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Query: UMLS:C0020538 (
hypertension
)
170,190
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Quinapril is a monoethyl ester which is hydrolysed after absorption to form an active metabolite, quinaprilat, which is a more potent angiotensin converting enzyme (ACE) inhibitor than the parent drug.
Quinaprilat
has a short elimination half-life but a potent binding affinity for ACE which enables once daily administration. Data from clinical studies indicate that quinapril 10 to 40 mg daily, given as a single dose, is an effective antihypertensive agent, suitable as monotherapy for reducing
high blood pressure
and maintaining satisfactory control during long term treatment of mild to severe
hypertension
. Dosages of 80 mg daily have been used in some patients. Concomitant diuretic therapy usually elicits a response in patients who fail to respond adequately to monotherapy. Initial studies suggest that quinapril also has a role in the treatment of mild to severe congestive heart failure. In the few long term studies conducted the beneficial acute haemodynamic effects were maintained during long term treatment and were accompanied by symptomatic and functional improvement. The majority of these patients responded to twice daily administration. Adverse effects associated with the antihypertensive action of quinapril are generally mild, well tolerated and are similar to those of other ACE inhibitors. Thus, quinapril appears to be a useful alternative ACE inhibitor for the treatment of mild to severe
hypertension
and congestive heart failure.
...
PMID:Quinapril. A review of its pharmacological properties, and therapeutic efficacy in cardiovascular disorders. 171 45
Quinapril is an orally active, non-peptide, nonsulfhydryl angiotensin-converting enzyme (ACE) inhibitor that acts potently and specifically to interrupt the conversion of angiotensin I to angiotensin II in both plasma and tissue. Quinapril is enzymatically hydrolyzed to a pharmacologically active diacid form quinaprilat. Quinapril is efficacious in hypertensive models exhibiting both high (renal hypertensive rats, diuretic-treated dogs) and normal (spontaneously hypertensive rats) plasma renin activity. Quinapril does not prevent the development of
hypertension
when plasma renin activity (PRA) is markedly suppressed as in the deoxycorticosterone-saline treated rat. Hemodynamic studies in dogs indicate that quinapril decreases total peripheral and renal vascular resistance.
Quinaprilat
produces natriuresis and mild diuresis at doses that do not alter mean arterial blood pressure. Quinapril has the potential to affect plasma lipids beneficially or at least be "lipid neutral." Oral absorption of quinapril is rapid in rats, dogs, and monkeys. There is rapid and extensive distribution of radiolabel to most tissues except brain. Plasma radiolabel concentration-time profiles exhibit polyexponential decay with a prolonged terminal phase at low concentrations in all species. Metabolism to compounds other than quinaprilat is not extensive. Quinapril is excreted primarily as quinaprilat and to a lesser degree as quinapril. Quinapril is well tolerated in a variety of pharmacologic safety screens and its toxicity profile is similar to that of other ACE inhibitors. Quinapril does not adversely affect reproduction; it is not teratogenic, carcinogenic, or mutagenic.(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Quinapril--a preclinical review of the pharmacology, pharmacokinetics, and toxicology. 253 61
Following systemic absorption, quinapril is converted by de-esterification to quinaprilat (the active diacid metabolite), an inhibitor of angiotensin converting enzyme (ACE). Pharmacodynamic studies in animals indicate inhibition of ACE both in plasma and at tissue sites, such as the arterial wall and heart, following administration of quinapril. Tissue ACE inhibition may be an important component of the mechanism of action of quinapril (and other ACE inhibitors) in achieving favourable effects in cardiovascular disorders.
Quinaprilat
has a short elimination half-life (approximately 2 hours), but binds potently to and dissociates slowly from ACE, thus allowing once or twice daily administration of quinapril in the treatment of patients with
hypertension
or congestive heart failure. Quinapril 10 to 40 mg/day has achieved adequate control of blood pressure in most patients with essential hypertension in clinical trials. Some patients required quinapril dosages up to 80 mg/day and/or concomitant diuretic therapy. Titrating quinapril dosages from 10 to 40 mg/day increased response rates without increasing the incidence or severity of adverse events. Addition of hydrochlorothiazide to quinapril therapy improved response rates by approximately 10 to 20% in patients with
hypertension
. In general, blood pressure control with quinapril monotherapy was similar to that achieved with enalapril or other standard antihypertensive agents in comparative trials. Quinapril < or = 40 mg/day improved exercise tolerance, reduced the severity and frequency of symptoms, and improved functional (New York Heart Association) class in most clinical studies of patients with congestive heart failure. In addition, beneficial haemodynamic and echocardiographic changes achieved with quinapril were maintained for up to 1 year with continued administration to such patients, but its effect on survival in patients with congestive heart failure has not been reported. The tolerability profile of quinapril is broadly similar to that of other ACE inhibitors; pooled data from clinical trials indicated that 12% of patients with
hypertension
or congestive heart failure receiving quinapril experienced a treatment-related adverse effects compared with 15% of enalapril recipients and 16% of captopril recipients. Thus, quinapril has clearly established a role as an effective and well tolerated alternative to other ACE inhibitors for the treatment of
hypertension
and congestive heart failure. While effects of quinapril on survival of patients with congestive heart failure have not been determined, large intervention studies have demonstrated improved mortality rates with other ACE inhibitors. Further studies, including a large ongoing trial of normotensive patients with coronary artery disease but normal left ventricular function, may also establish a role for quinapril in treating patients with ischaemic heart disease.
...
PMID:Quinapril. A reappraisal of its pharmacology and therapeutic efficacy in cardiovascular disorders. 752 26
ACE inhibitors block B(2) receptor desensitization, thereby potentiating bradykinin beyond blocking its hydrolysis. Angiotensin (Ang)-(1-7) also acts as an ACE inhibitor and, in addition, may stimulate bradykinin release via angiotensin II type 2 receptors. In this study we compared the bradykinin-potentiating effects of Ang-(1-7), quinaprilat, and captopril. Porcine coronary arteries, obtained from 32 pigs, were mounted in organ baths, preconstricted with prostaglandin F(2alpha), and exposed to quinaprilat, captopril, Ang-(1-7), and/or bradykinin. Bradykinin induced complete relaxation (pEC(50)=8.11+/-0.07, mean+/-SEM), whereas quinaprilat, captopril, and Ang-(1-7) alone were without effect.
Quinaprilat
shifted the bradykinin curve to the left in a biphasic manner: a 5-fold shift at concentrations that specifically block the C-domain (0.1 to 1 nmol/L) and a 10-fold shift at concentrations that block both domains. Captopril and Ang-(1-7) monophasically shifted the bradykinin curve to the left, by a factor of 10 and 5, respectively. A 5-fold shift was also observed when Ang-(1-7) was combined with 0.1 nmol/L quinaprilat. Repeated exposure of porcine coronary arteries to 0.1 micromol/L bradykinin induced B(2) receptor desensitization. The addition of 10 micromol/L quinaprilat or Ang-(1-7) to the bath, at a time when bradykinin alone was no longer able to induce relaxation, fully restored the relaxant effects of bradykinin. Angiotensin II type 1 or 2 receptor blockade did not affect any of the observed effects of Ang-(1-7). In conclusion, Ang-(1-7), like quinaprilat and captopril, potentiates bradykinin by acting as an ACE inhibitor. Bradykinin potentiation is maximal when both the ACE C- and N-terminal domains are inhibited. The inhibitory effects of Ang-(1-7) are limited to the ACE C-domain, raising the possibility that Ang-(1-7) synergistically increases the blood pressure-lowering effects of N-domain-specific ACE inhibitors.
Hypertension
2001 Jul
PMID:Bradykinin potentiation by angiotensin-(1-7) and ACE inhibitors correlates with ACE C- and N-domain blockade. 1146 67
Somatic angiotensin-converting enzyme (ACE) contains 2 domains (C-domain and N-domain) capable of hydrolyzing angiotensin I (Ang I) and bradykinin. Here we investigated the effect of the selective C-domain and N-domain inhibitors RXPA380 and RXP407 on Ang I-induced vasoconstriction of porcine femoral arteries (PFAs) and bradykinin-induced vasodilation of preconstricted porcine coronary microarteries (PCMAs). Ang I concentration-dependently constricted PFAs. RXPA380, at concentrations >1 mumol/L, shifted the Ang I concentration-response curve (CRC) 10-fold to the right. This was comparable to the maximal shift observed with the ACE inhibitors (ACEi) quinaprilat and captopril. RXP407 did not affect Ang I at concentrations < or =0.1 mmol/L. Bradykinin concentration-dependently relaxed PCMAs. RXPA380 (10 micromol/L) and RXP407 (0.1 mmol/L) potentiated bradykinin, both inducing a leftward shift of the bradykinin CRC that equaled approximately 50% of the maximal shift observed with quinaprilat. Ang I added to blood plasma disappeared with a half life (t(1/2)) of 42+/-3 minutes.
Quinaprilat
increased the t(1/2) approximately 4-fold, indicating that 71+/-6% of Ang I metabolism was attributable to ACE. RXPA380 (10 micromol/L) and RXP407 (0.1 mmol/L) increased the t(1/2) approximately 2-fold, thereby suggesting that both domains contribute to conversion in plasma. In conclusion, tissue Ang I-II conversion depends exclusively on the ACE C-domain, whereas both domains contribute to conversion by soluble ACE and to bradykinin degradation at tissue sites. Because tissue ACE (and not plasma ACE) determines the hypertensive effects of Ang I, these data not only explain why N-domain inhibition does not affect Ang I-induced vasoconstriction in vivo but also why ACEi exert blood pressure-independent effects at low (C-domain-blocking) doses.
Hypertension
2005 Jan
PMID:Selective angiotensin-converting enzyme C-domain inhibition is sufficient to prevent angiotensin I-induced vasoconstriction. 1558 77
