Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: EC:3.4.15.1 (ACE)
18,300 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Nitrate tolerance has been explained by 1) a direct loss of pharmacological effect due to reduced bioconversion and 2) an indirect effect due to activation of the renin/angiotensin system and counter-regulatory vasoconstriction. The sulfhydryl compound N-acetylcysteine (NAC) has been shown to attenuate and partly counteract tolerance to nitrates, and this effect has been attributed to a nitrate/sulfhydryl interaction and increased production of vasoactive intermediates. The effect of NAC on counter-regulatory mechanisms is, however, unknown. This study examined whether NAC modulates the function of the renin/angiotensin system in normal rats and in nitrate-tolerant healthy volunteers. Animal study: Conscious rats received NAC (5 mmol/kg/hr i.v., n = 8) or placebo (N-acetylserine, n = 8). Two hours of NAC infusion significantly reduced the pressor effect of angiotensin I (ANG I) by 39 +/- 14% (mean +/- SEM) and reduced angiotensin converting enzyme activity by 31% in plasma (N-acetylserine: 74 +/- 9 nmol/min/mg, NAC: 51 +/- 7) and 43% in kidney (N-acetylserine: 0.9 +/- 0.3, NAC: 0.5 +/- 0.1 nmol/min/mg protein) (P < .05). Clinical study: Isosorbide dinitrate (5 mg/hr) was infused into six male volunteers for 48 hr. NAC (2 g i.v. followed by 5 mg/kg/hr) was co-infused from 24 to 48 hr. Plasma angiotensin II (ANG II) increased during the first 24 hr of isosorbide dinitrate infusion and decreased from 28 +/- 4 to 14 +/- 2 ng/l after 2 hr of NAC infusion (P < .05). The results suggest that sulfhydryl supplementation modifies the function of the renin/angiotensin system in vivo, an effect probably mediated by inhibition of angiotensin converting enzyme activity.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:N-acetylcysteine inhibits angiotensin converting enzyme in vivo. 838 58

The clinical syndrome of congestive heart failure remains a therapeutic dilemma and challenge for the physician in 1992. This is a disease process that appears to be increasing in frequency and continues to carry an unacceptably high mortality rate. For years it has been well recognized that the combination of digoxin, Lasix and vasodilator therapy improved symptoms in these patients and decreased hospitalization, but did not increase survival. It was not until 1986 that the combination of digoxin, Lasix, Isordil, and hydralazine was shown to increase survival. Further significant improvement in quality of life and survival has recently been established in three large clinical trials, and it is now safe to say that the standard of care for symptomatic congestive heart failure in 1992 is digoxin, furosemide, and an ACE inhibitor, with the survival trials favoring the ACE inhibitor enalapril. The IV inotropic drug dobutamine remains the mainstay of pharmacological therapy for the treatment of severely refractory heart failure. Unfortunately, the phosphodiesterase inhibitors--amrinone, milrinone, and enoximone--have demonstrated unacceptable clinical side effects and have been withdrawn from further clinical study. In spite of these promising developments, the mortality and morbidity of congestive heart failure remains unacceptably high, and continued investigation in the new fields of pharmacology and the pathophysiology of congestive heart failure still must be aggressively pursued.
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PMID:Inotropic therapy of the failing myocardium. 841 61

Nitrate tolerance is of significant clinical concern and every effort should be made to avoid this undesirable effect. The mechanism of tolerance is not clear but probably is multifactorial. Although ACE inhibitors, diuretics, and NAC have been tried as preventative measures, the only method proven to maintain nitrate effectiveness in patients is a nitrate-free interval. The results of further studies designed to determine the actual period of time that the patient is protected will be helpful. This may guide us in choosing the optimal nitrate therapy.
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PMID:Nitrate tolerance--mechanisms and prevention. 850 54

Sixty-four diabetic patients suffering an acute myocardial infarct were retrospectively matched, by age, gender and smoking habit, to non-diabetic controls. The two groups were compared for cardiovascular risk factors, pre-admission and discharge drug treatment, in-hospital drug treatment, and complication and mortality rates. Hypertension was more prevalent in the diabetic (63%) than in the control (42%) group. When comparing drugs on admission to those at discharge, there was a significant increase in antiplatelet and nitrate usage in both groups (P < 0.001), in beta-blocker usage in the control group (P < 0.001) and in loop diuretic usage in the diabetic group (P < 0.001). The usage of angiotensin converting enzyme inhibitors was low: 16% of diabetic patients and 5% of controls at discharge. Thrombolytic therapy was used in 29 diabetics and 37 controls. There was a significantly higher complication rate in the diabetic group than in the control group (P < 0.006), the most common being congestive cardiac failure (59% vs 30%, P < 0.001). Four controls and 13 diabetic patients died; three of the latter had their diabetes diagnosed during the admission. This study did not clearly demonstrate any underlying risk factors or treatment variables to account for the increased morbidity or mortality in diabetic patients with acute myocardial infarct, when compared to a matched non-diabetic population. However, modest associations not detected by this relatively small study are still possible.
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PMID:A survey of drug treatment and outcomes in diabetic patients with acute myocardial infarcts. 855 84

Pentachlorophenol (PCP) dechlorination by a methanogenic consortium was observed when glucose, formate, lactate, or yeast extract was present in the mineral medium as a secondary carbon source. Acetate was not a good substrate to sustain dechlorination. The consortium was able to dechlorinate the different monochlorophenols, although the chlorine in position ortho and meta was removed more readily than in para position. Dechlorination was most efficient at 37 degrees C. At 45 degrees C, the first PCP dechlorination steps were very rapid, but 3,5-dichlorophenol (3,5-DCP) was not further dechlorinated. At 15 and 4 degrees C, dechlorination was very slow. The dechlorination of PCP to 3-chlorophenol (3-CP) was still observed after the consortium had been subjected to heat treatment (80 degrees C, 60 min), suggesting that spore-forming bacteria were responsible. The dechlorinating activity of the consortium was significantly reduced by the presence of hydrogen, 2-bromoethanosulfonic acid (BESA), or sulfate but not of nitrate. The dechlorination of 3-CP was completely inhibited by heat treatment or the presence of BESA, suggesting that a syntrophic microorganism would be involved. Vigorous agitation of the consortium stopped the dechlorination, but the presence of DEAE-Sephacel acting as a support was very efficient in restoring the activity, suggesting that association between certain members of the consortium was important.
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PMID:Study of the reductive dechlorination of pentachlorophenol by a methanogenic consortium. 859 Apr 1

The aim of this study was to document changes in drug prescription after myocardial infarction. One hundred and seventy four men with typical myocardial infarction recensed by the Toulouse MONICA centre between 1989 and 1990 were followed up for 4.5 years. A copy of their drug prescription was obtained during the acute phase of infarction, at the time of discharge from hospital or clinic, after 6 months, and finally, after 4.5 years after infarction. During the acute phase, the majority of patients received nitrate derivatives, platelet antiaggregants, calcium antagonists, betablockers and antiarrhythmics. Between hospital discharge and the sixth month, the prescription of lipid lowering drugs quadrupled (from 8 to 33%; p < 0.00001) and those of platelet anti-aggregants decreased (from 82 to 70%; p < 0.01). The prescriptions of other drugs remained relatively stable. Between the 6th month and the 4th year of follow-up the only prescription to increase significantly was that of ACE inhibitors (from 14 to 23%; p < 0.03). The other prescriptions were maintained: platelet anti-aggregants (70% at 6 months vs 75% at 4.5 years), nitrate derivatives (59 vs 51%), betablockers (51 vs 52%), calcium antagonists (51 vs 48%), lipid lowering drugs (33 vs 42%), diuretics (3 vs 6%) and inotropic agents (2 vs 2%). Overall analysis showed an increase in the prescriptions of lipid-lowering agents (p < 0.00001) and ACE inhibitors (p < 0.002). On the other hand, the prescriptions of calcium antagonists and nitrate derivatives tended to decrease. These results show that the treatment of patients with coronary artery disease is based on drugs of proven efficacy, reflecting the impact of large scale therapeutic trials on everyday medical practice.
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PMID:[Long-term effects of prescription drugs in 174 patients treated for myocardial infarction, followed up from 4 to 5 years (the DEVENIR study)]. 867 36

Organic nitrates are widely used in the treatment of ischemic heart disease. The magnitude and duration of their circulatory and ischemic effects are, however, rapidly reduced during continuous treatment. The specific mechanisms underlying this tolerance development are not clear. According to the most widely accepted theory, tolerance is due to an intracellular depletion of thiol compounds (GSH and/or cysteine) involved in the conversion of nitrates to vasoactive intermediates. This presentation deals with aspects of in vivo thiol/nitrate interactions in different experimental and clinical conditions. The major results and conclusions are: The acute hypotensive effect of NTG is decreased by lowering of intracellular GSH levels. This finding emphasizes that normal intracellular thiol levels are required for optimal conversion of nitrates. Thus, intracellular GSH plays a critical role in the metabolism of NTG. Despite development of tolerance to the hypotensive effect of NTG, arterial and venous thiol levels are similar in nitrate tolerant and non-tolerant animals, suggesting that depletion of vascular thiol compounds may not be the cause of nitrate tolerance in vivo. The effect of exogenous thiol administration on intravascular thiol levels are different in nitrate tolerant and non-tolerant conscious rats. Exogenous thiol compounds (e.g. NAC) augments the hypotensive effect of NTG by a tolerance nonspecific mechanism. This effect is most likely mediated by an extracellular and/or membrane-related nitrate/thiol interaction and formation of NO. N-acetylcysteine inhibits angiotensin converting enzyme and counteracts nitrate-induced stimulation of the renin angiotensin system in vivo. Therefore, in addition to an effect on nitrate metabolism, thiol compounds may modify tolerance development by attenuating nitrate-induced counter-regulatory mechanisms. In the clinical setting, co-administration of NAC and ISDN delays and partially prevents tolerance to the antianginal and antiischemic effects normally seen in patients with stable angina pectoris during treatment with ISDN. N-acetylcysteine treatment in humans, potentiates and preserves nitrate induced venodilation and augments the effect of nitrates on small resistance vessels without affecting the response to nitrates in larger sized arteries. Thus, administration of NAC may change the normal vasodilator profile of nitrates. In conclusion, changes in cellular thiol levels may modify the hemodynamic effect of organic nitrates and the cellular handling of thiols and/or thiol related enzymes is altered after development of nitrate tolerance. In addition, a tolerance unrelated thiol/nitrate interaction, potentiating the effect of nitrates, may occur after administration of exogenous thiol compounds. In the clinical setting administration of thiols results in a characteristic change in the vasodilator profile of nitrates and an attenuation of the nitrate-induced stimulation of the renin-angiotensin system. The combination of these effects probably contributes to the improvement in antianginal and antiischemic parameters which may be seen during continuous and prolonged treatment with nitrates and thiol compounds.
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PMID:Thiol compounds and organic nitrates. 874 3

For nitrates their efficacy in acute and chronic heart failure has to be differentiated. In acute heart failure the hemodynamic and symptomatic improvements after administration of short term nitrate therapy render this form of therapy a standard medication. In contrast, the therapy with nitrates in chronic heart failure has not significantly improved prognosis especially when compared with ACE-inhibitors. On the contrary, nitrates in chronic heart failure tend to increase the sympathetic tone which is negatively correlated to survival. Thus, nitrates are only adjunctive therapy in patients with chronic heart failure.
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PMID:[The role of nitrates in therapy of heart failure]. 876 23

1. Angiotensin converting enzyme inhibitors have been suggested to act in part by potentiating the stimulatory effect of bradykinin on endothelial prostacyclin and/or nitric oxide (NO) formation. This may give rise to interaction with cyclo-oxygenase inhibiting drugs like acetylsalicylic acid, which is most often used in low doses in patients with cardiovascular diseases. 2. We investigated the effects of captopril (2 x 25 mg day-1), or ASA (1 x 100 mg day-1), or the combination of both drugs for 7 days, on blood pressure, prostanoid and NO formation rates in a double-blind, double dummy, randomized crossover study in 13 healthy female subjects. The urinary metabolites of thromboxane A2 (2,3-dinor-TXB2) and prostacyclin (2,3-dinor-6-keto-PGF1 alpha), and PGE2 were measured by gas chromatography/tandem mass spectrometry in urine on days 1, 6 and 7 of each medication. NO formation was assessed using urinary NO3- and cyclic GMP as indicators. 3. Urinary 2,3-dinor-6-keto-PGF1 alpha excretion was not significantly changed by either captopril, ASA, or their combination. Urinary 2,3-dinor-TXB2 excretion was inhibited by > 80% by ASA alone or in combination with captopril (each P < 0.05), but was not affected by captopril alone. Urinary PGE2 excretion was not significantly changed by either of the treatments. Urinary NO3- and cyclic GMP excretion rates were not significantly changed by captopril, ASA, or their combination. 4. Blood pressure was slightly reduced by captopril. ASA had no effect on blood pressure when given alone, nor did it modulate the effect of captopril on blood pressure during co-administration. Angiotensin II/angiotensin I ratio (index of ACE activity) was significantly decreased by captopril alone or in combination with ASA, but was unaffected by ASA alone. 5. Captopril does not stimulate prostacyclin formation in healthy human subjects in a dose sufficient to substantially inhibit ACE activity. Co-administration of ASA significantly inhibits 2,3-dinor-TXB2 excretion, but does not interfere with the blood pressure lowering effect of captopril in healthy human subjects.
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PMID:Effect of captopril on prostacyclin and nitric oxide formation in healthy human subjects: interaction with low dose acetylsalicylic acid. 897 27

Vascular tolerance develops rapidly in isolated vascular strips exposed to millimolar concentrations of nitroglycerin. Several mechanisms, including depletion of sulfhydryl groups, reduced biotransformation of nitrates to NO or nitrosothiols, oxygen free radical injury, and downregulation of a membrane-bound enzyme or a nitrate receptor, have been proposed, but the exact mechanism responsible for in-vitro tolerance remains unknown. In-vivo tolerance of the beneficial effects of nitrates on hemodynamics, myocardial ischemia, and exercise performance develops rapidly. It has been suggested, but remains to be proven, that development of venous tolerance and not arterial tolerance is responsible for the attenuation of nitrate effects during long-term nitrate therapy. Several mechanisms, including neurohormonal activation, depletion of sulfhdryl groups, and the shift of fluid from the extravascular to intravascular compartment have been implicated. However, the use of agents to counteract these mechanisms (ACE inhibitors, sulfhydryl donors, diuretics) has produced conflicting results. Thus, at present the mechanism responsible for in vivo tolerance to nitrates remains unknown. Both in vitro and in vivo vascular tolerance to nitrates can be prevented or minimized by providing nitrate-free or low-nitrate intervals. However, during nitrate-free periods, rebound phenomena (rest angina in patients with ischemic heart disease or a deterioration in exercise performance prior to the renewal of the morning dose in patients with stable angina) remain a clinical concern. When treating patients with stable angina pectoris, it must be recognized that none of the nitrate preparations or formulations can provide round-the-clock antianginal or antiischemic prophylaxis. In these patients, beneficial antianginal and antiischemic effects of nitrates for 10-14 hours during the daytime can be maintained by using formulations and dosing regimens that avoid or minimize the development of tolerance (standard formulation of isosorbide-5-mononitrate, 20 mg in the morning and 7 hours later; slow-release formulation of isosorbide-5-mononitrate, 120-240 mg once a day; or nitroglycerin patch delivering 0.6 nitroglycerin per hour for 10-12 hours each day). Only the patch on and off treatment is associated with nitrate rebound. Although intermittent nitrate therapy is not associated with the development of tolerance, this strategy cannot be recommended for treating unstable angina because rebound angina during nitrate-free periods complicates clinical decision making. In the acute phase of unstable angina, continuous treatment with intravenous nitroglycerin is recommended because it permits rapid up- or down-titration. Tolerance towards antianginal and antiischemic effects does develop in a substantial number of patients with 24 hours, but this can be overridden by dose escalation and restoration of the therapeutic effectiveness of nitroglycerin. Tolerance towards the beneficial effects of nitrates on hemodynamics and on exercise performance also develops rapidly during continuous or long-term nitrate therapy, and for these reasons nitrates are not used as first-line therapy to treat chronic heart failure. In combination with hydralazine, high-dose isosorbide dinitrate (30-40 mg four times a day) improves survival, but this combination therapy is inferior to ACE inhibitors.
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PMID:Nitrate tolerance, rebound, and their clinical relevance in stable angina pectoris, unstable angina, and heart failure. 911 Jan 17


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