Infarction

All patients with acute myocardial infarction should be considered for intravenous thrombolytic therapy with streptokinase, tissue plasminogen activator (TPA), or anistreplase because these agents are effective in both preserving cardiac function and reducing mortality. 

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A II H 11 Its 2HC1 salt (Agr307) opposes the formation of extensive infarct lesions 910... 

Other nootropic agents in some stage of clinical development include nebracetam (9), nefinacetam (10), and BMY 21502 (11). Nebracetam, an aminomethyl pyrrolidinone derivative, is expected to be approved in Japan in 1994 (73). In clinical studies involving patients having cerebrovascular or senile dementia of the Alzheimer s type, clinical symptoms such as spontaneous or emotional expression were enhanced in up to 71% of cases. Long-term treatment using nebracetam in patients with cerebral infarction also afforded marked improvement in most cases with few side effects (74). A review of this compound has beenpubUshed (75). 

Fig. 4. Myocardial infarction occurs during insufficient delivery of oxygen to a portion of the heart muscle.

There is a close correlation between myocardial infarctions and tachyarrhythmias, illustrated by the presence of complex ventricular arrhythmias among heart attack victims which are estimated to affect one-third of the survivors each year. Frequendy, the immediate cause of sudden death is ventricular fibrillation, an extreme arrhythmia that is difficult to detect or treat. In the majority of cases, victims have no prior indication of coronary heart disease. 

Technetium-99m tetrafosmin ( Tc-(V)02 (l,2-bis(bis(2-ethoxyethyl)phosphino)ethane) (see Fig. 3d)) is a myocardial perfusion agent. It is used as an adjunct in the diagnosis and localization of myocardial ischemia and/or infarction. 

Another example is the use of Tc-sestamibi, approved for use in the evaluation of coronary artery disease and myocardial infarction, in patients with breast cancer. Use in breast cancer is under investigation by a number of physicians. The data are not yet sufficient to determine the efficacy of this agent in this setting. Its safety, of course, has already been demonstrated as part of its initial evaluation for heart disease. 

There has been a rebirth of interest in a spirin between the 1970s and 1990s as evidence accumulated from a number of clinical trials that aspirin ingestion lowers the incidence of myocardial infarction (39,40), unstable angina (41,42), and stroke (43). 

Cardiac arrhythmias are an important cause of morbidity and mortality approximately 400,000 people per year die from myocardial infarctions (MI) in the United States alone. Individuals with MI exhibit some form of dysrhythmia within 48 h. Post-mortem examinations of MI victims indicate that many die in spite of the fact that the mass of ventricular muscle deprived of its blood supply is often quite small. These data suggest that the cause of death is ventricular fibrillation and that the immediate availability of a safe and efficacious antiarrhythmic agent could have prolonged a number of Hves. The goals of antiarrhythmic therapy are to reduce the incidence of sudden death and to alleviate the symptoms of arrhythmias, such as palpitations and syncope. Several excellent reviews of the mechanisms of arrhythmias and the pharmacology of antiarrhythmic agents have been pubflshed (1,2). 

Glass IB Antiarrhythmic Agents. Class IB antiarrhythmic agents produce less inhibition of the inward sodium current than Class lA agents. In normal myocardial tissue, phase 0 may be unaffected or minimally depressed. However, in ischemic or infarcted tissue, phase 0 is depressed. Myocardial tissue exposed to Class IB agents exhibits decreased automaticity, shortened action potential duration, ie, shortened repolarization, and shortened refractory period. Excitability of the myocardium is not affected and conduction velocity is increased or not modified. The refractory period is shortened less than its action potential duration, thus the ratio of refractory period to action potential duration is increased by these agents. The net effect is increased refractoriness. The PR and QT intervals of the ECG are shortened and the QRS interval is unchanged (1,2). 

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

There have been a number of long-term trials with various P-adrenoceptor blockers in patients surviving acute MI (37—39) that demonstrated a reduction in mortaUty, sudden death, and nonfatal re-infarctions. The term cardioprotective has been used to describe this effect for the dmgs studied. The... 

Nitroglycerin remains the dmg of choice for treatment of angina pectoris. It has also been found useful for the treatment of congestive heart failure, myocardial infarction, peripheral vascular disease, such as Raynaud s disease, and mitral insufficiency, although the benefits of nitroglycerin in mitral insufficiency have been questioned. 

There can be a number of underlying causes of CHE. The most prevalent is the lack of oxygenated blood reaching the heart muscle itself because of coronary artery disease with myocardial infarction (111). Hypertension and valvular disease can contribute to CHE as well, but to a lesser extent in terms of principal causes for the disease. 

Other Cardiovascular Agents Effecting Atherosclerosis. A large amount of clinical data is available concerning semm Upid profiles in patients subjected to dmg therapy for other cardiovascular diseases. Atheroma, for example, may be the underlying cause of hypertension and myocardial infarction. There are on the order of 1.5 million heart attacks pet year in the United States (155). 

It is well accepted that hypertension is a multifactorial disease. Only about 10% of the hypertensive patients have secondary hypertension for which causes, ie, partial coarctation of the renal artery, pheochromacytoma, aldosteronism, hormonal imbalances, etc, are known. The hallmark of hypertension is an abnormally elevated total peripheral resistance. In most patients hypertension produces no serious symptoms particularly in the early phase of the disease. This is why hypertension is called a silent killer. However, prolonged suffering of high arterial blood pressure leads to end organ damage, causing stroke, myocardial infarction, and heart failure, etc. Adequate treatment of hypertension has been proven to decrease the incidence of cardiovascular morbidity and mortaUty and therefore prolong life (176—183). 

A third study (85) enrolled 7825 hypertensive patients (55% males and 45% females) having diastoHc blood pressures (DBP) of 99—104 mm Hg (13—14 Pa) there were no placebo controls. Forty-six percent of the patients were assigned to SC antihypertensive dmg therapy, ie, step 1, chlorthaUdone step 2, reserpine [50-55-5] or methyldopa [555-30-6], and step 3, hydralazine [86-54-4]. Fifty-four percent of the patients were assigned to the usual care (UC) sources in the community. Significant reductions in DBP and in cardiovascular and noncardiovascular deaths were noted in both groups. In the SC group, deaths from ischemic heart disease increased 9%, and deaths from coronary heart disease (CHD) and acute myocardial infarctions were reduced 20 and 46%, respectively. 

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. 

Several clinical trials have been conducted with streptokinase adrninistered either intravenously or by direct infusion into a catheterized coronary artery. The results from 33 randomized trials conducted between 1959 and 1984 have been examined (75), and show a significant decrease in mortaUty rate (15.4%) in enzyme-treated patients vs matched controls (19.2%). These results correlate well with an ItaUan study encompassing 11,806 patients (76), in which the overall reduction in mortaUty was 19% in the streptokinase-treated group, ie, 1.5 million units adrninistered intravenously, compared with placebo-treated controls. The trial also shows that a delay in the initiation of treatment over six hours after the onset of symptoms nullifies any benefit from this type of thrombolytic therapy. Conversely, patients treated within one hour from the onset of symptoms had a remarkable decrease in mortaUty (47%). The benefits of streptokinase therapy, especially in the latter group of patients, was stiU evident in a one-year foUow-up (77). In addition to reducing mortahty rate, there was an improvement in left ventricular function and a reduction in the size of infarction. Thus early treatment with streptokinase is essential. 

In a more extensive international trial, 17,187 patients were treated intravenously with streptokinase alone, aspirin alone, a combination of streptokinase and aspirin, or placebo (78). Streptokinase and aspirin were equally effective in treating acute myocardial infarction, each decreasing mortahty by 25% their combination further reduced mortahty by 42%. A significant reduction in mortahty was seen even in those patients treated up to 24 hours after the onset of symptoms. 

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. 

Second International Study of Infarct Survival (ISIS-2)," Eaneetii, 349 (1988). 

Third International Study of Infarct Survival Collaborative Group (ISIS-3 trial). Lancet 339, 753 (1992). 

The complex investigation of the heart of IHD patients with Myocardial Infarction (MI) was performed. The results obtained showed that all investigated elements divided in two groups - the behavior in different parts of the heart of the certain elements (e.g., Se-Rb) were synergetic, the behaviour of another one was antagonistic (e.g., K-Ca, Fe-Br). 

The increased concentrations of K, Ca, Fe, Br, Se and Rb in infarction and scar areas are observed for patient with the recent infarction. For the patients with old infarction the levels of these elements are decreased in the same areas. This reflects the intensity of metabolic processes in the pathological area of myocardium. Additionally, the elevated levels of Se was find out in myocardium of right ventricle in both patients, that may be caused by the increasing the activity of the glutathione peroxidase enzyme. 

Meticulous care needs to be used in the application of this tissue adhesive. Only a very thin layer of adhesive should be used to assist with reapproximation of the intima and adventitia. It is important to remember that the material should not be allowed to drip into or onto critical areas such as the ostium of the coronary arteries. Inadvertent placement of this agent in such areas can result in blockage of a critical artery and a potentially fatal myocardial infarction. In addition. 

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