Ischemic heart disease Myocardial infarction

Sethi AA, Tybjaerg-Hansen A, Gron-holdt M-LM, Steffensen R, Schnohr P, Nordestgaard BG. Angiotensinogen mutations and risk for ischemic heart disease, myocardial infarction, and ischemic cerebrovascular disease. Ann Intern Med 2001 134 941-954. 

Angina, arrhythmias, congestive heart failure, ischemic heart disease, myocardial infarction Endocrine and metabolic... 

Decreased cardiac performance. Any number of factors that affect cardiac pumping ability may be responsible for initiating a change in myocardial performance. Factors such as ischemic heart disease, myocardial infarction, valve dysfunction, and hypertension may all compromise the heart s pumping ability.29 53 71 Also, cardiomyopathy may result from other diseases and infections.13... 

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. 

Serious adverse effects of epinephrine potentially occur when it is given in an excessive dose, or too rapidly, for example, as an intravenous bolus or a rapid intravenous infusion. These include ventricular dysrhythmias, angina, myocardial infarction, pulmonary edema, sudden sharp increase in blood pressure, and cerebral hemorrhage. The risk of epinephrine adverse effects is also potentially increased in patients with hypertension or ischemic heart disease, and in those using (3-blockers (due to unopposed epinephrine action on vascular Ui-adrenergic receptors), monoamine oxidase inhibitors, tricyclic antidepressants, or cocaine. Even in these patients, there is no absolute contraindication for the use of epinephrine in the treatment of anaphylaxis [1,5,6]. 

Age >40 yr, previous venous thromboembolism, chronic heart failure, acute respiratory failure, recent major surgery (within 2 wk), confined air/ground travel (>6 h duration within 1 wk of admission), inflammatory bowel disease, myocardial infarction, nephrotic syndrome, and ischemic stroke... 

O Ischemic heart disease results from an imbalance between myocardial oxygen demand and oxygen supply that is most often due to coronary atherosclerosis. Common clinical manifestations of ischemic heart disease include chronic stable angina and the acute coronary syndromes of unstable angina, non-ST-segment elevation myocardial infarction, and ST-segment elevation myocardial infarction. 

To control risk factors and prevent major adverse cardiac events, statin therapy should be considered in all patients with ischemic heart disease, particularly in those with elevated low-density lipoprotein cholesterol. In the absence of contraindications, angiotensin-converting enzyme inhibitors should be considered in ischemic heart disease patients who also have diabetes melli-tus, left ventricular dysfunction, history of myocardial infarction, or any combination of these. Angiotensin receptor blockers... 

Ventricular premature depolarizations occur with variable frequency, depending on underlying comorbid conditions. The prevalence of complex or frequent VPDs is approximately 33% and 12% in men with and without CAD, respectively 34 in women, the prevalence of complex or frequent VPDs is 26% and 12% in those with and without CAD, respectively.35 Ventricular premature depolarizations occur more commonly in patients with ischemic heart disease, a history of myocardial infarction, and HF due to LV dysfunction. They may also occur as a result of hypoxia, anemia, and following cardiac surgery. 

Randomized trials have been completed assessing the role of antiplatelet therapy with aspirin for primary stroke prevention. The use of aspirin in patients with no history of stroke or ischemic heart disease reduced the incidence of non-fatal myocardial infarction (MI) but not of stroke. A meta-analysis of eight trials found that the risk of stroke was slightly increased with aspirin use, especially hemorrhagic stroke. Major bleeding risk was also increased with aspirin use.4 Aspirin is beneficial in the primary prevention of MI, but not for primary stroke prevention. 

Goal BP values are <140/90 for most patients, but <130/80 for patients with diabetes mellitus, significant chronic kidney disease, known coronary artery disease (myocardial infarction [MI], angina), noncoronary atherosclerotic vascular disease (ischemic stroke, transient ischemic attack, peripheral arterial disease [PAD], abdominal aortic aneurysm), or a 10% or greater Framingham 10-year risk of fatal coronary heart disease or nonfatal MI. Patients with LV dysfunction have a BP goal of <120/80 mm Hg. 

They are used for arrhythmias associated with nervous stress, myocardial infarction, and thyrotoxicosis accompanied by elevated adrenergic activity. Moreover, many antiarrhythmic drugs themselves can cause arrhythmia, especially in patients with ischemic heart disease. The examined 8-adrenergic receptor blockers are an exception. Having said that, practically all )3-adrenergic receptor blockers can be used as antiarrhythmics. 

Myocardial ischemia and infarction cause abnorma myocardial metabolism, decreased left ventricular (LV) systolic function, diastolic dysfunction, congestive heart failure, and decreased survival. Consequently, revascularization techniques, either surgical or catheter based, have become integral to treatment of severe ischemic heart disease. 

Conduction system abnormalities are common in chronic heart failure, occurring in 15-30% of the population with low left ventricular ejection fraction (LVEF) [1-3]. The prevalence in ischemic heart disease is roughly similar to that seen in other forms of dilated cardiomyopathy. Conduction system disease can occur both at the time of an acute myocardial infarction as well as slowly progressing in chronic ischemic heart disease. Intraventricular conduction delays are associated with a poor prognosis in heart failure, with up to a 70% increase in the risk of death, and are also more prevalent in patients with advanced symptoms [2,4]. In ischemic heart disease, all components of the conduction system are at risk of ischemic injury, from the sinoatrial node to the His-Pukinje system. These conduction system abnormalities have the potential to impair cardiac function by a number of mechanisms. Since conduction abnormalities impair cardiac function, it is logical that pacing therapies to correct or improve these conduction abnormalities may improve cardiac function. 

The transdifferentiation of HSCs into a mature hematopoietic fate (e.g., endothelium) in the heart is less controversial [148]. In animal models of stem cell therapy in ischemic heart disease, the evidence points toward increased neovascularization (with reduced myocardial ischemia) and consequent improvement in cardiac function [149-151]. Bone marrow stem cells may directly contribute to an increase in contractility or, more likely, may passively limit infarct expansion and remodeling. Unfortunately, the limitations of the present animal models leave this question unanswered. 

Propranolol was the first blocker shown to be effective in hypertension and ischemic heart disease. Propranolol has now been largely replaced by cardioselective blockers such as metoprolol and atenolol. All B-adrenoceptor-blocking agents are useful for lowering blood pressure in mild to moderate hypertension. In severe hypertension, blockers are especially useful in preventing the reflex tachycardia that often results from treatment with direct vasodilators. Beta blockers have been shown to reduce mortality after a myocardial infarction and some also reduce mortality in patients with heart failure they are particularly advantageous for treating hypertension in patients with these conditions (see Chapter 13). 

The most significant toxicity from diazoxide has been excessive hypotension, resulting from the recommendation to use a fixed dose of 300 mg in all patients. Such hypotension has resulted in stroke and myocardial infarction. The reflex sympathetic response can provoke angina, electrocardiographic evidence of ischemia, and cardiac failure in patients with ischemic heart disease, and diazoxide should be avoided in this situation. 

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