Myocardial infarction acute, treatment

Alteplase was the first commercially available recombinant tissue-type plasminogen activator (rt-PA) (25), It has a plasma half-life of less than five minutes and is metabolized by the liver, This agent was initially hailed as fibrin-specific unlike its precursors (urokinase and streptokinase). It was thought that this would result in a better safety profile, but this has not been born out in either the coronary or the peripheral experience, where actually there may be a higher bleeding risk as infusion time increases. Alteplase is currently indicated for use in the treatment of myocardial infarction, acute ischemic stroke, and pulmonary embolism. 

Abciximab Prevention ot ischemic cardiac complications during percutaneous coronary interventions short-term prevention ot myocardial infarction Atelimomab Treatment ot sepsis Alemtuzumab Chronic lymphocytic leukemia Apolizumab Chronic lymphocytic leukemia Basiliximab Prevention ot acute renal allograft rejection Clenoliximab Rheumatoid arthritis Daclizumab Prevention ot acute renal allograft rejection Edrecolomab Adjuvant therapy tor cancer after colorectal surgery... 

Sasaki M, Suzuki A, Ishihara T. [A case of acute myocardial infarction after treatment with cisplatin.] Gan To Kagaku Ryoho 1989 16(6) 2289-91. 

The dmg is effective in the treatment of ventricular arrhythmias, especially those following acute myocardial infarctions (1,2,22). 

Thrombolytic Enzymes. Although atherosclerosis and the accompanying vascular wall defects are ultimately responsible for such diseases as acute pulmonary embolism, arterial occlusion, and myocardial infarction, the lack of blood flow caused by a fibrin clot directly results in tissue injury and in the clinical symptoms of these devastating diseases (54). Thrombolytic enzyme therapy removes the fibrin clot by dissolution, and has shown promise in the treatment of a number of thrombo-occlusive diseases (60). 

Indications for treatment with streptokinase include acute occlusion of arteries, deep vein thrombosis, and pulmonary embolism. Streptokinase therapy in coronary thrombosis, which is the usual cause of myocardial infarction (54,71,72), has proved to be valuable. In this frequently fatal condition, the enzyme is adrninistered intravenously at a dose of 1.5 million units over 60 min, or given by intracoronary infusion at a 20,000- to 50,000-unit bolus dose followed by 2000 to 4000 units/min for 60 min therapy must be instituted as soon as practicable after the diagnosis of heart attack is made. For deep vein thrombosis, pulmonary embolism, or arterial occlusion, streptokinase is infused at a loading dose of 250,000 units given over 30 min, followed by a maintenance dose of 100,000 units over a 60-min period. 

Compared to streptokinase, urokinase has been less extensively studied because of its high cost, ie, about 10 times that of a comparable treatment with streptokinase. In addition to the indications described for streptokinase, urokinase is indicated for use in patients with prior streptokinase treatment, or prior Streptococcal infection. Urokinase is commonly used at a loading dose of 4400 units /kg, with a maintenance intravenous infusion dose of 4400 units/kg/h for thromboses other than acute myocardial infarction. In the latter case, a much larger dose, ie, 0.5—2.0 million units/h or a bolus dose of 1.0 million units followed by a 60-min infusion with 1.0 million units, has been found optimal (106). An intracoronary dose of 2000 units/min for two hours was used in one comparative study with intracoronary streptokinase (107). In this study, urokinase exhibited efficacy equivalent to streptokinase with fewer side effects. Other studies with intracoronary urokinase have adrninistered doses ranging from 2,000 to 24,000 units/min with a reperfusion efficacy of 60—89% (108—112). In another urokinase trial, 2.0 million units were adrninistered intravenously, resulting in a thrombolytic efficacy of 60% (113). Effectiveness in terms of reduction in mortaUty rate has not been deterrnined because of the small number of patients studied. 

Fondaparinux, the factor Xa-binding pentasaccharide (Arixtra, MW 1,728 Da), is prepared synthetically, unlike UFH, LMWH and danaparoid, which are obtained from animal sources. Despite only inactivating free factor Xa, clinical trials indicate that fondaparinux is an effective antithrombotic agent, both for venous thromboembolism prophylaxis and treatment, as well as for acute coronary syndrome and ST elevation myocardial infarction [4]. 

In rodent stroke models, statin pretreatment has been shown to reduce infarct volumes and improve outcomes. Similarly, several clinical studies have shown that prior statin use reduced the severity of acute ischemic stroke and myocardial infarction. Recent studies indicate that beneftt can be achieved even when treatment is initiated after the onset of symptoms. In rodents, atorvastatin and simvastatin have been shown to reduce the growth of ischemic lesions, enhance functional outcome, and induce brain plasticity when administered after stroke onset. A retrospective analysis of the population-based Northern Manhattan Stroke Study (NOMASS) showed that patients using lipid-lowering agents at the time of ischemic stroke have a lower incidence of in-hospital stroke progression and reduced 90-day mortality rates. Retrospective analysis of data of the phase III citicoline trial showed... 

Ticlopidine inhibits the P2Yj2 platelet ADP receptor, thus inhibiting ADP-dependent activation of the GP Ilb/IIIa receptor. It has a slow onset of action and takes 3-7 days to reach its maximal antiplatelet effect. It is inactive in vitro and must undergo activation by the hepatic cytochrome p450 enzyme system. Secondary prevention trials have found that ticlopidine-treated patients have an estimated RRR of 33% for the composite endpoint of stroke, myocardial infarction, or vascular death after ischemic stroke. Significant adverse effects include bone marrow depression, rash, diarrhea, and thrombotic thrombocytopenic purpura. No clinical trials have studied ticlopidine for the treatment of stroke in the acute phase. 

In stroke patients presenting to the ED, the first goal of treatment is immediate cardiac and respiratory stabilization. The systemic blood pressure is most often elevated in the setting of an acute stroke as the result of a catecholamine surge, and if the patient is hypotensive, the clinician should consider a concomitant cardiac process, such as myocardial infarction (MI), congestive heart failure (CHF), or pulmonary embolism (PE). 

Retevase Reteplase Boehringer Man Centocor Treatment of acute myocardial infarction... 

Alteplase has proven effective in the early treatment of patients with acute myocardial infarction (i.e. those treated within 12 h after the first symptoms occur). Significantly increased rates of patient survival (as measured 1 day and 30 days after the initial event) are noted when tPA is administered in favour of streptokinase, a standard therapy (see later). tPA has thus established itself as a first-line option in the management of acute myocardial infarction. A therapeutic dose of 90-100 mg (often administered by infusion over 90 min) results in a steady-state alteplase concentration of 3-4 mg l 1 during that period. However, the product is cleared rapidly by the liver, displaying a serum half-life of approximately 3 min. As is the case for most thrombolytic agents, the most significant risk associated with tPA administration is the possible induction of severe haemorrhage. 

Rabasseda, X. 2001. Tenecteplase (TNK tissue plasminogen activator) a new fibrinolytic for the acute treatment of myocardial infarction. Drugs of Today 37(11), 749-760. 

Another theory is that the inhibition of fibrinolysis is due to the interaction of Lp(a) with tPA bound to fibrin, and thereby influencing plasminogen activation (L10, R17, R18). Von Hodenberg (H32), however did not find a relationship between Lp(a) level and treatment success of thrombolysis in acute myocardial infarction with recombinant tPA. 

Ivabradine is used in the treatment of angina in patients in normal sinus rhythm. It acts on the sinus node resulting in a reduction of the heart rate. It is contraindicated in severe bradycardia (heart rate lower than 60 beats/ minute), cardiogenic shock, acute myocardial infarction, moderate-to-severe heart failure, immediately after a cerebrovascular accident, second and third-degree heart block and patients with unstable angina or a pacemaker. Side-effects include bradycardia, first-degree heart block, ventricular extrasystoles, headache, dizziness and visual disturbances, including blurred vision. 

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