rats, these agents inhibit the pressor effect of angiotensin I, augment the vasodepressor effect of bradykinin, and lower blood pressure in a model of renovascular hypertension.
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PMID:Design of specific inhibitors of angiotensin-converting enzyme: new class of orally active antihypertensive agents. 19 8

1. The effects of long-term treatment with the angiotensin I converting-enzyme inhibitor YS 980 were examined in stroke-prone spontaneously hypertensive (sp-SH) rats. Development of hypertension was markedly blunted in the YS 980-treated animals. 2. Effective converting-enzyme inhibition was confirmed by significant increases in plasma angiotensin I (ANG I) and plasma renin concentration, inhibition of the pressor responses to intravenous ANG I and potentiation of the depressor responses to intravenous bradykinin. 3. Urinary free aldosterone excretion was decreased but no changes in urinary sodium and potassium excretion were observed. 4. The pressor responses to intravenous leucine-enkephalin were reduced. 5. The pressor responses to injection of ANG I and bradykinin into the lateral brain ventricle were unaltered. 6. We conclude that the antihypertensive action of YS 980 in sp-SH rats cannot be explained by the inhibition of the plasma renin-angiotensin system alone. Effects on other peptide systems must be considered.
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PMID:A novel orally active converting-enzyme inhibitor YS 980: effects on blood pressure in spontaneously hypertensive rats. 23 20

Captopril inhibits angiotensin II formation and bradykinin degradation in vivo. Eleven patients with essential hypertension (EH) and four patients with renovascular hypertension (RVH) were treated with captopril for periods ranging from 3 days to 12 months. All patients had a diastolic blood pressure (DBP) over 95 mm Hg after receiving a placebo for 3 days. Captopril given in ascending doses (10-1000 mg/day) caused normalization of blood pressure in all but three patients, one with severe RVH whose pressure fell 11%, one patient with severe EH, whose pressure fell 27%, and one with EH whose blood pressure fell 8.5%. The average control DBP in patients with EH was 113.7 +/- 5.5 (SE) mm Hg and fell to 89.9 +/- 3.6 mm Hg (p less than 0.001), while DBP in patients with RVH fell from 110.7 +/- 7.6 mm Hg to 94.5 +/- 8.2 (p less than 0.005). All patients were studied in balance on a 100 mEq sodium (Na) diet. Plasma renin activity (PRA) versus 24-hour urinary Na excretion increased sevenfold during therapy while converting enzyme activity fell by about one half. The magnitude of the blood pressure response was not related to control PRA. Cardiac output was estimated by echocardiography during placebo administration and during maintenance therapy with captopril. A significant change was not observed. Total peripheral resistance fell an average of 18.9% (p less than 0.05) in 11 of the 13 patients in whom the measurement could be made. It is concluded that captopril effectively lowers blood pressure in patients with EH or RHV by reducing total peripheral resistance.
Hypertension
PMID:Hemodynamic and antihypertensive effects of captopril, an orally active angiotensin converting enzyme inhibitor. 23 84

Purified peptidyl dipeptidase (angiotensin I converting enzyme or kininase II) from human lung or hog kidney is inhibited by commercially prepared plasma protein preparations, by human serum albumin and by the additive albumin stabilizer, acetyltryptophan. After the initial steps of purification, albumin was detected by immunodiffusion as a component in human lung peptidyl dipeptidase preparation. Fragment C of albumin (sequence 124-298) is a more potent inhibitor than the parent molecule (Ki = 1.7 X 10(-5)M). Reduction and carboxymethylation of five of the six S-S bridges in Fragment C yield the most potent noncompetitive inhibitor (Ki = 3 X 10(-6)M). Reduction of the sixth bridge raises the K1. This indicates that maintenance of the tertiary structure in Fragment C is of importance for the inhibition. Neither albumin nor Fragment C are substrates of the enzyme. Fragment C and its derivative also inhibit the inactivation of bradykinin by the purified human enzyme and by the peptidyl dipeptidase on the surface of intact cultured human endothelial cells.
Hypertension
PMID:Inhibition of human peptidyl dipeptidase (angiotensin I converting enzyme: kininase II) by human serum albumin and its fragments. 23 85

To determine the relative importance of hormonal factors in mediating the hypotensive response to converting enzyme inhibition (CEI), plasma renin activity (PRA), angiotensin II, and bradykinin responses to SQ20,881 were measured in 20 supine patients with essential hypertension in balance on a 10 mEq sodium diet. Patients were divided into two groups according to their diastolic blood pressure response: responders had a decrement in diastolic pressure which exceeded 9 mm Hg, the upper value of the 95% confidence limits for normotensive patients studied under similar conditions; nonresponders did not. Compared to the nonresponders, responders not only had a higher control PRA (8.7 +/- 1.7 ng/ml/hr vs 4.8 +/- 2.1, p < 0.05) and larger decrement in plasma angiotensin II (18.7 +/- 4.9 pg/ml vs 3.2 +/- 1.7, p < 0.01), but also had a higher control bradykinin (3.2 +/- 0.7 ng/ml vs 1.1 +/- 0.2, p < 0.05) and larger increment in bradykinin (4.5 +/- 1.3 ng/ml vs 1.0 +/- 0.4, p < 0.05) following SQ20,881. Because SQ20,881 altered both angiotensin II and bradykinin concentrations, we assessed the contribution of blockade of angiotensin II formation by administering angiotensin II infusions to seven responders during coverting enzyme blockade, with the angiotensin II dose adjusted to restore diastolic pressure to control levels. The plasma angiotensin II level required to return blood pressure to control was 45 +/- 15 pg/ml higher than the control plasma angiotensin II level (p < 0.01), suggesting that some other factor(s), perhaps bradykinin, are also responsible for the hypotensive response to converting enzyme inhibition.
Hypertension
PMID:Converting enzyme inhibition in essential hypertension: the hypotensive response does not reflect only reduced angiotensin II formation. 23 66

1. Bradykinin (0.02-5 microgram) applied to the epicardium of the left ventricle in the open-chest, anaesthetized dog, elicits dose-related reflex pressor effects and acceleration of the heart rate. 2. Bradykinin-induced reflex tachycardia was suppressed after the blockade of beta-adrenoceptors with propranolol, whereas reflex pressor responses were prevented by blocking the alpha-adrenoceptor sites with phenoxybenzamine. 3. Vagotomy and atropine treatment did not affect reflex hypertension and tachycardia to epicardial bradykinin. 4. After spinal section at C1, the pressor responses to epicardial bradykinin were significantly reduced, but still present in all but one experiment. A small acceleration of the heart occurred in two out of five spinal dogs with intact vagi and was absent in three vagotomized spinal dogs. 5. The results indicate the reflex activation of the sympathetic outflow to the heart and blood vessels, mediated mainly at a supraspinal level as a predominant mechanism for the cardiovascular response initiated by bradykinin-induced stimulation of cardiac pain receptors.
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PMID:Sympathetic cardiovascular reflex initiated by bradykinin-induced stimulation of cardiac pain receptors in the dog. 26 62

The complex hormonal action of angiotensin II in the long-term control of blood pressure or sodium metabolism, or in renal hypertension, is not completely understood. Structure-activity relations with analogues of angiotensin II gave information about the functions responsible for pressor and myotropic response in the molecule that led to the synthesis of competitive antagonists of this hormone. These antagonists, however, show variable agonist/antagonist ratios in different species or different tissues of the same species. This fact necessitates further work to induce tissue specificity. Although des-Asp1-angiotensin II ("angiotensin III") has been recognized as a hormone, its exact role in the biosynthesis of aldosterone is yet to be discovered. The antagonists such as des-Asp1-[Ile8]-angiotensin II or des-Asp1-[Thr8]-angiotensin II have provided important leads in this direction. Many of the biologic effects of angiotensin I have been attributed to its conversion to angiotensin II by the converting enzyme. Recent investigations indicate that angiotensin I itself may play a direct role; however, most of these studies were carried out by inhibiting the converting enzyme activity with peptides obtained from the venom of Bothrops jararaca. Since these peptides also potentiate bradykinin action, the observed biologic activities could be caused by either angiotensin I or bradykinin. Bsides, converting enzyme is no longer thought to be a single enzyme and its nature varies from species to species and from tissue to tissue in the same species. Renin inhibitors related to renin substrate or pepstatin are not freely soluble in plasma and are not effective under physiologic conditions. This points to the importance of renin inhibitors isolated from kidney or other natural sources. Thus, although the renin-angiotensin system appears to be an integral part of the problem of hypertension, characterization of various converting enzymes, roles of extrarenal renin, isorenin, tonin, and brain-renin, and the involvement of other humoral, neurogenic, and immunogenic factors should be pieced together to get a clear picture of the hypertension problem.
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PMID:Pathogenic factors involved in renovascular hypertension. State of the art. 32 61

Plasma kallikrein releases bradykinin when activated by gram-negative septicemia or irreversible hemorrhagic shock. Pancreatitis releases glandular kallikrein causing hypotension and increased vascular permeability. Bradykinin in the brain produces hypertension. Renal kallikrein is released by high arterial pressure, vasodilators, low doses of noradrenaline, angiotensin II, mineralocorticoids and rapid volume expansion. It has a biphasic relation to sodium excretion. In essential hypertension, kallikrein release into the blood and urine is low and facilitates hypertension. High renin in Bartter's syndrome is balanced by high PGE and kallikrein without hypertension.
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PMID:Kallikrein, kininogen and kinins in control of blood pressure. 37 13

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