Harrison's Principle of Internal Medicine 17th Ed.2008
Introduction
Definition
Pathophysiology
UA/NSTEMI is most commonly caused by a reduction in oxygen supply and/or by an increase in myocardial oxygen demand superimposed on an atherosclerotic coronary plaque, with varying degrees of obstruction. Four pathophysiologic processes that may contribute to the development of UA/NSTEMI have been identified: (1) plaque rupture or erosion with superimposed nonocclusive thrombus, believed to be the most common cause—NSTEMI may occur with downstream embolization of platelet aggregates and/or atherosclerotic debris; (2) dynamic obstruction [e.g., coronary spasm, as in Prinzmetal's variant angina (p. 4)]; (3) progressive mechanical obstruction [e.g., rapidly advancing coronary atherosclerosis or restenosis following percutaneous coronary intervention (PCI)]; and (4) secondary UA related to increased myocardial oxygen demand and/or decreased supply (e.g., tachycardia, anemia). More than one of these processes may be involved.
Clinical Presentation
History and Physical Examination
The clinical hallmark of UA/NSTEMI is chest pain, typically located in the substernal region or sometimes in the epigastrium, that radiates to the neck, left shoulder, and left arm. This discomfort is usually severe enough to be considered painful. Anginal "equivalents" such as dyspnea and epigastric discomfort may also occur, and these appear to occur more often in women. The examination resembles that in patients with stable angina and may be unremarkable. If the patient has a large area of myocardial ischemia or a large NSTEMI, the physical findings can include diaphoresis, pale cool skin, sinus tachycardia, a third and/or fourth heart sound, basilar rales, and sometimes hypotension, resembling the findings of large STEMI.
In UA, ST-segment depression, transient ST-segment elevation, and/or T-wave inversion occur in 30–50% of patients, depending on the severity of the clinical presentation. In patients with the clinical features of UA, the presence of new ST-segment deviation, even of only 0.05 mV, is an important predictor of adverse outcome. T-wave changes are sensitive for ischemia but less specific, unless they are new, deep T-wave inversions (>0.3 mV).
Figure 1. Diagnostic evaluation of patients presenting with suspected UA/NSTEMI. The first step is to assess the likelihood of coronary artery disease (CAD). Patients at high or intermediate likelihood are admitted to the hospital. Those with clearly atypical chest pain are sent home. Patients with a low likelihood of ischemia enter the pathway and are observed in a monitored bed in the emergency department (ED) or observation unit over a period of 6 h, and 12-lead electrocardiograms are performed if the patient has recurrent chest discomfort. A panel of cardiac markers (e.g., troponin and CK-MB) is drawn at baseline and 6 h later. If the patient develops recurrent pain, has ST-segment or T-wave changes, or has positive cardiac markers, he/she is admitted to the hospital and treated for UA/NSTEMI. If the patient has negative markers and no recurrence of pain, he/she is sent for exercise treadmill testing, with imaging reserved for patients with abnormal baseline electrocardiograms (e.g., left bundle branch block or left ventricular hypertrophy). If positive, the patient is admitted; if negative, the patient is discharged, with follow-up to his/her primary physician. ETT, exercise tolerance test; MI, myocardial infarction. [Adapted from CP Cannon, E Braunwald, in Heart Disease: A Textbook of Cardiovascular Medicine, 6th ed, E Braunwald et al (eds).
Risk Stratification and Prognosis
Patients with documented UA/NSTEMI exhibit a wide spectrum of early (30 days) risk of death, ranging from 1 to 10%, and of new or recurrent infarction of 3–10%. Assessment of "global risk" can be accomplished by clinical risk scoring systems such as that developed from in the Thrombolysis in Myocardial Infarction (TIMI) Trials, which includes seven independent risk factors: age >65 years, three or more risk factors for CAD, documented CAD at catheterization, development of UA/NSTEMI while on aspirin, more than two episodes of angina within the preceding 24 h, ST deviation >0.5 mm, and an elevated cardiac marker (Fig. 2). Other risk factors include diabetes mellitus, left ventricular dysfunction, and elevated levels of creatinine, atrial natriuretic peptides, and C-reactive protein.
Figure 2. The TIMI Risk Score for UA/NSTEMI, a simple but comprehensive clinical risk stratification score to identify increasing risk of death, myocardial infarction, or urgent revascularization to day 14. CAD, coronary artery disease; ASA, aspirin. (Adapted from Antman et al.)
Early risk assessment (especially using troponin, ST-segment changes, and/or a global risk scoring system) is useful both in predicting the risk of recurrent cardiac events and in identifying those patients who would derive the greatest benefit from antithrombotic therapies more potent than unfractionated heparin, such as low-molecular-weight heparin (LMWH) and glycoprotein (GP)IIb/IIIa inhibitors, and from an early invasive strategy. For example, in the TACTICS-TIMI 18 Trial, an early invasive strategy conferred a 40% reduction in recurrent cardiac events in patients with a positive troponin level, whereas no benefit was observed in those with a negative troponin level.
C-reactive protein, a marker of vascular inflammation, and B-type natriuretic peptide, a marker of increased myocardial wall tension, correlate independently with increased mortality (and, in some studies, recurrent cardiac events) in patients presenting with UA/NSTEMI. Multimarker strategies are now gaining favor both to define the pathophysiologic mechanisms underlying a given patient's presentation more fully and to stratify the patient's risk further.
TREATMENT
Medical Treatment
Patients with UA/NSTEMI should be placed at bed rest with continuous ECG monitoring for ST-segment deviation and cardiac rhythm. Ambulation is permitted if the patient shows no recurrence of ischemia (discomfort or ECG changes) and does not develop a biomarker of necrosis for 12–24 h. Medical therapy involves simultaneous anti-ischemic treatment and antithrombotic treatment.
(Table 1) In order to provide relief and prevention of recurrence of chest pain, initial treatment should include bed rest, nitrates, and beta blockers.
Nitrates
Nitrates should first be given sublingually or by buccal spray (0.3–0.6 mg) if the patient is experiencing ischemic pain. If pain persists after three doses given 5 min apart, intravenous nitroglycerin (5–10 µg/min using nonabsorbing tubing) is recommended. The rate of the infusion may be increased by 10 µg/min every 3–5 min until symptoms are relieved or systolic arterial pressure falls to <100 style=""> can be used once the pain has resolved, or they may replace intravenous nitroglycerin when the patient has been pain-free for 12–24 h. The only absolute contraindications to the use of nitrates are hypotension or the use of sildenafil (Viagra) or other drugs in that class within the previous 24 h.
β-Adrenergic Blockade
These agents are the other mainstay of anti-ischemic treatment. Intravenous beta blockade followed by oral beta blockade targeted to a heart rate of 50–60 beats/min is recommended. Heart rate–slowing calcium channel blockers, e.g., verapamil or diltiazem, are recommended in patients who have persistent or recurrent symptoms after treatment with full-dose nitrates and beta blockers and in patients with contraindications to beta blockade. Additional medical therapy includes angiotensin-converting enzyme (ACE) inhibition and HMG-CoA reductase inhibitors (statins) for long-term secondary prevention.
If pain persists despite intravenous nitroglycerin and beta blockade, morphine sulfate, 1–5 mg intravenously, can be administered every 5–30 min as needed.
(Table 2) This is the other main component of treatment for UA/NSTEMI. Initial treatment should begin with the platelet cyclooxygenase inhibitor aspirin (Fig. 3). The typical initial dose is 325 mg daily, with lower doses (75–162 mg daily) recommended for long-term therapy. "Aspirin resistance" has been noted in research studies in 5–10% of patients and more frequently in patients treated with lower doses of aspirin. No clear guidelines are available regarding evaluation or treatment, but the use of higher doses of aspirin and/or a thienopyridine (clopidogrel) appears to be logical in this situation.
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aOther LMWH exist beyond those listed. Note: IV, intravenous; SC, subcutaneously; UFH, unfractionated heparin. Source: Modified from E Braunwald et al: J Am Coll Cardiol 2000;36:970–1056. |
Figure 3. Platelets initiate thrombosis at the site of a ruptured plaque with denuded endothelium: platelet adhesion occurs via (1) the GP 1b receptor in conjunction with von Willebrand factor. This is followed by platelet activation (2), which leads to a shape change in the platelet, degranulation of the alpha and dense granules, and expression of glycoprotein IIb/IIIa receptors on the platelet surface with activation of the receptor, such that it can bind fibrinogen. The final step is platelet aggregation (3), in which fibrinogen (or von Willebrand factor) binds to the activated GP IIb/IIIa receptors. Aspirin (ASA) and clopidogrel act to decrease platelet activation, whereas the GP IIb/IIIa inhibitors inhibit the final step of platelet aggregation. GP, glycoprotein. [Modified from CP Cannon, E Braunwald, in Heart Disease: A Textbook of Cardiovascular Medicine, 8th ed, P Libby et al (eds).
The thienopyridine clopidogrel, which blocks the platelet P2Y12 (adenosine) receptor (in combination with aspirin), was shown in the CURE trial to confer a 20% relative reduction in cardiovascular death, MI, or stroke, compared with aspirin alone in both low- and high-risk patients with UA/NSTEMI, but to be associated with a moderate (absolute 1%) increase in major bleeding, which is more common in patients who undergo coronary artery bypass grafting. Pretreatment with clopidogrel (a 300 or 600 mg loading dose, followed by 75 mg qd) has also been shown in three studies to reduce adverse outcomes associated with and following PCI and has a Class I, Grade A evidence recommendation in the PCI Guidelines. Continued benefit of long-term (~1 year) treatment with the combination of clopidogrel and aspirin has been observed both in patients treated conservatively and in those who underwent a PCI. This combination is recommended for all patients with UA/NSTEMI who are not at excessive risk for bleeding.
Four options are available for anticoagulation therapy to be added to aspirin and clopidogrel. Unfractionated heparin (UFH) is the mainstay of therapy. The LMWH enoxaparin has been shown in several studies to be superior to UFH in reducing recurrent cardiac events, especially in conservatively managed patients. The Factor Xa inhibitor fondaparinux is equivalent for early efficacy compared with enoxaparin but appears to have a lower risk of major bleeding and thus may have the best benefit risk ratio. However, UFH, LMWH, or a direct thrombin inhibitor such as bivalirudin should be used during cardiac catheterization or PCI. Preliminary data indicate that bivalirudin is equivalent (for both efficacy and safety) to either UFH or enoxaparin among patients treated with a GP IIb/IIIa inhibitor, but use of bivalirudin alone had less bleeding than the combination of a heparin and GP IIb/IIIa inhibitor in patients with UA/NSTEMI undergoing PCI.
Intravenous GP IIb/IIIa inhibitors have also been shown to be beneficial in treating UA/NSTEMI. For "upstream" management of high-risk patients in whom an invasive management is intended (i.e., initiating therapy when the patient first presents to the hospital), the small molecule inhibitors eptifibatide and tirofiban show benefit, while the monoclonal antibody abciximab appears not to be effective in patients treated conservatively, (i.e., in those not undergoing coronary angiography or PCI). However, abciximab has been shown to be beneficial in patients with UA/NSTEMI undergoing PCI, even among troponin positive patients pretreated with clopidogrel. The ACC/AHA Guidelines note that these agents can be started either in the ED or during PCI. As with all antithrombotic agents, bleeding is the most important adverse effect of antiplatelet drugs, especially their combination. Thus, patients with a history of bleeding must be screened carefully and given fewer antithrombotic agents.
Invasive versus Conservative Strategy
Multiple clinical trials have shown the benefit of an early invasive strategy in high-risk patients, i.e., patients with multiple clinical risk factors, ST-segment deviation, and/or positive biomarkers (Table 3). In this strategy, following treatment with anti-ischemic and antithrombotic agents, coronary arteriography is carried out within ~48 h of admission, followed by coronary revascularization (PCI or coronary artery bypass grafting), depending on the coronary anatomy.
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Abbreviations: TnT, troponin T; TnI, troponin I; Rec, recurrent; CHF, congestive heart failure; MR, mitral regurgitation; EF, ejection fraction; BP, blood pressure; VT, ventricular tachycardia; PCI, percutaneous coronary intervention; CABG, coronary artery bypass grafting. Source: E Braunwald et al: Circulation 106:1893, 2002. In low-risk patients, the outcomes from an invasive strategy are similar to those obtained from a conservative strategy, which consists of anti-ischemic and antithrombotic therapy followed by "watchful waiting," in which coronary arteriography is carried out only if rest pain or ST-segment changes recur or there is evidence of ischemia on a stress test. |
Long-Term Management
The time of hospital discharge is a "teachable moment" for the patient with UA/NSTEMI, when the physician can review and optimize the medical regimen. Risk factor modification is key, and the physician should discuss with the patient the importance of smoking cessation, achieving optimal weight, daily exercise following an appropriate diet, blood pressure control, tight control of hyperglycemia (for diabetic patients), and lipid management, as recommended for patients with chronic stable angina.
There is evidence of benefit with long-term therapy with five classes of drugs that are directed at different components of the atherothrombotic process. Beta blockers are appropriate anti-ischemic therapy and may help decrease triggers for MI. Statins (at a high dose, e.g., atorvastatin 80 mg/d) and ACE inhibitors are recommended for long-term plaque stabilization. Antiplatelet therapy, now recommended to be the combination of aspirin and clopidogrel for at least 9–12 months, with aspirin continued thereafter, prevents or reduces the severity of any thrombosis that would occur if a plaque does rupture. Thus, a multifactorial approach to long-term medical therapy is directed at preventing the various components of atherothrombosis. This therapy should be begun early, i.e. within a week of the event, whenever possible.
PRINZMETAL'S VARIANT ANGINA
In 1959 Prinzmetal et al. described a syndrome of ischemic pain that occurs at rest but not usually with exertion and is associated with transient ST-segment elevation. This syndrome is due to focal spasm of an epicardial coronary artery, leading to severe myocardial ischemia. The exact cause of the spasm is not well defined, but it may be related to hypercontractility of vascular smooth muscle due to vasoconstrictor mitogens, leukotrienes, or serotonin. In some patients it is a manifestation of a vasospastic disorder and is associated with migraine, Raynaud's phenomenon, or aspirin-induced asthma.
Clinical and Angiographic Manifestations
Patients with variant angina are generally younger and have fewer coronary risk factors (with the exception of cigarette smoking) than patients with UA secondary to coronary atherosclerosis. The anginal discomfort is often extremely severe and has usually not progressed from a period of chronic stable angina. Cardiac examination is usually normal in the absence of ischemia.
The clinical diagnosis of variant angina is made with the detection of transient ST-segment elevation with rest pain. Many patients also exhibit multiple episodes of asymptomatic ST-segment elevation (silent ischemia). Small elevations of CK-MB and troponin may occur in patients with prolonged attacks of variant angina. Exercise testing in patients with variant angina is of limited value because the patients can demonstrate ST elevation, depression, or no ST changes.
Coronary angiography demonstrates transient coronary spasm as the diagnostic hallmark of Prinzmetal's angina. Atherosclerotic plaques, which do not usually cause critical obstruction, in at least one proximal coronary artery occur in the majority of patients, and in them spasm usually occurs within 1 cm of the plaque. Focal spasm is most common in the right coronary artery, and it may occur at one or more sites in one artery or in multiple arteries simultaneously. Ergonovine, acetylcholine, other vasoconstrictor medications, and hyperventilation have been used to provoke and demonstrate focal coronary stenosis to establish the diagnosis. Hyperventilation has also been used to provoke rest angina, ST-segment elevation, and spasm on coronary arteriography.
Prinzmetal's Variant Angina: Treatment
Nitrates and calcium channel blockers are the main treatments for patients with variant angina. Sublingual or intravenous nitroglycerin often abolishes episodes of variant angina promptly, and long-acting nitrates are useful in preventing recurrences. Calcium antagonists are extremely effective in preventing the coronary artery spasm of variant angina, and they should be prescribed in maximally tolerated doses. Similar efficacy rates have been noted among the various types of calcium antagonists. Prazosin, a selective α-adrenoreceptor blocker, has also been found to be of value in some patients, while aspirin may actually increase the severity of ischemic episodes. The response to beta blockers is variable. Coronary revascularization may be helpful in patients with variant angina who also have discrete, proximal fixed obstructive lesions.