ST-Elevation Myocardial Infarction: Management

Aspirin

Aspirin is effective across the entire ACS spectrum and is part of the initial management strategy for patients with suspected STEMI. Because low doses take several days to achieve a full antiplatelet effect, 162 to 325 mg should be administered at the first opportunity after initial medical contact. To achieve therapeutic blood levels rapidly, the patient should chew a non–enteric-coated tablet to promote buccal absorption bypassing the gastric mucosa.

Control of Cardiac Pain

Initial management of patients with STEMI should target relief of pain and its associated heightened sympathetic activity. Control of cardiac pain uses a combination of analgesics (e.g., morphine) and interventions to improve the balance of myocardial oxygen supply and demand, including oxygen (in the setting of hypoxia), nitrates, and in appropriately selected patients, beta-adrenergic receptor-blocking agents (beta blockers).

Dynamic Nature of Infarction

STEMI is a dynamic process that does not occur instantaneously but rather evolves over hours. The fate of jeopardized, ischemic tissue can be ameliorated by interventions that restore myocardial perfusion, reduce microvascular damage in the infarct zone, decrease myocardial oxygen requirements, inhibit accumulation or facilitate washout of noxious metabolites, augment the availability of substrate for anaerobic metabolism, or blunt the effects of mediators of injury that compromise the structure and function of intracellular organelles and constituents of cell membranes. Strong evidence in experimental animals and suggestive evidence in patients indicate that ischemic preconditioning, a form of endogenous protection against STEMI, before sustained coronary occlusion decreases infarct size and associates with a more favorable outcome, along with decreased risk for extension of infarction and recurrent ischemic events. Brief episodes of ischemia in one coronary vascular bed may precondition myocardium in a remote zone and thereby attenuate the size of infarction in the latter when sustained coronary occlusion occurs.

Perfusion of myocardium in the infarct zone appears to fall maximally immediately following coronary occlusion. Spontaneous recanalization of an occluded infarct-related artery occurs in up to one-third of patients beginning at 12 to 24 hours. This delayed spontaneous reperfusion may enhance LV function because it improves healing of infarcted tissue, prevents ventricular remodeling, and reperfuses hibernating myocardium. Yet, strategies involving pharmacologically induced and catheter-based reperfusion of the infarct vessel can maximize the amount of salvaged myocardium by accelerating the process of reperfusion and also implementing it in patients who would otherwise have a persistently occluded infarct-related artery. An overarching concept that applies to all methods of reperfusion is the critical importance of time. The earlier the infarct artery is reperfused, the greater the reduction in mortality ( Fig. 38.4 ).

Additional factors that may limit infarct size during reperfusion include relief of coronary spasm, prevention of damage to the microvasculature, improved systemic hemodynamics (augmentation of coronary perfusion pressure and reduced LV end-diastolic pressure), and collateral circulation. Prompt implementation of measures designed to protect ischemic myocardium and support myocardial perfusion may provide sufficient time for the development of compensatory mechanisms that limit the ultimate extent of infarction (see Chapter 37 ). Interventions designed to protect the ischemic myocardium during the initial event may also reduce the extension of infarction or early reinfarction. An area of active investigation includes LV unloading with a microaxial LV assist device prior to revascularization, attempting to reduce LV oxygen demands and therefore minimize ischemia and reperfusion injury.

Routine Measures for Limitation of Infarct Size

Although timely reperfusion of ischemic myocardium is the most important intervention to limit infarct size, several routine measures to accomplish this goal apply to all patients with STEMI, regardless of whether they receive reperfusion therapy. The treatment strategies discussed in this section can be initiated at first medical contact and can be continued throughout the hospital phase of care.

Myocardial oxygen consumption should be minimized by maintaining the patient at rest both physically and emotionally and by using mild sedation and a quiet atmosphere—in addition to the interventions already discussed. Administration of adrenergic agonists should be avoided whenever possible. All forms of tachyarrhythmia require prompt treatment because they increase myocardial oxygen needs. HF should also be treated swiftly to minimize increases in adrenergic tone and hypoxemia (see later, Left Ventricular Failure). If ongoing ischemia occurs, severe anemia (hemoglobin <7 g/dL) can be corrected by the cautious administration of packed red blood cells, accompanied by a diuretic if there is any evidence of LV failure. Associated conditions, particularly infections and accompanying tachycardia, fever, and elevated myocardial oxygen needs, require management.

Reperfusion Injury

Reperfusion, although beneficial in terms of myocardial salvage, may cause adverse sequelae described by the term reperfusion injury (see Chapter 37 ). ^, Several types of reperfusion injury occur in experimental animals: (1) lethal reperfusion injury, which refers to reperfusion-induced death of cells that were still viable at restoration of coronary blood flow; (2) vascular reperfusion injury, which is progressive damage to the microvasculature such that there is an expanding area of no-reflow and loss of coronary vasodilatory reserve; (3) stunned myocardium, in which salvaged myocytes display a prolonged period of contractile dysfunction after restoration of blood flow because of abnormalities in intracellular metabolism, leading to reduced energy production; and (4) reperfusion arrhythmias, which refer to bursts of VT (and occasionally VF) that occur within seconds of reperfusion. ^{, ,} Vascular reperfusion injury, stunning, and reperfusion arrhythmias can all occur in patients with STEMI. The concept of lethal reperfusion injury to potentially salvageable myocardium remains controversial, both in animals and in humans. ^,

Reperfusion Arrhythmias

Transient sinus bradycardia occurs in many patients with inferior infarcts at the time of acute reperfusion, often accompanied by some degree of hypotension. This combination of hypotension and bradycardia with a sudden increase in coronary flow may involve activation of the Bezold-Jarisch reflex. Premature ventricular contractions (PVCs), accelerated idioventricular rhythm, and nonsustained VT also usually follow successful reperfusion. Although some investigators have postulated that early afterdepolarizations participate in the genesis of reperfusion-related ventricular arrhythmias, they are present during both ischemia and reperfusion and therefore not likely to be involved in the development of reperfusion-associated VT or VF.

When present, rhythm disturbances may actually indicate successful restoration of coronary flow, but their specificity for successful reperfusion is limited. In general, clinical features are inaccurate markers of reperfusion, with no single clinical finding or constellation of findings being reliably predictive of angiographically demonstrated coronary artery patency. Although reperfusion arrhythmias may show a temporal clustering at restoration of coronary blood flow in patients after successful fibrinolysis, this brief “electrical storm” is generally innocuous and therefore does not warrant prophylactic antiarrhythmic therapy or specific treatment, except in rare cases of symptomatic or hemodynamically significant reperfusion arrhythmias.

Late Establishment of Patency of the Infarct Vessel

The improved survival and ventricular function after successful reperfusion may not result entirely from limitation of infarct size. Poorly contracting or noncontracting myocardium in a zone that is supplied by a stenosed infarct-related artery with slow anterograde perfusion may still contain viable myocytes. PCI can augment flow in the infarct-related artery and thus improve the function of hibernating myocardium.

Comparison of Fibrinolytic Agents

Table 38.4 presents the comparative features of the approved fibrinolytic agents for IV therapy. All fibrinolytic agents exert their effect by converting the proenzyme plasminogen to the active enzyme plasmin. The so-called fibrin-specific fibrinolytics are those that are relatively inactive in the absence of fibrin but in its presence substantially increase their activity on plasminogen (see Chapter 95 ). The tissue plasminogen activator (t-PA) molecule contains five domains ( eFig. 38.6 ). In the absence of fibrin, t-PA is a weak plasminogen activator; fibrin provides a scaffold on which t-PA and plasminogen are held in such a way that the catalytic efficiency of t-PA increases many-fold. A dose regimen of t-PA administered over a 90-minute period produces more rapid thrombolysis than a 3-hour fixed-rate infusion. Therefore, the recommended dosage for t-PA is the 90-minute “accelerated” regimen. Modifications in the native t-PA structure have yielded a group of fibrinolytic agents with prolonged clearance that allows them to be administered as a bolus (see eFig. 38.6 and Table 38.4 ). Reteplase (double fixed-dose bolus) and tenecteplase (single weight-based bolus) confer mortality benefits similar to that achieved with accelerated t-PA, but with more convenient dosing. In one large trial, tenecteplase had a lower rate of major bleeding than accelerated t-PA or other regimens. Streptokinase, a protein derived from streptococci, binds and activates human plasminogen and is an inexpensive and effective fibrinolytic agent that is still used in some regions of the world.

The choice of fibrinolytic in hospital systems is generally driven by the desire to establish consistent protocols within the health care system by weighing ease of dosing, cost, and other institutional preferences. In patients seen early with acceptable bleeding risk, a high-intensity fibrin-specific regimen, such as accelerated t-PA, reteplase, or tenecteplase, is usually preferable. Bolus fibrinolytics have a lower chance of medication errors and are associated with less noncerebral bleeding—as well as offering the potential for prehospital treatment. ^,

Effect on Left Ventricular Function

As with survival, improvement in global LV function is related to the time of initiation of fibrinolytic treatment, with the greatest improvement occurring with the earliest therapy. Nevertheless, left ventricular ejection fraction (LVEF) is not adequate as a surrogate for infarct size because little difference is seen in EF between groups that show a significant difference in mortality. However, patients with smaller end-systolic volumes and better-preserved ventricular shape have better survival. The myocardial salvage index is defined as the difference between the initial perfusion defect (e.g., by CMR or sestamibi scintigraphy) and the final perfusion defect. ^, CMR can characterize LV volumes, the extent of the scar by gadolinium delayed hyperenhancement, and the presence of ischemia with stress perfusion imaging, providing significant incremental prognostic information over other clinical variables. ^,

Complications of Fibrinolytic Therapy

Bleeding complications are most common, and intracranial hemorrhage is the most serious complication of fibrinolytic therapy; its frequency is generally less than 1% but varies with the clinical characteristics of the patient and the fibrinolytic agent used ( Fig. 38.7 ). Intracranial bleeding in the setting of fibrinolysis for STEMI is associated with a high case-fatality rate. Nonintracranial bleeding can also increase morbidity, but whether it causes higher overall mortality after taking into account the higher-risk clinical characteristics that also predispose patients to bleeding during treatment of STEMI is uncertain. ^,

Reports have demonstrated an “early hazard” with fibrinolytic therapy—that is, an excess of deaths in the first 24 hours in fibrinolytic-treated patients compared with controls, especially in elderly patients treated more than 12 hours after symptom onset. However, this excess early mortality is more than offset by deaths prevented beyond the first day, with an average 18% (range, 13% to 23%) reduction in mortality by 35 days compared with offering no reperfusion therapy. The mechanisms responsible for this early hazard are probably multiple, including an increased risk for myocardial rupture, fatal intracranial hemorrhage, and possibly myocardial reperfusion injury.

Recent exposure to streptococci or streptokinase produces some degree of antibody-mediated resistance to streptokinase (and anistreplase) in most patients. Although such resistance is only rarely of clinical consequence, patients should not receive streptokinase for STEMI if they have been treated with a streptokinase product within the past 6 months.

Surgical Reperfusion

Providing surgical reperfusion in a timely fashion during STEMI is usually not logistically possible. Therefore, patients with STEMI who are candidates for reperfusion should undergo either immediate PCI or if not practical then fibrinolysis. However, patients with STEMI may be referred for CABG for persistent or recurrent ischemia after fibrinolysis or primary PCI with residual coronary disease not amenable to PCI, high-risk coronary anatomy (e.g., left main stenosis) discovered at initial catheterization or a complication of STEMI such as ventricular septal rupture or severe mitral regurgitation caused by papillary muscle dysfunction. STEMI patients with continued severe ischemic and hemodynamic instability will probably benefit from emergency revascularization.

Patients who successfully undergo fibrinolysis but have important residual stenoses and on anatomic grounds are more suitable for surgical revascularization than for PCI have undergone CABG with quite low rates of mortality (approximately 4%) and morbidity, provided that the procedure is carried out more than 24 hours after STEMI; patients requiring urgent or emergency CABG within 24 to 48 hours of STEMI have mortality rates between 12% and 15%. Surgery performed under urgent conditions with active and ongoing ischemia or cardiogenic shock, are associated with higher operative mortality rates, in large part reflecting the patient’s overall condition that necessitated emergency surgery.

Referral for Angiography with Intent of Revascularization after Initial Fibrinolysis

Patients with STEMI who are initially managed by fibrinolysis at a non–PCI-capable center should be transferred urgently to a PCI-capable center if the patient develops cardiogenic shock or severe HF or has failed reperfusion with a fibrinolytic. Transfer should also be considered (class IIa) as a part of a pharmacoinvasive strategy in stable patients with the intention of performing angiography, and PCI as necessary, 3 to 24 hours after fibrinolysis ( Table 38.5 ; see Fig. 38.2 ). ^,

Patients undergoing angiography and PCI after the suspected failure of reperfusion with fibrinolysis tend to have a lower mortality rate and significantly lower rates of recurrent MI and HF compared with patients who continue medical therapy, including readministration of a fibrinolytic agent. In the REACT (Rapid Early Action for Coronary Treatment) study, patients with suspected failed reperfusion at 90 minutes by electrocardiographic criteria were randomly assigned to one of three treatment arms: rescue PCI, conservative care, or repeated fibrinolytic therapy. The composite of death, reinfarction, stroke, or severe HF at 6 months was significantly lower in patients randomly assigned to rescue PCI than in the two other treatment groups. More minor bleeding, however, occurred in patients randomly assigned to rescue PCI. The option of administration of a fibrinolytic agent at non-PCI-capable hospitals, followed by routine transfer for angiography and PCI if indicated, has been advanced as an attractive strategy to offer timely reperfusion therapy and arrange a “nonemergency” transfer for subsequent procedures to reduce the risk for subsequent reinfarction. Retrospective analyses of trials of fibrinolytic therapy indirectly support this approach because they suggest a lower risk for recurrent MI and a lower 2-year mortality rate in patients who subsequently undergo early PCI. The limited randomized trials evaluating a strategy of routine catheterization after fibrinolysis have provided mixed results. Nevertheless, overall, these trials have suggested improvement in clinical outcomes in patients transferred for early catheterization, particularly those at higher risk for death and recurrent ischemia ( Fig. 38.11 and eFig. 38.7 ). In the largest of these studies, TRANSFER-AMI (Trial of Routine Angioplasty and Stenting after Fibrinolysis to Enhance Reperfusion in Acute Myocardial Infarction; n = 1059), immediate transfer for angiography versus conservative care reduced the composite endpoint of death, recurrent MI, recurrent ischemia, new or worsening HF, or shock at 30 days. In a meta-analysis that included seven randomized trials of early transfer for catheterization, a strategy of routine early catheterization after fibrinolysis yielded a statistically significant 35% reduction in the incidence of death or MI at 30 days (odds ratio [OR], 0.65; 95% confidence interval [CI] 0.49 to 0.88) without an increase in the risk for major bleeding (see Fig. 38.11 ). ^,

Notably, the clinical trials that assessed routine invasive evaluation after initial fibrinolysis used a time window of 0 to 24 hours for the “early invasive” strategy, thus supporting earlier transfer after administration of fibrinolytic therapy, even for patients without high-risk features. Although we believe that there will probably be continued benefit even beyond 24 hours in patients with a patent but stenotic infarct artery after initial successful reperfusion, later time windows have not been directly examined. Because of the associated increased bleeding risk, very early (<2 to 3 hours) catheterization after the administration of fibrinolytic therapy with the intent to perform revascularization should be reserved for patients with evidence of failed fibrinolysis and significant myocardial jeopardy, for whom rescue PCI would be appropriate. In addition, when STEMI is suspected to have occurred by a mechanism other than thrombotic occlusion at the site of atherosclerotic plaque, coronary angiography may provide diagnostic information and direct specific therapy.

In summary, delayed coronary angiography with PCI of the infarct artery is indicated in patients initially treated with a noninvasive strategy (i.e., with fibrinolysis or without reperfusion therapy) who become unstable with cardiogenic shock, acute severe HF, or ongoing ischemia, provided that invasive management is not considered futile or inappropriate (see Table 38.5 ). Delayed PCI also appears to be reasonable in patients with failed fibrinolysis or reocclusion of the infarct artery or in those who demonstrate significant residual ischemia during hospitalization after initial noninvasive management. The benefits of routine (non-ischemia-driven) PCI on an angiographically significant stenosis in a patent infarct artery more than 24 hours after STEMI are less well established, and delayed PCI on a totally occluded infarct artery longer than 24 hours after STEMI should not be undertaken in clinically stable patients without evidence of severe ischemia.

Patients Not Eligible for Reperfusion Therapy

Aspirin and antithrombin therapy can be prescribed for patients who are not candidates for acute reperfusion because of the lack of availability of PCI and contraindications to fibrinolysis. In the setting of absolute contraindications to fibrinolysis (see Table 38.3 ) and lack of access to PCI facilities, antithrombotic therapy should be initiated because of the slight chance (approximately 10%) of restoring TIMI grade 3 flow in the infarct vessel and decreasing the chance of complications of STEMI.

Anticoagulant Therapy

The rationale for administering anticoagulant therapy acutely to patients with STEMI includes establishing and maintaining patency of the infarct-related artery, regardless of whether a patient receives fibrinolytic therapy ( eFig. 38.8 ), and preventing deep venous thrombosis, pulmonary embolism, ventricular thrombus formation, and cerebral embolization.

Hirudin and Bivalirudin

In patients undergoing fibrinolysis, direct thrombin inhibitors such as hirudin or bivalirudin reduce the incidence of recurrent MI by 25% to 30% compared with heparin but have not reduced mortality. In addition, either hirudin or bivalirudin causes higher rates of major bleeding than heparin when used with fibrinolytic agents. As direct thrombin inhibitors have not been studied with fibrin-specific agents, there is no evidence to guide recommendations on their use in fibrinolysis.

In contrast, when administered for a short period as an adjunct to primary PCI in the HORIZONS-AMI (Harmonizing Outcomes with Revascularization and Stents in Acute Myocardial Infarction) trial, bivalirudin (open label), versus heparin plus glycoprotein (GP) IIb/IIIa inhibitors, reduced the 30-day rate of major bleeding or major adverse CV events, including death, reinfarction, target vessel revascularization for ischemia, and stroke (RR, 0.76; 95% CI 0.63 to 0.92; P = 0.005), driven by a significant 40% reduction in major bleeding ( eFig. 38.9 ). Treatment with bivalirudin significantly reduced mortality at 30 days and at 1 year but increased the early risk for stent thrombosis. Similarly, in the EUROMAX (European Ambulance Acute Coronary Syndrome Angiography) trial, when started during transport for primary PCI in STEMI, bivalirudin reduced the primary outcome of death or major bleeding compared to heparin with optional GP IIb/IIIa, with a reduction in major bleeding but increase in stent thrombosis. However, there was no significant difference in mortality. A meta-analysis of 16 randomized controlled trials (RCTs), including four with predominantly STEMI patients, reported an increased risk of major adverse cardiovascular events (MACE) (RR, 1.09; 95% CI 1.01 to 1.17; P = 0.0204) with bivalirudin, primarily from increases in MI, ischemia-driven revascularization, and acute stent thrombosis ( Fig. 38.12 ). There was no difference in mortality, and bleeding rates were generally lower with bivalirudin, with the magnitude of the reduction dependent on the rates of GP IIb/IIIa co-administration in the relevant trials. The findings were consistent in the subset with STEMI.

Low-Molecular-Weight Heparins

Advantages of low-molecular-weight heparins (LMWHs) include a stable, reliable anticoagulant effect, high bioavailability permitting administration via the subcutaneous (SC) route, and a high anti-Xa/anti-IIa ratio producing blockade of the coagulation cascade in an upstream location and greatly reducing thrombin generation. The primary role of LMWH for the management of STEMI is as an adjunct to fibrinolytic therapy. Although LMWHs do not improve the rate of early (60 to 90 minutes) reperfusion of the infarct artery, LMWH reduces rates of reocclusion of the infarct artery, reinfarction, or recurrent ischemic events. This effect may underlie the significant reduction in recurrent MI with a strategy of extended anticoagulation with LMWHs, or a factor Xa antagonist versus standard therapy, in patients with STEMI undergoing fibrinolysis.

Moreover, in a placebo-controlled trial, an LMWH reduced the incidence of death, recurrent MI, or stroke at 30 days. This finding demonstrated not only that LMWHs are clinically effective in patients with STEMI, but also that anticoagulant therapy provides benefit as part of a fibrinolytic reperfusion strategy.

Several trials have compared an LMWH with UFH as part of a pharmacologic reperfusion strategy and demonstrated the LMWH to be superior. In the ASSENT (Assessment of the Safety and Efficacy of a New Thrombolytic) 3 trial, enoxaparin (30-mg IV bolus, followed by SC injections of 1 mg/kg every 12 hours until discharge from the hospital) reduced 30-day mortality, in-hospital reinfarction, or in-hospital refractory ischemia compared with UFH (RR, 0.74; 95% CI 0.63 to 0.87). The rate of intracranial hemorrhage was similar with UFH and enoxaparin (0.93% versus 0.88%; P = 0.98). In the ExTRACT-TIMI 25 (Enoxaparin and Thrombolysis Reperfusion for Acute Myocardial Infarction Treatment–Thrombolysis in Myocardial Infarction 25) trial, a strategy of enoxaparin administered for the duration of the index hospitalization was superior ( Fig. 38.13A ) to the conventional antithrombin strategy of UFH administration for 48 hours after fibrinolysis, with a 33% reduction ( P = 0.001) in reinfarction and a nonsignificant favorable trend on overall mortality ( P = 0.11). This improvement in recurrent MI was balanced by an increase in the incidence of major bleeding (1.4% and 2.1%, P = 0.001). In a meta-analysis of trials of LMWH versus UFH, LMWH clearly reduced recurrent MI but with a pattern of increased bleeding ( Fig. 38.13B ).

Antiplatelet Therapy

Platelets play a major role in the response to the disruption of coronary artery plaque, especially in the early phase of thrombus formation. Fibrinolysis can activate platelets, and platelet-rich thrombi resist fibrinolysis more than fibrin and erythrocyte-rich thrombi (see eFig. 38.8 ). Thus, a sound scientific basis exists for inhibiting platelet aggregation in all patients with STEMI, regardless of the reperfusion management strategy. The agent most extensively tested has been aspirin, and treatment with aspirin and a second antiplatelet agent, such as clopidogrel, prasugrel, ticagrelor, or cangrelor, has become the standard of care for patients with STEMI.

Antiplatelet Therapy for Percutaneous Coronary Intervention in ST-Elevation Myocardial Infarction

All patients with STEMI should receive aspirin as soon as possible after an initial encounter in the absence of contraindications. Adding the P2Y ₁₂ inhibitor clopidogrel to aspirin appears to offer additional benefit in patients undergoing PCI after STEMI ( Fig. 38.14 ). In patients undergoing either primary PCI or delayed PCI after initial therapy for STEMI, the more potent P2Y ₁₂ inhibitor prasugrel was superior to clopidogrel in reducing the risk for CV death, MI, or stroke. In the subgroup of patients with STEMI enrolled in TRITON-TIMI 38 (Trial to Assess Improvement in Therapeutic Outcomes by Optimizing Platelet Inhibition with Prasugrel–Thrombolysis in Myocardial Infarction; n = 3534), the primary endpoint was lowered by 32% at 30 days with prasugrel compared with aspirin (6.5% versus 9.5%; P = 0.0017) and by 21% at 15 months (10.0% versus 12.4%; P = 0.022) ( Fig. 38.15 ). Prasugrel reduced definite or probable stent thrombosis by 42% compared with clopidogrel. Analogously, in the PLATO (Platelet Inhibition and Patient Outcomes) trial, compared with clopidogrel, treatment with the reversible P2Y ₁₂ inhibitor ticagrelor in patients with STEMI undergoing primary PCI ( n = 7544) tended to reduce the primary endpoint of CV death, recurrent MI, or stroke by 13%, a magnitude similar to that for the overall trial population (see Fig. 38.15 ); there was a 26% reduction in definite or probable stent thrombosis and an 18% reduction in all-cause mortality.

Current evidence does not support initiation of P2Y ₁₂ inhibitor therapy before PCI for STEMI unless the strategy is for delayed invasive evaluation. As part of the PCI-CLARITY (PCI-Clopidogrel as Adjunctive Reperfusion Therapy) study, the investigators performed a meta-analysis of PCI-CLARITY, PCI-CURE (PCI-Clopidogrel in Unstable angina to prevent Recurrent Events), and CREDO (Clopidogrel for the Reduction of Events During Observation) and found that pretreatment with clopidogrel significantly reduced the risk for 30-day CV death or MI in a population that included both patients with STEMI and non-ST elevation ACS. ^, In a subsequent meta-analysis that included data from randomized trials and registries, higher-risk STEMI patients had a lower risk for major coronary events with clopidogrel pretreatment, but not a reduction in mortality or an increase in bleeding. Prehospital administration of ticagrelor did not improve the primary endpoint of coronary reperfusion but did reduce the secondary endpoint of stent thrombosis without any additional bleeding compared to in-hospital administration in patients with STEMI undergoing primary PCI in the ATLANTIC (Administration of Ticagrelor in the Cath Lab or in the Ambulance for New ST Elevation Myocardial Infarction to Open the Coronary Artery) trial. Chapter 41 discusses the use of GP IIb/IIIa inhibitors as part of adjunctive therapy for patients with STEMI undergoing PCI.

Cangrelor, a potent, fast-acting reversible, IV P2Y12 inhibitor, can be used during PCI in patients who have not received a P2Y12 inhibitor before PCI based on CHAMPION-PHOENIX (A Clinical Trial Comparing Cangrelor to Clopidogrel Standard Therapy in Subjects Who Require Percutaneous Coronary Intervention) findings demonstrating a lower rate of death, MI, revascularization, or stent thrombosis, compared with clopidogrel in patients undergoing PCI, including primary PCI for STEMI.

Recommendations for Antiplatelet Therapy

Patients who have not taken aspirin before the development of STEMI should chew non-enteric-coated aspirin, and the dose should be 162 to 325 mg initially. During the maintenance phase of antiplatelet therapy following STEMI, the dose of aspirin should be reduced to 75 to 162 mg to minimize the risk of bleeding. Lower doses are preferable because of the increased risk for bleeding with higher doses reported in several studies; the CURRENT-OASIS 7 trial did not find differences in terms of efficacy or safety in STEMI patients randomly assigned to 81 versus 325 mg of aspirin. If true aspirin allergy is present, other antiplatelet agents such as clopidogrel or ticlopidine can be substituted.

The addition of a P2Y ₁₂ inhibitor to aspirin is warranted in most patients with STEMI. Based on the results of the COMMIT and CLARITY-TIMI 28 trials, clopidogrel, 75 mg/day orally, is an option for all patients with STEMI regardless of whether they receive fibrinolytic therapy, undergo primary PCI, or do not receive reperfusion therapy. The data available suggest that a loading dose of 300 mg of clopidogrel should be given to patients younger than 75 years who receive fibrinolytic therapy. Data are insufficient in elderly patients to recommend a loading dose in those 75 years or older who receive a fibrinolytic; however, this is being addressed in an ongoing study of half-dose fibrinolytic in older patients. When primary PCI is the mode of reperfusion therapy, an oral loading dose of 600 mg of clopidogrel before stent implantation is an established treatment, followed by 75 mg daily. ^, Interpatient variability in the response to clopidogrel can occur (see Chapter 39, Chapter 9, Chapter 95 ), and individuals with lesser degrees of platelet inhibition have increased risk for death and ischemic complications.

Prasugrel and ticagrelor generally achieve greater degrees of platelet inhibition than clopidogrel and can be used to treat patients with STEMI. On the basis of the results of TRITON-TIMI 38, prasugrel administered as an oral loading dose of 60 and 10 mg daily thereafter demonstrated benefit in patients with STEMI but should not be used in patients with a history of cerebrovascular disease or who are at higher risk for life-threatening bleeding, including patients older than 75 years or those with low body weight. Ticagrelor also reduced CV events compared with clopidogrel, and in PLATO, ticagrelor was administered as an oral loading dose of 180 mg and then 90 mg twice daily. ^, When using ticagrelor, the recommended maintenance dose of aspirin is 81 mg daily. The duration of combined antiplatelet therapy for secondary prevention after STEMI is discussed in Chapter 41 (see also eFig. 38G.2 ).

General Measures

The managing clinical staff should be sensitive to patient concerns about prognosis and future productivity. Beginning education on lifestyle changes, including dietary interventions, is an important component of an overall strategy for secondary prevention (see Chapter 40 ).

The results of laboratory tests should be scrutinized for any derangements potentially contributing to arrhythmias, such as disturbances in acid-base balance or electrolytes. Delirium can be provoked by medications frequently used in the hospital, including antiarrhythmic drugs, H ₂ blockers, narcotics, and beta blockers. Use of potentially offending agents should be discontinued in patients with an abnormal mental status. Haloperidol, a butyrophenone, can be used safely in patients with STEMI.

Beta Blockers

Use of beta blockers for the treatment of patients with STEMI can cause both immediate effects (when the drug is given early in the course of infarction) and long-term effects (secondary prevention), as discussed previously. Because beta-adrenergic blockade diminishes circulating levels of free fatty acids (FFAs) by antagonizing the lipolytic effects of catecholamines and because elevated FFA levels augment myocardial oxygen consumption and probably increase the incidence of arrhythmias, these metabolic actions of beta blockers may also benefit the ischemic heart. As noted earlier, because early administration of IV beta blockers can cause detrimental effects in some patients, the present guidelines omit this therapy for most patients.

More than 52,000 patients have been randomly assigned to treatment in clinical trials studying beta-adrenergic blockade for acute MI. These trials cover a range of beta blockers and timing of administration and were largely conducted in the era before reperfusion strategies were developed for STEMI. Data available in the pre-reperfusion era suggested favorable trends toward a reduction in mortality, reinfarction, and cardiac arrest. In the reperfusion era, adding an IV beta blocker to fibrinolytic therapy was not associated with a reduction in mortality but helped reduce the rate of recurrent ischemic events. Concern arose regarding the potential risk of provoking cardiogenic shock if early IV followed by oral beta-adrenergic blockade was routinely administered to all patients with STEMI. The largest trial of beta blockers in patients with acute MI was COMMIT, which randomly assigned 45,852 patients within 24 hours of MI to metoprolol given as sequential IV boluses of 5 mg up to 15 mg, followed by 200 mg/day orally, or to placebo. The rate of the composite endpoint of death, reinfarction, or cardiac arrest in the metoprolol group (9.4%) did not differ from that in the placebo group (9.9%). Significant reductions occurred in reinfarction and episodes of VF in the metoprolol group, which translated into five fewer events for each of these endpoints per 1000 patients treated; yet, there were 11 more episodes of cardiogenic shock in the metoprolol group per 1000 patients treated. Risk for the development of cardiogenic shock (recorded as part of COMMIT protocol, in contrast to earlier studies) was greatest in patients with moderate to severe LV dysfunction (Killip class II or greater).

The combined results of the low-risk patients from COMMIT and data from earlier trials provide an overview of the effects of early IV therapy followed by oral therapy with beta blockers ( Fig. 38.16 ). A 13% reduction occurred in all-cause mortality (7 lives saved per 1000 patients treated), along with a 22% reduction in reinfarction (5 fewer events per 1000 patients treated) and a 15% reduction in VF or cardiac arrest (5 fewer events per 1000 patients treated). To achieve these benefits safely, early administration of beta blockers to patients with relative contraindications should be avoided ( Table 38.6 ).

Inhibition of the Renin-Angiotensin-Aldosterone System

The rationale for inhibition of the renin-angiotensin-aldosterone system (RAAS) includes experimental and clinical evidence of a favorable impact on ventricular remodeling, improvement in hemodynamics, and a reduction in HF incidence. Unequivocal evidence from RCTs has shown that ACE inhibitors reduce mortality from STEMI. These trials can be grouped into two categories. The first group selected MI patients for randomization on the basis of features indicative of increased mortality, such as LVEF lower than 40%, clinical signs and symptoms of HF, anterior location of infarction, and abnormal wall motion score index ( Fig. 38.17 ). The second group consisted of unselective trials that randomized all patients with MI provided that they had a minimum systolic BP of approximately 100 mm Hg (ISIS-4, GISSI-3 [Gruppo Italiano per lo Studio della Sopravvivenza nell’infarto Miocardico], CONSENSUS II [Cooperative New Scandinavian Enalapril Survival Study II], and Chinese Captopril Study) ( Fig. 38.18 ). All selective trials initiated ACE inhibitor therapy between 3 and 16 days (except for SMILE) and maintained it for 1 to 4 years, whereas the unselective trials all initiated treatment within the first 24 to 36 hours and maintained it for only 4 to 6 weeks.

A consistent survival benefit was observed in all the trials already noted, except for CONSENSUS II, the one study that used an IV preparation early in the course of MI. An estimate of the mortality benefit of ACE inhibitors in the unselective trials with a short duration of therapy was 5 lives saved per 1000 patients treated. Analysis of these unselective short-term trials indicates that approximately one-third of the lives saved occurred within the first 1 to 2 days. Certain subgroups, such as patients with anterior infarction, showed proportionately greater benefit with the early administration (11 lives saved per 1000) of ACE inhibitors. Not unexpectedly, greater survival benefits of 42 to 76 lives saved per 1000 patients treated were obtained in the selective trials with a long duration of therapy. Of note, a general 26% reduction in the risk for death attributable to ACE inhibitor treatment occurred in the selective trials. The reduction in mortality with ACE inhibitors was accompanied by significant reductions in the development of HF, thus supporting the underlying pathophysiologic rationale for administering this class of drugs to patients with STEMI.

The mortality benefits of ACE inhibitors add to those achieved with aspirin and beta blockers. The benefits of ACE inhibition appear to be a class effect because several agents reduce mortality and morbidity. To replicate these benefits in clinical practice, however, physicians should select a specific agent and prescribe the drug according to the protocols and dosages used in the clinical trials. The major contraindications to ACE inhibitors in patients with STEMI include hypotension in the setting of adequate preload, known hypersensitivity, and pregnancy. Adverse reactions include hypotension, especially after the first dose, and intolerable cough; much less often, angioedema can occur.

An alternative method of pharmacologic inhibition of the RAAS is the administration of angiotensin II receptor-blocking agents (ARBs). The VALIANT (Valsartan in Acute Myocardial Infarction) trial compared the effects of the ARB valsartan, valsartan and captopril, and captopril alone on mortality in patients with acute MI complicated by LV systolic dysfunction and/or HF within 10 days of MI. ^, Mortality rates were similar in the three treatment groups: 19.9% with valsartan, 19.3% with valsartan plus captopril, and 19.5% with captopril alone. The combination of the ACE and the ARB caused more unwanted actions; thus, drugs from these classes should not be combined.

Aldosterone blockade is another pharmacologic strategy for inhibition of the RAAS. The EPHESUS (Eplerenone Post-AMI Heart Failure Efficacy and Survival) trial randomly assigned 6642 patients with acute MI complicated by left ventricular dysfunction and heart failure to the selective aldosterone-blocking agent eplerenone or placebo in conjunction with contemporary postinfarction pharmacotherapy. ^, During a mean follow-up of 16 months, a 15% reduction occurred in the RR for mortality in favor of eplerenone. Eplerenone also reduced CV mortality or hospitalization for CV events ( Fig. 38.19 ). Serious hyperkalemia (serum potassium [K ⁺ ] concentration, 6 mmol/L) occurred in 5.5% of patients in the eplerenone group compared with 3.9% in the placebo group ( P = 0.002). In contrast, in the ALBATROSS (Aldosterone Lethal Effects Blocked in Acute MI Treated with or without Reperfusion to Improve Outcome and Survival at Six Months Follow-up) trial, early mineralocorticoid antagonism versus placebo in an expanded population of patients with MI, including both STEMI and non-ST elevation MI, and patients without left ventricular function or heart failure , did not reduce the primary outcome of death, cardiac arrest, ventricular arrhythmia, implantable cardioverter-defibrillator (ICD) placement, or HF. However, an exploratory analysis by MI type found a reduction in all-cause death (HR, 0.20; 95% CI 0.06 to 0.70) in the subgroup of patients with STEMI ( n = 1229). Further studies are necessary to determine if a mineralocorticoid receptor antagonist (MRA) improves outcomes in all STEMI patients regardless of HF or LV dysfunction.