Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0002962 (angina)
 21,142 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A number of newer antianginal agents, including nicorandil, trimetazidine, and ivabradine, have been synthesized in recent years, but ranolazine, a piperazine derivative that partially inhibits fatty acid oxidation and the late INa current in animal models, is of particular interest mechanistically. Earlier clinical trials with immediate-release ranolazine led to the current sustained-release version tested in the Monotherapy Assessment of Ranolazine In Stable Angina (MARISA) (n = 193) and Combination Assessment of Ranolazine In Stable Angina (CARISA) trials (n = 823) of patients with chronic angina and severe limitation of exercise capacity (ie, < 5 metabolic equivalents). MARISA was a placebo-controlled, randomized trial that compared ranolazine monotherapy (500 mg, 1000 mg, and 1500 mg, twice daily) to placebo. CARISA was a placebo-controlled trial that randomized patients on background beta-blocker or calcium antagonist therapy to placebo or ranolazine (750 mg or 1000 mg, twice daily). Both studies showed a significant increase in total exercise duration, time to angina onset, and time to 1 mm ST segment depression. The average magnitude of increase in exercise duration over placebo was 29 to 56 seconds at peak and 24 to 46 seconds at trough with the 3 doses tested in MARISA, and 24 to 34 seconds greater than placebo with the 2 doses used in CARISA. The beneficial effect was achieved without clinically important changes in rest or exercise heart rate or blood pressure. Weekly angina attack frequency and nitroglycerin usage were significantly reduced in a dose-dependent manner in the 12-week CARISA trial. Reported adverse effects were similar in MARISA and CARISA and consisted of asthenia, nausea, constipation, and dizziness. Syncope, reported in 8 patients at doses of 1000 mg twice daily or more may be related to attenuation of alpha-1 receptor activity. The mean QTc interval increased with dose and was less than 10 msec on ranolazine at 1000 mg twice daily. The mortality rates at 1 and 2 years in MARISA and CARISA open-label run-on studies were 2% and less than 5%, acceptable for this high-risk population with limited exercise capacity. In conclusion, clinical trial evidence with ranolazine to date is consistent with its proposed mechanism of action and demonstrates an effective antianginal profile that may benefit patients with severe chronic angina.
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PMID:Efficacy and safety of a metabolic modulator drug in chronic stable angina: review of evidence from clinical trials. 1537 31

The sodium current in the heart is not a single current with a mono-exponential decay but rather a mixture of currents with different kinetics. It is not clear whether these arise from distinct populations of channels, or from modulation of a single population. A very slowly inactivating component, [(INa(P))] I(Na(P)) is usually about 1% of the size of the peak transient current [I(Na(T))], but is enhanced by hypoxia. It contributes to Na(+) loading and cellular damage in ischaemia and re-perfusion, and perhaps to ischaemic arrhythmias. Class I antiarrhythmic agents such as flecainide, lidocaine and mexiletine generally block I(NA(P)) more potently than block of I(Na(T)) and have been used clinically to treat LQT3 syndrome, which arises because mutations in SCN5A produce defective inactivation of the cardiac sodium channel. The same approach may be useful in some pathological situations, such as ischaemic arrhythmias or diastolic dysfunction, and newer agents are being developed with this goal. For example, ranolazine blocks I(Na(P)) about 10 times more potently than I(Na(T)) and has shown promise in the treatment of angina. Alternatively, the combination of I(Na(P)) block with K(+) channel block may provide protection from the induction of Torsades de Pointe when these agents are used to treat atrial arrhythmias (eg Vernakalant). In all of these scenarios, an understanding of the role of I(Na(P)) in cardiac pathophysiology, the mechanisms by which it may affect cardiac electrophysiology and the potential side effects of blocking I(Na(P)) in the heart and elsewhere will become increasingly important.
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PMID:The cardiac persistent sodium current: an appealing therapeutic target? 1807 2

Ranolazine is a piperazine derivative believed to reduce anginal symptoms by preventing ischemia-mediated sodium and calcium overload in myocardial cells through inhibition of the late sodium current (late INa). Three small studies demonstrated the antianginal efficacy of ranolazine alone and in combination with betablockers or calcium channel blockers on conventional end points such as total exercise duration and time to ischemia/angina on a treadmill; however, questions of safety related to QT prolongation, efficacy in women and potential utility in higher risk populations remained. Metabolic Efficiency with Ranolazine for Less Ischemia in Non-ST Elevation Acute Coronary Syndromes-Thrombolysis in Myocardial Infarction (MERLIN-TIMI) 36 was a large randomized, double-blind, placebo-controlled trial, which evaluated the efficacy and safety of ranolazine initiated acutely and continued as chronic therapy following a non-ST-segment elevation acute coronary syndrome event. A total of 6560 patients were randomized 1:1 to ranolazine or placebo; the primary efficacy end point of the trial was a composite of cardiovascular death, myocardial infarction or recurrent ischemia. The key safety end points were death from any cause and symptomatic documented arrhythmia. Although statistically significant differences between the ranolazine and placebo groups were not reached in the primary efficacy analysis or in the major secondary outcome end point analyses (cardiovascular death, myocardial infarction or severe recurrent ischemia), the individual component of recurrent ischemia was significantly reduced by ranolazine, and ranolazine was demonstrated to be safe.
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PMID:Metabolic efficiency with ranolazine for less ischemia in non-ST elevation acute coronary syndromes (MERLIN TIMI-36) study. 1809 3

Inhibition of the persistent or late Na current (INa) using ranolazine (Ranexa) represents a novel mechanism of action that was approved in the United States in 2006 and only recently in the European Union for use in patients with stable angina pectoris. In general, myocardial ischemia is associated with reduced adenosine triphosphate fluxes and decreased energy supply, resulting in severe disturbances of intracellular ion homeostasis in cardiac myocytes. In the recent years, increased late INa was suggested to contribute to this phenomenon by elevating intracellular Na concentration with subsequent rise in diastolic Ca levels by means of the sarcolemmal Na-Ca exchange system. Ranolazine, a specific inhibitor of late INa, reduces Na influx and hence ameliorates disturbed Na and Ca homeostasis. This is associated with a symptomatic improvement of angina in patients unlike other antianginal drugs without affecting heart rate or systemic blood pressure as shown in placebo-controlled studies. Therefore, ranolazine is a useful new option for patients with chronic stable angina not only as an add-on therapy. New clinical and experimental studies even point to potential antiarrhythmic effects, beneficial effects in diastolic heart failure, and under hyperglycemic conditions. In the present article, the relevant pathophysiological concepts for the role of late INa inhibition are reviewed and the most recent data from basic studies and clinical trials are summarized.
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PMID:A novel mechanism for the treatment of angina, arrhythmias, and diastolic dysfunction: inhibition of late I(Na) using ranolazine. 1933 33

The sodium current (INa) plays a pivotal role in the propagation of electrical activity in the heart. However, a large body of evidence indicates that the "late" component of INa (INaL) may be enhanced in diseased myocardium. INaL enhancement has consequences on the electrical stability, contractile function and metabolism of cardiac myocytes, which may significantly contribute to disease progression. The possibility of blocking INaL selectively, that is to say without affecting the INa component involved in electrical propagation, has recently emerged. INaL has hence become a "therapeutic target", thus far clinically validated in the treatment of angina and arrhythmias but, as suggested by bench evidence, potentially relevant to a wider range of cardiac disorders. Such multiplicity of effects originates from the complex network of cell functions affected by INaL enhancement; acquaintance with such a network is useful in fully exploiting the therapeutic potential of selective INaL inhibition. This review deals with the pathophysiology of INaL enhancement and with the basic principles underlying its selective inhibition. Clinical evidence of antianginal and antiarrhythmic efficacy of INaL inhibition is available, but its discussion goes beyond the scope of this review.
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PMID:[The late sodium current: pathophysiology and pharmacology of a new therapeutic target]. 2194 34

Ranolazine, an inhibitor of the late current of the cardiac action potential (late I(Na)), is a well established clinical treatment for chronic angina. The late INa in cardiac myocytes also plays an important role in the pathophysiology of acute myocardial ischemia and reperfusion, and thus is a potential therapeutic target to ameliorate consequences of myocardial infarction. In experimental animal models, ranolazine has been shown to reduce myocardial infarct size, improve left ventricular function, decrease ischemia/reperfusion-induced arrhythmias and improve outcome in heart failure. Here we focus specifically on data from in vivo animal studies of myocardial ischemia and reperfusion.
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PMID:Ranolazine treatment for myocardial infarction? Effects on the development of necrosis, left ventricular function and arrhythmias in experimental models. 2511 50

Ranolazine is currently approved as an antianginal agent in patients with chronic angina (class IIA). Ranolazine exhibits antiarrhythmic effects that are related to its multichannel blocking effect, predominantly inhibition of late sodium (late INa) current and the rapid potassium rectifier current (IKr), as well as ICa, late ICa, and INa-Ca. It also suppresses the early and delayed after depolarizations. Ranolazine is effective in the suppression of atrial and ventricular arrhythmias (off-label use) without significant proarrhythmic effect. Currently, ongoing trials are evaluating the efficacy and safety of ranolazine in patients with cardiac arrhythmias; preliminary results suggest that ranolazine, when used alone or in combination with dronedarone, is safe and effective in reducing atrial fibrillation. Ranolazine is not currently approved by the US Food and Drug Administration as an antiarrhythmic agent.
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PMID:Ranolazine: Electrophysiologic Effect, Efficacy, and Safety in Patients with Cardiac Arrhythmias. 2726 35