American College of Cardiology

Antman et al., Management of Patients With STEMI: Executive Summary
J Am Coll Cardiol 2004;44:671-719

ACC/AHA Guidelines for the Management of Patients With ST-Elevation Myocardial Infarction—Executive Summary

A Report of the American College of Cardiology/American Heart Association Task Force on Practice Guidelines (Writing Committee to Revise the 1999 Guidelines for the Management of Patients With Acute Myocardial Infarction)

Developed in Collaboration With the Canadian Cardiovascular Society

6. Initial Recognition And Management In The Emergency Department

A variety of treatment options (Figure 3) (24-40) are available that can reduce mortality and morbidity in patients with STEMI, but the effectiveness of these therapies diminishes rapidly within the first several hours after symptoms onset (162,185). The traditional ED evaluation of patients with chest pain relies heavily on the patient’s history, physical examination, and the ECG. This approach not infrequently fails to identify patients who are actually suffering from STEMI, which results in an inappropriate discharge home from the ED (186). Such missed MI patients are at relatively high risk of death or complications for the next 4 to 6 weeks after ED discharge (187-192).

In a large study on this subject, Pope et al. (188) found that 889 of 10 689 patients who presented to 10 US hospital EDs with chest pain or other symptoms that suggested acute cardiac ischemia had STEMI; 19 patients (2.1%, 95% CI 1.1% to 3.1%) were discharged from the ED. Patients with STEMI were more likely not to be hospitalized if they were nonwhite (odds ratio [OR] for discharge 4.5; 95% CI 1.8 to 11.8) or had a normal or nondiagnostic ECG (OR 7.7; 95% CI 2.9 to 20.2). The risk-adjusted mortality ratio for MI patients who were not hospitalized compared with those who were hospitalized was 1.9 (95% CI 0.7 to 5.2).

6.1. Optimal Strategies for Emergency Department Triage

Class I
Hospitals should establish multidisciplinary teams (including primary care physicians, emergency medicine physicians, cardiologists, nurses, and laboratorians) to develop guideline-based, institution-specific written protocols for triaging and managing patients who are seen in the prehospital setting or present to the ED with symptoms suggestive of STEMI. (Level of Evidence: B)

The advent of highly effective, time-dependent treatment for STEMI coupled with the need to reduce healthcare costs adds further incentive for clinicians to get the right answer quickly and to reduce unnecessary admissions and length of hospital stay. Investigators have tried various diagnostic tools such as clinical decision algorithms, cardiac biomarkers, echocardiography, and myocardial perfusion imaging in an attempt to avoid missing patients with MI or unstable angina. The most successful strategies to emerge thus far are designed to identify MI patients and, when clinically appropriate, screen for unstable angina and underlying coronary artery disease. Most strategies use a combination of cardiac biomarkers, short-term observation, diagnostic imaging, and provocative stress testing. An increasing number of high-quality centers now use structured protocols, checklists, or critical pathways to screen patients with suspected MI or unstable angina (193-205). It does not appear to matter whether the institution designates itself a chest pain center. Rather, it is the multifaceted, structured approach to the problem that appears to provide clinical, cost-effective benefit (206,207). One randomized trial has confirmed the safety, efficacy, and cost-effectiveness of the structured decisionmaking approach compared with standard, unstructured care (208).

6.2. Initial Patient Evaluation

Class I
1. The delay from patient contact with the healthcare system (arrival at the ED or contact with paramedics) to initiation of fibrinolytic therapy should be less than 30 minutes. Alternatively, if PCI is chosen, the delay from patient contact with the healthcare system (typically, arrival at the ED, or contact with paramedics) to balloon inflation should be less than 90 minutes. (Level of Evidence: B)

2. The choice of initial STEMI treatment should be made by the emergency medicine physician on duty based on a predetermined, institution-specific, written protocol that is a collaborative effort of cardiologists (both those involved in coronary care unit management and interventionalists), emergency physicians, primary care physicians, nurses, and other appropriate personnel. For cases in which the initial diagnosis and treatment plan are unclear to the emergency physician or are not covered directly by the agreedupon protocol, immediate cardiology consultation is advisable. (Level of Evidence: C)

Regardless of the approach used, all patients presenting to the ED with chest discomfort or other symptoms suggestive of STEMI or unstable angina should be considered high-priority triage cases and should be evaluated and treated on the basis of a predetermined, institution-specific chest pain protocol. The protocol should include several diagnostic possibilities (Figure 9) (4). The patient should be placed on a cardiac monitor immediately, with emergency resuscitation equipment, including a defibrillator, nearby. An ECG should be performed and shown to an experienced emergency medicine physician within 10 minutes of ED arrival. If STEMI is present, the decision as to whether the patient will be treated with fibrinolytic therapy or primary PCI should be made within the next 10 minutes (Figure 7) (180). The goal for patients with STEMI should be to achieve a door-to-needle time of within 30 minutes and a door-to-balloon time of within 90 minutes (Figure 6) (155). If the initial ECG is not diagnostic, the patient remains symptomatic, and there is a high clinical suspicion for STEMI, serial ECGs at 5- to 10-minute intervals or continuous ST-segment monitoring should be performed.

Ideally, such decisions should be made by the emergency medicine physician on duty in the ED based on a predetermined, institution-specific, written protocol that has been developed with input from cardiologists (both those involved in coronary care unit management and interventionalists), emergency medicine physicians, primary care physicians, nurses, and other appropriate personnel. For non-interventional hospitals, this will usually require formal, written transfer agreements and protocols that will permit expeditious transfer of patients who require urgent mechanical revascularization to the nearest appropriate interventional facility (Figure 6) (155). The protocol should also include the level of training and certification of personnel required to accompany the patient during transfer, the minimum equipment requirements, and the type(s) of transport vehicles (e.g., standard ground ambulance, mobile intensive care unit, helicopter, or fixed-wing aircraft) that can be used on the basis of patient condition. For cases in which the initial diagnosis and treatment plan are unclear to the emergency medicine physician or are not covered directly by the agreed-upon protocol, immediate cardiology consultation is advisable.

6.2.1. History

Class I
The targeted history of STEMI patients taken in the ED should ascertain whether the patient has had prior episodes of myocardial ischemia, such as stable or unstable angina, MI, coronary bypass surgery, or PCI. Evaluation of the patient’s complaints should focus on chest discomfort, associated symptoms, sex and age-related differences in presentation, hypertension, diabetes mellitus, possibility of aortic dissection, risk of bleeding, and clinical cerebrovascular disease (amaurosis fugax, face/limb weakness or clumsiness, face/limb numbness or sensory loss, ataxia, or vertigo). (Level of Evidence: C)

The history taken in the ED must be concise and detailed enough to establish the probability of STEMI but should be obtained expeditiously so as not to delay implementation of reperfusion therapy.

Chest Discomfort. The severity of discomfort varies and is typically graded on a scale of 1 to 10, with 10 being the mostsevere pain. It is important to keep in mind that many patients will not admit having chest “pain” but will acknowledge the presence of chest “discomfort,” because of their definition of pain. The chest discomfort is often described as a crushing, vice-like constriction, a feeling equivalent to an “elephant sitting on the chest,” or heartburn. Usually, the discomfort is substernal but may originate in or radiate to areas such as the neck, jaw, interscapular area, upper extremities, and epigastrium. The duration of the discomfort, which typically lasts longer than 30 minutes, may wax and wane and may be remitting. It may be described as “indigestion in the chest” and occasionally may be relieved with belching. The possibility of precipitation of STEMI by use of illicit drugs such as cocaine should be considered.

The targeted history of patients with STEMI taken in the ED should ascertain whether the patient has had prior episodes of myocardial ischemia such as stable or unstable angina, MI, coronary bypass surgery, or PCI. Evaluation of the patient’s complaints should focus on chest discomfort, associated symptoms, sex- and age-related differences in presentation, hypertension, diabetes mellitus, possibility of aortic dissection, risk of bleeding, and clinical cerebrovascular disease (amaurosis fugax, face/limb weakness or clumsiness, face/limb numbness or sensory loss, ataxia, or vertigo).

Associated Symptoms. Other symptoms to be aware of when taking a patient’s history include nausea and vomiting. Diaphoresis associated with a pale complexion may also appear, as well as weakness or profound fatigue. Dizziness, lightheadedness, syncope, and paresthesia may occur because of pain and hyperventilation.

Hypertension. Hypertension should be assessed, because chronic, severe, poorly controlled hypertension or severe uncontrolled hypertension on presentation is a relative contraindication to fibrinolytic therapy (see Section 6.3.1.6.3.2).

Sex- and Age-Related Differences in Presentation. It has been noted in studies that women present with STEMI at an older age and later after the onset of symptoms than men (53,210). There must be an elevated index of suspicion during the evaluation of women for STEMI. Although some variation exists, when large databases of MI patients are examined, symptom profiles for STEMI by sex generally appear more similar than different between men and women (211-215). Elderly patients with STEMI are significantly less likely than younger patients to complain of chest discomfort. However, elderly patients with STEMI are more likely to complain of shortness of breath, as well as other atypical symptoms such as syncope or unexplained nausea. (181).

Diabetes Mellitus. Diabetics may have impaired angina (pain) recognition, especially in the presence of autonomic neuropathy. A diabetic may misinterpret dyspnea, nausea, vomiting, fatigue, and diaphoresis as disturbance of diabetic control. Up to 50% of diabetic individuals with type 2 diabetes for longer than 10 years will have autonomic nervous system dysfunction manifested by impaired heart rate variability. Diabetics with STEMI should be evaluated for renal dysfunction (216).

Possibility of Aortic Dissection. Severe tearing pain radiating directly to the back associated with dyspnea or syncope and without ECG changes indicative of STEMI should raise the suspicion for aortic dissection, and appropriate studies should be undertaken. Clinicians should have a heightened index of suspicion for aortic dissection in elderly hypertensive patients. However, it must be kept in mind that the dissection may extend to the pericardial sac and produce cardiac tamponade or disrupt the origin of a coronary artery.

Risk of Bleeding. Patients should be questioned about previous bleeding problems, e.g., during surgery or dental procedures, history of ulcer disease, cerebral vascular accidents, unexplained anemia, or melena. The use of antiplatelet, antithrombin, and fibrinolytic agents as part of the treatment for STEMI will exacerbate any underlying bleeding risks.

Clinical Cerebrovascular Disease. The patient with STEMI frequently has medical conditions that are risk factors for both MI and stroke. Evidence for prior episodes suggestive of clinical cerebrovascular disease should be sought. For example, the patient should be asked whether he/she has ever had symptoms of transient retinal or cerebral ischemia such as amaurosis fugax, face/limb weakness or clumsiness, face/limb numbness or sensory loss, ataxia, or vertigo. Transient ischemic attacks (TIAs) typically last less than 30 minutes, whereas symptoms that last more than 60 to 90 minutes are more likely to indicate the presence of a stroke (217). In addition, the patient should be asked whether he/she has ever had an ischemic stroke, intracerebral hemorrhage [ICH], or subarachnoid hemorrhage. A brief summary of the details for diagnosis of the different stroke subtypes is available (218). Finally, a history of cognitive decline/dementia may indicate the presence of cerebral amyloid angiopathy and increased risk of ICH, and information regarding head and facial trauma should be obtained.

6.2.2. Physical Examination

Class I
1. A physical examination should be performed to aid in the diagnosis and assessment of the extent, location, and presence of complications of STEMI. (Level of Evidence: C)

2. A brief, focused, and limited neurological examination to look for evidence of prior stroke or cognitive deficits should be performed on STEMI patients before administration of fibrinolytic therapy. (Level of Evidence: C)

A brief physical examination may promote rapid triage (Table 5), whereas a more detailed physical examination aids in the differential diagnosis and is useful for assessing the extent, location, and presence of complications of STEMI (Tables 6 and 7) (219).

Evidence of prior stroke or dementia may be suggested by the finding on examination of focal neurological or cognitive deficits (Table 6). A brief but focused examination can identify focal neurological or cognitive deficits.

6.2.2.1. Differential Diagnosis

The differential diagnosis of STEMI includes conditions that can be exacerbated by fibrinolysis and anticoagulation (Table 8). The pain of aortic dissection is typically described as searing, ripping, or tearing and frequently radiates to the back or lower extremities. The pain is worse at onset and lasts for hours. Major pulses may be absent, and a murmur of aortic regurgitation may be present. A transesophageal echocardiogram, computed tomography (CT) scan, or magnetic resonance imaging scan is useful for establishing the diagnosis of aortic dissection. Active peptic ulcer disease can be present with chest or epigastric pain, sometimes radiating posteriorly, and may be associated with syncope, hematemesis, or melena. Free subdiaphragmatic air may be seen on upright chest X-ray in perforations. Acute pericarditis may show PR-segment depression and ST-segment elevation on the ECG but without reciprocal ST-segment depression (220). Pain from pericarditis is usually pleuritic and can radiate to the shoulder and trapezius ridge and is often relieved by sitting up and leaning forward, characteristics not found in STEMI. A rub is often present. Pulmonary embolus, with or without infarction, presents with dyspnea and knifelike pleuritic pain, sometimes with hemoptysis. Pulmonary embolism can present with chest pain similar to that of STEMI. Costochondral pain is described as sharp or sticking, with associated localized tenderness. Pneumothorax may present with acute dyspnea, pleuritic pain, and differential decrease in breath sounds with hyperresonance over 1 lung field. Acute cholecystitis may mimic STEMI, and rightupper- quadrant abdominal tenderness should be sought on physical examination.

6.2.3. Electrocardiogram

Class I
1. A 12-lead ECG should be performed and shown to an experienced emergency physician within 10 minutes of ED arrival on all patients with chest discomfort (or anginal equivalent) or other symptoms suggestive of STEMI. (Level of Evidence: C)

2. If the initial ECG is not diagnostic of STEMI but the patient remains symptomatic, and there is a high clinical suspicion for STEMI, serial ECGs at 5- to 10- minute intervals or continuous 12-lead ST-segment monitoring should be performed to detect the potential development of ST elevation. (Level of Evidence: C)

3. In patients with inferior STEMI, right-sided ECG leads should be obtained to screen for ST elevation suggestive of RV infarction. (See Section 7.6.6 and the ACC/AHA/ASE 2003 Guideline Update for the Clinical Application of Echocardiography). (Level of Evidence: B)

The 12-lead ECG in the ED is at the center of the therapeutic decision pathway because of the strong evidence that ST-segment elevation identifies patients who benefit from reperfusion therapy (221). Mortality increases with the number of ECG leads showing ST elevation. Important predictors of mortality on the initial 12-lead ECG include left bundle branch block (LBBB) and anterior location of infarction (Figure 10) (222,223). Diagnostic criteria of greater than 0.1 mV in leads V1 through V4 may have reduced specificity for STEMI in patients with early repolarization. Some evidence exists to support the use of greater than or equal to 0.2 mV anteroseptal elevation as a preferable threshold for diagnosing STEMI, because a higher proportion of patients are correctly classified as having STEMI than with a threshold of greater than 0.1 mV in these leads (221).

In the absence of ST elevation, there is no evidence of benefit of fibrinolytic therapy for patients with normal ECG or nonspecific changes, and there is some suggestion of harm (including increased bleeding risk) for patients with ST-segment depression only (221,224). Notwithstanding this, fibrinolytic therapy may be appropriate when there is marked STsegment depression confined to leads V1 through V4 and accompanied by tall R waves in the right precordial leads and upright T waves indicative of a true posterior injury current and circumflex coronary occlusion. In circumstances where there is a suggestive clinical history and suggestive evidence of true posterior infarction, confirmatory data from posterior leads (i.e., V7 and V8) as well as 2-dimensional echocardiography may be especially helpful; this latter investigation has a high negative predictive value (225,226). Primary PCI is another reperfusion strategy that may be effective in patients with true posterior MI (see Section 6.3.1.6.4.2).

Initial errors in ECG interpretation can result in up to 12% of patients being categorized inappropriately, demonstrating a potential benefit of accurate computer-interpreted electrocardiography and fax transmission to an expert (227). It is less likely that STEMI is present if the upward-directed STsegment changes are concave rather than convex (228). Because lethal ventricular arrhythmias may develop abruptly in patients with STEMI, all patients should be monitored electrocardiographically on arrival in the ED. It is important to examine serial tracings approximately 5 to 10 minutes apart, or if symptoms recur, during evaluation in the ED for development of ST elevation if the initial ECG is nondiagnostic. ST elevation may also be detected by intermittent visual inspection of the oscilloscope or auditory alarms in systems with continuous ST-segment monitoring capability.

Although the Fibrinolytic Therapy Trialists’ (FTT) Collaborative Group overview indicates that patients with new or presumably new LBBB are at high risk when presenting with presumed MI, this ECG presentation is a frequent cause of delay or lack of reperfusion therapy because of the concern of the validity of the ECG criteria for MI diagnosis and the risk of therapy. This is also a situation in which direct PCI may be preferable to fibrinolytic therapy (156). It has been suggested that patients with new or presumably new LBBB coupled with a typical ischemic history be approached with a plan to rule in MI using 1 of 3 ECG criteria that provide independent diagnostic value. These consist of ST elevation greater than or equal to 0.1 mV in leads with a positive QRS, ST depression greater than or equal to 0.1 mV in V1 to V3, and ST elevation greater than or equal to 0.5 mV in leads with a negative QRS (229,230).

6.2.4. Laboratory Examinations

Class I
Laboratory examinations should be performed as part of the management of STEMI patients but should not delay the implementation of reperfusion therapy. For specific laboratory examinations, see Table 9. (Level of Evidence: C)

In addition to serum cardiac biomarkers for cardiac damage, several routine evaluations have important implications for management of patients with STEMI (Table 9). Although these studies should be undertaken when the patient is first examined, therapeutic decisions should not be delayed until results are obtained because of the crucial role of time to therapy in STEMI.

6.2.5. Biomarkers of Cardiac Damage

Class I
1. Cardiac-specific troponins should be used as the optimum biomarkers for the evaluation of patients with STEMI who have coexistent skeletal muscle injury. (Level of Evidence: C)

2. For patients with ST elevation on the 12-lead ECG and symptoms of STEMI, reperfusion therapy should be initiated as soon as possible and is not contingent on a biomarker assay. (Level of Evidence: C)

Class IIa
Serial biomarker measurements can be useful to provide supportive noninvasive evidence of reperfusion of the infarct artery after fibrinolytic therapy in patients not undergoing angiography within the first 24 hours after fibrinolytic therapy. (Level of Evidence: B)

Class III
Serial biomarker measurements should not be relied upon to diagnose reinfarction within the first 18 hours after the onset of STEMI. (Level of Evidence: C)

The nomenclature of acute coronary syndromes is illustrated in Figure 2 (8-10). The central position of the 12-lead ECG and initial triage of patients are emphasized. Serum cardiac biomarkers (creatine kinase [CK], CK-MB, cardiac-specific troponins, myoglobin) are useful for confirming the diagnosis of MI and estimating infarct size. Serum cardiac biomarkers also provide valuable prognostic informatin. For patients with ST-segment elevation, the diagnosis of STEMI is secure; initiation of reperfusion therapy should not be delayed while awaiting the results of a cardiac biomarker assay (231,232) (Table 10). Quantitative analysis of cardiac biomarker measurements provides prognostic information as well as a noninvasive assessment of the likelihood that the patient has undergone successful reperfusion when fibrinolytic therapy is administered (Figure 11) (233,234).

Because there are differences in the clinical need for biomarke in STEMI versus NSTEMI patients and differences in the characteristics of the various cardiac biomarkers, preferential use of a particular biomarker should be base on the clinical syndrome. CK-MB is found in the skeletal muscle and blood of healthy subjects; therefore, the cutoff value for an elevated CK-MB is typically set a few units above the upper end of the reference (normal) range. In contrast, because cardiac troponin I (cTnI) and cardiac troponin T (cTnT) are not normally detected in the blood of healthy people, the definition of an abnormally increased level is a value that exceeds that of 99% of a reference control group. Given the nearly absolute myocardial tissue specificity and high sensitivity for even microscopic zones of myocardial necrosis, the ACC and the European Society of Cardiology subsequently declared cardiac troponins to be the preferred biomarker for diagnosing MI (233). A single cutoff point was recommended such that an MI would be diagnosed if, as a result of myocardial ischemia, cTnI or cTnT were detected at least once within 24 hours of the index clinical event at a level exceeding the 99th percentile of the mean value measured in a normal control population (233). The superior sensitivity makes troponin the preferred marker for patients with UA/NSTEMI. In contrast, patients with STEMI are recognized on the basis of the 12-lead ECG, and in general, subsequent confirmation of MI can be ascertained by measurement of any of the available cardiac biomarkers. Occasionally, a very small infarct will be missed by CK-MB; therefore, troponin should be measured for patients suspected to have STEMI who have negative serial CK-MBs.

It should be recognized that in patients with STEMI, cTnT and cTnI may first begin to rise above the reference limit by 3 to 6 hours from the onset of ischemic symptoms. Therefore, a significant number of patients will present o the emergency room with negative biomarkers. Myoglobin, a low-molecular-weight heme protein found in cardiac and skeletal muscle, is not cardiac specific but is released more rapidly from infarcted myocardium than CK-MB and may be detected as early as 2 hours after STEMI.

In some patients, cardiac-specific troponins may not be detectable for up to 6 hours after onset of chest pain. Thus, when CK-MB, cTnI, or cTnT levels are elevated in less than 6 hours after the onset of discomfort in patients with STEMI, clinicians should suspect that an antecedent episode of unstable angina was in fact MI and the patient is exhibiting a stuttering course of occlusion and release of the infarct artery. Data from the Global Utilization of Streptokinase and TPA for Occluded Arteries (GUSTO) III Study suggest that patients with STEMI who have elevated cTnT levels and who are less than 6 hours from the onset of discomfort have an increased mortality risk (235).

CK-MB is the preferred, widely available cardiac biomarker for most patients with STEMI, for whom the need to diagnose reinfarction and noninvasively assess reperfusion is greater than the need to make the diagnosis. By mapping the time course of the rise and fall of a biomarker (typically CKMB), clinicians can detect an interruption of the progressive fall of the biomarker level to a point below the upper reference limit (Figure 11) (233,234). Re-elevation of the biomarker level is evidence of myocardial reinfarction (Figure 12). A more rapidly rising and falling biomarker such as CKMB or myoglobin is superior for diagnosing reinfarction. As a consequence of continuous release from a degenerating contractile apparatus in necrotic myocytes, elevations of cTnI may persist for 7 to 10 days after MI, and elevations of cTnT may persist for up to 10 to 14 days. The more protracted time course of kinetic release of cTnI and cTnT limits the ability of clinicians to make the diagnosis of reinfarction within several days after the index STEMI event. An algorithm illustrating the decision making process that incorporates biomarker measurements, ECG findings, clinical symptoms, and, if available, autopsy data for making the diagnosis of reinfarction is shown in Figure 12.

In addition to monitoring the patient for resolution of schemic-type chest discomfort and regression of the magnitude of ST-segment elevation on the ECG, clinicians can obtain serial measurements of serum cardiac markers to buttress the noninvasive diagnosis of reperfusion of the infarctrelated artery after fibrinolytic therapy (Figure 11) (233,234,236). An early peak of CK-MB (12 to 18 hours) suggests reperfusion. Because of its rapid-release kinetics, myoglobin is also an attractive marker for the early diagnosis of reperfusion.

CK-MB isoforms are another serum cardiac biomarker less frequently used for evaluating patients with STEMI. CK-MB exists in only 1 form in myocardial tissue but in different isoforms (or subforms) in the plasma. An absolute level of CKMB2 greater than 1 U/L or a ratio of CK-MB2 to CK-MB1 of 1.5 has improved sensitivity and specificity for diagnosis of MI within the first 6 hours compared with conventional assays for CK-MB (237).

6.2.5.1. Bedside Testing for Serum Cardiac Biomarkers

Class I
1. Although handheld bedside (point-of-care) assays may be used for a qualitative assessment of the presence of an elevated level of a serum cardiac biomarker, subsequent measurements of cardiac biomarker levels should be done with a quantitative test. (Level of Evidence: B)

2. For patients with ST elevation on the 12-lead ECG and symptoms of STEMI, reperfusion therapy should be initiated as soon as possible and is not contingent on a bedside biomarker assay. (Level of Evidence: C)

Handheld rapid bedside assays are clinically available for measuring cTnI, cTnT, myoglobin, and CK-MB, but in general, bedside assays are less sensitive and less precise than quantitative assays. Small desktop rapid analyzers are also available for the same purpose. A rapid, high-voltage electrophoretic system is available for measuring CK-MB isoforms. Monitoring the timing of the appearance of a positive bedside assay result may provide clinicians with a tool for a semiquantitative estimate of a serum cardiac biomarker level at the patient’s bedside (238). A positive bedside test should be confirmed by a conventional quantitative test. However, reperfusion therapy should not be delayed while one awaits the results of a quantitative assay.

6.2.6. Imaging

Class I
1. Patients with STEMI should have a portable chest X-ray, but this should not delay implementation of reperfusion therapy (unless a potential contraindication is suspected, such as aortic dissection). (Level of Evidence: C)

2. Imaging studies such as a high-quality portable cest X-ray, transthoracic and/or transesophageal echocardiography, and a contrast chest CT scan or magnetic resonance imaging scan should be used for differentiating STEMI from aortic dissection in patients for whom this distinction is initially unclear. (Level of Evidence: B)

Class IIa
Portable echocardiography is reasonable to clarify the diagnosis of STEMI and allow risk stratification of patients with chest pain who present to the ED, especially if the diagnosis of STEMI is confounded by LBBB or pacing or if there is suspicion of posterior STEMI with anterior ST depressions. (See Section 7.6.7, Mechanical Causes of Heart Failure/Low-Output Syndrome.) (Level of Evidence: B)

Class III
Single-photon emission CT (SPECT) radionuclide imaging should not be performed to diagnose STEMI in patients for whom the diagnosis of STEMI is evident on the ECG. (Level of Evidence: B)

Various forms of imaging are often used to evaluate patients with symptoms that are suggestive of MI or acute coronary syndrome. Cardiac imaging can be of value in further determining the cause of chest discomfort in patients suspected of having an acute MI or unstable angina but whose initial ECG is normal or nondiagnostic. The 2 most studied techniques thus far have been echocardiography and radionuclide imaging.

Bedside echocardiography is useful for diagnosis and risk stratification of chest pain patients in the ED (226). A highquality portable chest X-ray, transthoracic and/or transesophageal echocardiography, and a contrast chest CT scan can be useful for differentiating acute MI from aortic dissection in patients for whom this distinction is clinically unclear. SPECT radionuclide imaging at rest is not routinely indicated to establish the diagnosis of MI in patients with STEMI, although it can provide valuable, accurate diagnostic and prognostic information in patients who present to the ED with symptoms suggestive of acute cardiac ischemia and a normal or nondiagnostic ECG (239). During the recuperative phase of hospitalization for STEMI, SPECT imaging can be used to study myocardial perfusion and to look for segmental abnormalities of LV wall motion.

6.2.7. Global Risk Assessment Tools

Global risk assessment provides an opportunity to integrate various patient characteristics into a single score that can convey an overall estimate of a patient’s prognosis over a given period of time. Beyond being informative about prognosis, the general value of these risk assessment tools is that they can influence clinical strategies. In general, the risk of the intervention should be commensurate with the underlying risk of the patient without the intervention and the expected benefit of the intervention. That is, a high-risk intervention should usually not be used for a very low-risk patient. The expected increase in risk associated with the intervention would very likely outweigh the expected benefit.

Several risk assessment tools have been proposed for patients with STEMI (240-243). One such tool uses clinical and ECG characteristics to predict risk of mortality for a patient if and if not treated with fibrinolytic therapy, as well as the risk of intracranial hemorrhage and major bleeding. This decision aid suggests that some patients with small infarctions may not have a substantial benefit from fibrinolytic therapy, particularly those who may have a risk factor for bleeding. These estimates are based on trials and registries. The use of this aid in clinical practice did not increase the use of fibrinolytic therapy overall (244). Whether the widespread application of these tools can improve decision making is not clear. Nevertheless, they provide estimates of risk that may be useful in the tailoring of therapy for individual patients. In general, however, patients who present with STEMI require evaluation for rapid reperfusion therapy and treatment with aspirin, beta-blockers, and ACE inhibitors. Nevertheless, any patient with a risk from the intervention that exceeds their STEMI risk reduction will, on average, do better without that treatment. This group will generally include patients with a higher risk from the intervention or a lower absolute risk reduction (generally because of a low absolute STEMI risk). This issue may be particularly important for younger patients, who tend to have a lower absolute risk of mortality (245), and for the elderly, who tend to have a higher risk from interventions, particularly with respect to fibrinolytic therapy (246). Precise estimates of risks and benefits are useful because the low STEMI risk in younger patients is often accompanied by a lower risk of interventions. In contrast, in the elderly, the higher intervention risk is accompanied by a higher STEMI risk (and thus a larger absolute reduction in risk with the intervention) (247).

The use of any risk assessment tool should not contribute to any delay in providing the time-sensitive assessment and treatment strategies that patients with STEMI require. Further research is necessary to determine how these tools may best contribute to optimizing patient outcomes.

6.3. Management

6.3.1. Routine Measures

6.3.1.1. Oxygen

Class I
Supplemental oxygen should be administered to patients with arterial oxygen desaturation (SaO₂ less than 90%). (Level of Evidence: B)

Class IIa
It is reasonable to administer supplemental oxygen to all patients with uncomplicated STEMI during the first 6 hours. (Level of Evidence: C)

It has become universal practice to administer oxygen, usually by nasal prongs, to virtually all patients suspected of having acute ischemic-type chest discomfort, although it is not known whether this therapy limits myocardial damage or reduces morbidity or mortality. If oxygen saturation monitoring is used, therapy with supplemental oxygen is indicated if the saturation is less than 90%. Experimental results indicate that breathing oxygen may limit ischemic myocardial injury (248), and there is evidence that oxygen administration reduces ST-segment elevation (249). The rationale for use of oxygen is based on the observation that even with uncomplicated MI, some patients are modestly hypoxemic initially, presumably because of ventilation-perfusion mismatch and excessive lung water (250).

In patients with severe congestive heart failure, pulmonary edema, or a mechanical complication of STEMI, significant hypoxemia may not be corrected with supplemental oxygen alone. Continuous positive-pressure breathing or endotracheal intubation and mechanical ventilation may be required in such cases (251).

For patients without complications, excess administration of oxygen can lead to systemic vasoconstriction, and high flow rates can be harmful to patients with chronic obstructive airway disease. In the absence of compelling evidence for established benefit in uncomplicated cases, and in view of its expense, there appears to be little justification for continuing its routine use beyond 6 hours.

6.3.1.2. Nitroglycerin

Class I
1. Patients with ongoing ischemic discomfort should receive sublingual nitroglycerin (0.4 mg) every 5 minutes for a total of 3 doses, after which an assessment should be made about the need for intravenous nitroglycerin. (Level of Evidence: C)

2. Intravenous nitroglycerin is indicated for relief of ongoing ischemic discomfort, control of hypertension, or management of pulmonary congestion. (Level of Evidence: C)

Class III
1. Nitrates should not be administered to patients with systolic blood pressure less than 90 mm Hg or greater than or equal to 30 mm Hg below baseline, severe bradycardia (less than 50 beats per minute [bpm]), tachycardia (more than 100 bpm), or suspected RV infarction. (Level of Evidence: C)

2. Nitrates should not be administered to patients who have received a phosphodiesterase inhibitor for erectile dysfunction within the last 24 hours (48 hours for tadalafil). (Level of Evidence: B)

The physiological effects of nitrates include reducing preload and afterload through peripheral arterial and venous dilation, relaxation of epicardial coronary arteries to improve coronary flow, and dilation of collateral vessels, potentially creating a more favorable subendocardial to epicardial flow ratio (252-254). Vasodilation of the coronary arteries, especially at or adjacent to sites of recent plaque disruption, may be particularly beneficial for the patient with acute infarction. Nitrate-induced vasodilatation may also have particular utility in those rare patients with coronary spasm presenting as STEMI.

Clinical trial results have suggested only a modest benefit from nitroglycerin used acutely in STEMI and continued subsequently. A pooled analysis of more than 80 000 patients treated with nitrate-like preparations intravenously or orally in 22 trials revealed a mortality rate of 7.7% in the control group, which was reduced to 7.4% in the nitrate group. These data are consistent with a possible small treatment effect of nitrates on mortality such that 3 to 4 fewer deaths would occur for every 1000 patients treated (152).

Nitroglycerin may be administered to relieve ischemic pain and is clearly indicated as a vasodilator in patients with STEMI associated with LV failure. Nitrates in all forms should be avoided in patients with initial systolic blood pressures less than 90 mm Hg or greater than or equal to 30 mm Hg below baseline, marked bradycardia or tachycardia (256), or known or suspected RV infarction. Patients with RV infarction are especially dependent on adequate RV preload to maintain cardiac output and may experience profound hypotension during administration of nitrates (257). Phosphodiesterase inhibitors potentiate the hypotensive effects of nitrates because of their mechanism of action in releasing nitric oxide and increasing cyclic guanosine monophosphate (258). Therefore, it is useful clinical practice to ascertain whether such agents have been used, and nitrates should not be administered to patients who have received a phosphodiesterase inhibitor for erectile dysfunction in the prior 24 hours (48 hours for tadalafil).

Nitroglycerin is commonly given sublingually at doses of 0.4 mg when patients present with STEMI. Arterial pressure may decline precipitously because of limited control of the initial dose and rate of absorption. An intravenous infusion of nitroglycerin allows clinicians to titrate the therapy in response to the patient’s blood pressure. A useful intravenous nitroglycerin regimen employs an initial infusion rate of 5 to 10 mcg per minute with increases of 5 to 20 mcg per minute until symptoms are relieved or mean arterial blood pressure is reduced by 10% of its baseline level in normotensive patients and by up to 30% for hypertensive patients, but in no case below a systolic pressure of 90 mm Hg or a drop greater than 30 mm Hg below baseline. In view of their marginal treatment benefits, nitrates should not be used if hypotension limits the administration of beta-blockers, which have more powerful salutary effects.

6.3.1.3. Analgesia

Class I
Morphine sulfate (2 to 4 mg IV with increments of 2 to 8 mg IV repeated at 5- to 15-minute intervals) is the analgesic of choice for management of pain associated with STEMI. (Level of Evidence: C)

Pain relief is an important element in the early management of the patient with STEMI. There is a tendency to underdose patients with STEMI because of the desire to assess the response to anti-ischemic or reperfusion therapy. This should be avoided, because patients with STEMI have a hyperadrenergic state particularly early after the onset of coronary occlusion. Conversely, it should not be assumed that resolution of discomfort after administration of analgesics indicates reperfusion has occurred (see Section 6.3.1.6.3.7 for further discussion). Pain, which is commonly severe in the acute phase of the event, contributes to increased sympathetic activity.

Pain management should be directed toward acute relief of symptoms of ongoing myocardial ischemia and necrosis and toward general relief of anxiety and apprehension, the latter of which can heighten pain perception. Surges of catecholamines have been implicated as having a role in plaque fissuring and thrombus propagation and in reducing the threshold for ventricular fibrillation (259). Because the pain of STEMI is related to ongoing ischemia, interventions that affect the oxygen supply-demand relationship (i.e., by either increasing supply or decreasing demand) may lessen the pain of STEMI (260).

Control of cardiac pain is typically accomplished with a combination of nitrates, opiate analgesic agents, oxygen, and beta-adrenergic blockers. Treatment with these agents extends from the ED to the critical care unit. An important consideration when using intravenous nitrates is not to lower blood pressure to a level that would preclude adequate dosage of morphine sulfate for pain control. Morphine sulfate remains the analgesic agent of choice for management of pain associated with STEMI, except in documented cases of morphine sensitivity. The dose required for adequate pain relief varies in relation to age and body size, as well as blood pressure and heart rate. Anxiety reduction secondary to morphine administration reduces the patient’s restlessness and the activity of the autonomic nervous system, with a consequent reduction of the heart’s metabolic demands. Morphine administration for patients with pulmonary edema is clearly beneficial and may promote peripheral arterial and venous dilation, reducing the work of breathing and slowing the heart rate secondary to combined withdrawal of sympathetic tone and augmentation of vagal tone (259,260).

Side effects of morphine administration such as hypotension can be minimized by keeping the patient supine and elevating the lower extremities if systolic pressure goes below 100 mmHg systolic, assuming pulmonary edema is not present. The concomitant use of atropine in 0.5- to 1.5-mg doses intravenously may be helpful in reducing the excessive vagomimetic effects of morphine if significant bradycardia or hypotension occurs. Although respiratory depression is relatively uncommon, patients’ respirations should be monitored, particularly as their cardiovascular status improves. The narcotic reversing agent naloxone, 0.1 to 0.2 mg intravenously, can be given initially if indicated and repeated after 15 minutes if necessary. Nausea and vomiting as potential side effects of large doses of morphine may be treated with a phenothiazine (260).

See “Hospital Management” (Section 7.2.4) for additional discussion of analgesia.

6.3.1.4. Aspirin

Class I
Aspirin should be chewed by patients who have not taken aspirin before presentation with STEMI. The initial dose should be: 162 mg (Level of Evidence: A) to 325 mg (Level of Evidence: C). Although some trials have used enteric-coated aspirin for initial dosing, more rapid buccal absorption occurs with non–enteric-coated aspirin formulations.

At a dose of 162 mg or more, aspirin produces a rapid clinical antithrombotic effect caused by immediate and near-total inhibition of thromboxane A2 production. The Second International Study of Infarct Survival (ISIS-2) has shown conclusively the efficacy of aspirin alone for treatment of evolving acute MI, with an absolute risk difference in 35-day mortality of 2.4% (relative risk reduction [RRR] 23%) (261). When aspirin was combined with streptokinase, the absolute risk difference in mortality was 5.2% (RRR 42%). A metaanalysis demonstrated that aspirin reduced coronary reocclusion and recurrent ischemic events after fibrinolytic therapy with either streptokinase or alteplase (262). Accordingly, aspirin now forms part of the early management of all patients with suspected STEMI and should be given promptly, certainly within the first 24 hours, at a dose between 162 and 325 mg and continued indefinitely at a daily dose of 75 to 162 mg (263). Although some trials have used entericcoated aspirin for initial dosing, more rapid buccal absorption occurs with non–enteric-coated formulations (264).

Unlike fibrinolytic agents, there is little evidence for a time-dependent effect of aspirin on early mortality. However, data do support the contention that a chewable aspirin is absorbed more quickly than one swallowed in the early hours after infarction, particularly after opiate therapy. The use of aspirin is contraindicated in those with a hypersensitivity to salicylate. Aspirin suppositories (300 mg) can be used safely and are the recommended route of administration for patients with severe nausea and vomiting or known upper-gastrointestinal disorders. In patients with true aspirin allergy (hives, nasal polyps, bronchospasm, or anaphylaxis), clopidogrel or ticlopidine may be substituted.

6.3.1.5. Beta-Blockers

Class I
Oral beta-blocker therapy should be administered promptly to those patients without a contraindication, irrespective of concomitant fibrinolytic therapy or performance of primary PCI. (Level of Evidence: A)

Class IIa
It is reasonable to administer IV beta-blockers promptly to STEMI patients without contra-indications, especially if a tachyarrhythmia or hypertension is present. (Level of Evidence: B)

During the first few hours after the onset of STEMI, betablocking agents may diminish myocardial oxygen demand by reducing heart rate, systemic arterial pressure, and myocardial contractility. In addition, prolongation of diastole caused by a reduction in heart rate may augment perfusion to ischemic myocardium, particularly the subendocardium. As a result, immediate beta-blocker therapy appears to reduce 1) the magnitude of infarction and incidence of associated complications in subjects not receiving concomitant fibrinolytic therapy, 2) the rate of reinfarction in patients receiving fibrinolytic therapy, and 3) the frequency of life-threatening ventricular tachyarrhythmias.

In patients not receiving fibrinolytic therapy, intravenously administered beta-blocking agents exert a modestly favorable influence on infarct size (265). Large early trials suggested a mortality benefit as well. In ISIS-1 (266), more than 16 000 patients with suspected acute MI were enrolled within 12 hours of onset of symptoms; immediate atenolol, 5 to 10 mg IV, followed by oral atenolol, 100 mg daily, reduced 7-day mortality from 4.3% to 3.7% (p less than 0.02; 6 lives saved per 1000 treated). The mortality difference between those receiving and not receiving atenolol was evident by the end of day 1 and was sustained subsequently. In the Metoprolol In Acute Myocardial Infarction (MIAMI) trial (267), more than 5700 subjects with evolving MI were randomly assigned to receive placebo or metoprolol, up to 15 mg IV in 3 divided doses followed by 50 mg orally every 6 hours for 48 hours and then 100 mg twice per day thereafter. Fifteen-day mortality was reduced with metoprolol from 4.9% to 4.3%. As in ISIS-1, the mortality difference between those given placebo and those receiving metoprolol was evident by the end of day 1, after which it was sustained.

In subjects receiving concomitant fibrinolytic therapy, intravenously administered beta-blocking drugs diminish the incidence of subsequent nonfatal reinfarction and recurrent ischemia. In addition, they may reduce mortality if given particularly early (i.e., within 2 hours) after onset of symptoms. In the Thrombolysis In Myocardial Infarction Phase II (TIMI-II) trial (268), in which all patients received IV alteplase, those randomly assigned to receive metoprolol, 15 mg IV, followed by oral metoprolol, 50 mg twice per day for 1 day and then 100 mg twice per day thereafter, had a diminished incidence of subsequent nonfatal reinfarction and recurrent ischemia compared with those begun on oral metoprolol 6 days after the acute event. Among those treated especially early (i.e., within 2 hours of symptom onset), the composite end point, death or reinfarction, occurred less often in those given immediate IV metoprolol than in those who did not receive it.

The benefits of routine early IV use of beta-blockers in the fibrinolytic era have been challenged by 2 later randomized trials of IV beta-blockade (269,270) and by a post hoc analysis of the use of atenolol in the GUSTO-I trial (271). A subsequent systematic review of early beta-blocker therapy in STEMI found no significant reduction in mortality (67). Therefore, data on the early use of intravenous beta-blockade in STEMI are inconclusive, and patterns of use vary.

Beta-blockers should not be administered to patients with STEMI precipitated by cocaine use because of the risk of exacerbating coronary spasm (272). If IV beta-blockade induces an untoward effect, such as atrioventricular (AV) block, excessive bradycardia, or hypotension, the condition is quickly reversed by infusion of a beta-adrenergic agonist (i.e., isoproterenol 1 to 5 mcg/min). The presence of moderate LV failure early in the course of STEMI should preclude the use of early IV beta-blockade until the heart failure has been compensated but is a strong indication for the oral use of beta-blockade before discharge from the hospital.

The following are relative contraindications to beta-blocker therapy: heart rate less than 60 bpm, systolic arterial pressure less than 100 mm Hg, moderate or severe LV failure, signs of peripheral hypoperfusion, shock, PR interval greater than 0.24 second, second- or third-degree AV block, active asthma, or reactive airway disease.

Randomized trials of beta-blocker therapy in patients with STEMI undergoing PCI without fibrinolytic therapy have not been performed. However, it seems reasonable pending further information to extrapolate data from those receiving another form of revascularization, fibrinolytic therapy, to the PCI population. The more contemporary CAPRICORN (Carvedilol Post-infarct Survival Controlled Evaluation) trial (273), which includes patients undergoing either form of revascularization, confirms the benefits of beta-blocker therapy in patients with transient or sustained postinfarction LV dysfunction.

6.3.1.6. Reperfusion

6.3.1.6.1. General Concepts

Class I
All STEMI patients should undergo rapid evaluation for reperfusion therapy and have a reperfusion strategy implemented promptly after contact with the medical system. (Level of Evidence: A)

Although rapid spontaneous reperfusion of the infarct artery may occur, in the majority of patients there is persistent occlusion of the infarct artery in the first 6 to 12 hours while the affected myocardial zone is undergoing necrosis. Prompt and complete restoration of flow in the infarct artery can be achieved by pharmacological means (fibrinolysis), PCI (balloon angioplasty with or without deployment of an intracoronary stent under the support of pharmacological measures to prevent thrombosis), or surgical measures (Figure 3) (24-40). Despite the extensive improvement in intraoperative preservation with cardioplegia and hypothermia and in numerous surgical techniques, it is not logistically possible to provide surgical reperfusion in a timely fashion, and therefore patients with STEMI who are candidates for reperfusion routinely receive either fibrinolysis or a catheter-based treatment.

Evidence exists that expeditious restoration of flow in the obstructed infarct artery after the onset of symptoms in patients with STEMI is a key determinant of short- and longterm outcomes regardless of whether reperfusion is accomplished by fibrinolysis or PCI (24,274,275). As discussed previously (Section 4.1), efforts should be made to shorten the time from recognition of symptoms by the patient to contact with the medical system. All healthcare providers caring for patients with STEMI from the point of entry into the medical system must recognize the need for rapid triage and implementation of care in a fashion analogous to the handling of trauma patients. When considering recommendations for timely reperfusion of patients with STEMI, the Writing Committee reviewed data from clinical trials, focusing particular attention on enrollment criteria for selection of patients for randomization, actual times reported in the trial report rather than simply the allowable window specified in the trial protocol, treatment effect of the reperfusion strategy on individual components of a composite primary end point (e.g., mortality, recurrent nonfatal infarction), ancillary therapies (e.g., antithrombin and antiplatelet agents), and the interface between fibrinolysis and referral for angiography and revascularization. When available, data from registries were also reviewed to assess the generalizability of observations from clinical trials of reperfusion to routine practice. Despite the wealth of reports on reperfusion for STEMI, it is not possible to produce a simple algorithm given the heterogeneity of patient profiles and availability of resources in various clinical settings at various times of day. This section introduces the recommendations for an aggressive attempt to minimize the time from entry into the medical system to implementation of a reperfusion strategy using the concept of medical system goals. More detailed discussion of these goals and the issues to be considered in selecting the type of reperfusion therapy may be found in Section 6.3.1.6.2, followed by a discussion of available resources in Section 6.3.1.6.2.1.

The medical system goal is to facilitate rapid recognition and treatment of patients with STEMI such that door-to-needle (or medical contact–to-needle) time for initiation of fibrinolytic therapy can be achieved within 30 minutes or that door-to-balloon (or medical contact–to-balloon) time for PCI can be kept under 90 minutes. These goals may not be relevant for patients with an appropriate reason for delay, such as uncertainty about the diagnosis (particularly for the use of fibrinolytic therapy), need for evaluation and treatment of other life-threatening conditions (e.g., respiratory failure), or delays associated with the patient’s informed choice to have more time to consider the decision. In the absence of such types of circumstances, the emphasis is on having a system in place such that when a patient with STEMI presents for medical care, reperfusion therapy can be provided as soon as possible within these time periods. Because there is not considered to be a threshold effect for the benefit of shorter timesto reperfusion, these goals should not be understood as “ideal” times but rather the longest times that should be considered acceptable. Systems that are able to achieve even more rapid times for patients should be encouraged. Also, this goal should not be perceived as an average performance standard but as a goal that an early treatment system in every hospital should seek for every appropriate patient.

A critically important goal of reperfusion is to restore flow in the infarct artery as quickly and as completely as possible, but the ultimate goal of reperfusion in STEMI is to improve myocardial perfusion in the infarct zone. Despite adequate restoration of flow in the epicardial infarct artery, perfusion of the infarct zone may still be compromised by a combination of microvascular damage and reperfusion injury (276-278). Microvascular damage occurs as a consequence of downstream embolization of platelet microemboli and thrombi followed by the release of substances from activated platelets that promote occlusion or spasm in the microvasculature. Reperfusion injury results in cellular edema, free radical formation, calcium overload, and acceleration of the apoptotic process. Cytokine activation in the infarct zone leads to neutrophil accumulation and inflammatory mediators that contribute to tissue injury.

Thus, construction of an ideal reperfusion regimen in patients with STEMI not only should focus on the primary means of restoring flow in the epicardial infarct artery (pharmacological or catheter-based) but should also include adjunctive and ancillary treatments that minimize the amount of microvascular damage and protect the jeopardized myocardial infarct zone that contains cells in various stages of ischemia, necrosis, and apoptosis (279,280). The Writing Committee endorses further research to identify the optimum strategies for achieving these goals.

6.3.1.6.2. Selection Of Reperfusion Strategy

The literature provides very strong evidence that among patients with suspected STEMI and without contraindications, the prompt use of reperfusion therapy is associated with improved survival (156). Despite such strong evidence, studies continue to indicate that reperfusion therapy is underutilized and often not administered soon after presentation (281-283). Indecision about the choice of reperfusion therapy should not deter physicians from using these strategies or delay them in administering therapy.

There is controversy about which form of reperfusion therapy is superior in various clinical settings. Part of the uncertainty derives from the continual introduction of new agents, devices, and strategies, which quickly make previous studies less relevant to contemporary practice. With pharmacological reperfusion therapies, there are new agents, dosing regimens, adjunctive treatments, and combined strategies with procedures that are in a continual process of refinement and evaluation. Similarly, with catheter-based approaches, there are new devices, adjunctive therapies, technologies, and combined strategies with medications that are being introduced and evaluated. As a result, the evidence base regarding the best approach to reperfusion therapy is quite dynamic.

Several issues should be considered in selecting the type of reperfusion therapy, as discussed below.

Time From Onset of Symptoms. Time from onset of symptoms to fibrinolytic therapy is an important predictor of MI size and patient outcome (284). The efficacy of fibrinolytic agents in lysing thrombus diminishes with the passage of time (279). Fibrinolytic therapy administered within the first 2 hours (especially the first hour) can occasionally abort MI and dramatically reduces mortality (Figure 13) (156,159). The National Heart Attack Alert Working Group (179) recommends that EDs strive to achieve a 30-minute door-toneedle time to minimize treatment delays. Prehospital fibrinolysis reduces treatment delays by up to 1 hour and reduces mortality by 17% (285).

The amount of myocardium at risk, presence of collateral blood flow, and duration of coronary occlusion are major determinants of myocardial infarct size (286-289). In animal models (18), occlusions persisting greater than 30 minutes produce myonecrosis. Reperfusion at 90 minutes salvages approximately half of the myocardium at risk. Myocardial salvage is minimal after 4 to 6 hours of ischemia unless ischemic preconditioning and/or collateral flow have modified the wave front of necrosis.

A time-dependent decrease in efficacy of fibrinolytic therapy may also contribute to the higher mortality rate in patients with longer symptom duration (279). In contrast, the ability to produce a patent infarct artery is much less dependent on symptom duration in patients undergoing PCI. Several reports claim no influence of time delay on mortality rates when PCI is performed after 2 to 3 hours of symptom duration (290,291). One study suggests that time to PCI is only important for patients presenting with shock (292). Another showed that time was associated with outcome in higher-risk but not lower-risk patients (293). Conversely, others have reported increasing mortality rates with increasing door-to-balloon times (294,295). Importantly, after adjustment for baseline characteristics, time from symptom onset to balloon inflation is significantly correlated with 1- year mortality in patients undergoing primary PCI for STEMI (relative risk [RR] equals 1.08 for each 30 minute delay from symptom onset to balloon inflation, p equals 0.04) (275,275a). Interestingly, although the CAPTIM (173) and PRAGUE-2 (177) studies reached different conclusions about the overall superiority of PCI over fibrinolysis, important observations were made in the subset of patients presenting very early after the onset of symptoms. In the subset of patients presenting within 3 hours of the onset of symptoms in PRAGUE-2, mortality was equivalent in those treated with streptokinase and those transferred with PCI (177). Patients treated within 2 hours of symptom onset in CAPTIM had improved outcomes with prehospital tissue plasminogen activator (tPA) versus transfer for PCI (176). (See Section 6.3.1.6.2.1.)

It is also possible that time-to-treatment analyses have been confounded by other variables (293, 296). First, higherrisk patients report later to the hospital and may respond better to PCI than to fibrinolytic agents. Second, shorter doorto- balloon times may be a surrogate for better quality of care and adherence to treatment guidelines. The Task Force on the Management of Acute Myocardial Infarction of the European Society of Cardiology (297) and this Committee both recommend a target medical contact– or door-to-balloon time of less than 90 minutes.

Risk of STEMI. Several models have been developed that assist clinicians in estimating the risk of mortality in patients with STEMI (240-242,298,299). Although these models vary somewhat in the factors loaded into the risk prediction tool and also vary with respect to statistical measures of their discriminative power (e.g., C statistic), all the models provide clinicians with a means to assess the continuum of risk from STEMI. None of the models have been tested prospectively by randomizing patients to a reperfusion strategy based on estimated mortality at presentation. Retrospective analyses do suggest that the absolute difference in mortality at 30 days between PCI and fibrinolysis increases in favor of PCI as the estimated risk of mortality with fibrinolysis increases (300). Conversely, as the estimated mortality benefit with fibrinolysis decreases, the absolute mortality benefit of PCI decreases, with equipoise appearing (i.e., similar 30-day mortality rates) when the estimated mortality with fibrinolysis is approximately 2% to 3% (300).

When the estimated mortality with fibrinolysis is extremely high, as is the case in patients with cardiogenic shock, compelling evidence exists that favors a PCI strategy. The SHOCK trial (SHould we emergently revascularize Occluded Coronaries for cardiogenic shocK?) demonstrated that patients with cardiogenic shock have a better 1-year survival if they have undergone early coronary revascularization (184). At 1 year, patients in the early revascularization group had a mortality rate of 53% compared with 66% for the group that had initial medical stabilization followed by no or late revascularization (184,301). Observational data from NRMI suggest superiority of PCI over fibrinolysis for patients with Killip class greater than or equal to II (302).

Risk of Bleeding. Choice of reperfusion therapy is also affected by the patient’s risk of bleeding. When both types of reperfusion are available, the higher the patient’s risk of bleeding with fibrinolytic therapy, the more strongly the decision should favor PCI. If PCI is unavailable, then the
benefit of pharmacological reperfusion therapy should be balanced against the risk. A decision analysis suggested that fibrinolytic therapy should be favored against no reperfusion treatment until the risk of a life-threatening bleed exceeds 4% in older patients who have a risk profile similar to those in the classic randomized trials of fibrinolytic therapy (247). Risk scores for bleeding after fibrinolytic therapy allow for the calculation of this risk (246). Because they are derived from less restricted populations, the scores that are most generalizable are those derived from observational studies (246).

Time Required for Transport to Skilled PCI Laboratory. The availability of interventional cardiology facilities is a key determinant of whether PCI can be provided. For facilities that can offer PCI, the literature suggests that this approach is superior to pharmacological reperfusion (303). The trials comparing pharmacological and PCI strategies, however, were conducted before the advent of more recent pharmacological and PCI strategies. When a composite end point of death, nonfatal recurrent MI, or stroke is analyzed, much of the superiority of a PCI strategy is driven by a reduction in the rate of nonfatal recurrent MI (Figure 14) (40). The rate of nonfatal recurrent MI can be influenced both by the adjunctive therapy used (Figure 3) (24-40) and by the proportion of patients who are referred for PCI when the initial attempt at fibrinolysis fails or myocardial ischemia recurs after initially successful pharmacological reperfusion (Figure 14) (155).

The experience and location of the PCI laboratory also plays a role in the choice of therapy. The trials were performed in centers with highly experienced teams, and their results may not be generalizable to all PCI laboratories throughout the country. Not all laboratories can provide prompt, high-quality primary PCI. Even centers with interventional cardiology facilities may not be able to provide the staffing required for 24-hour coverage of the catheterization laboratory. Despite staffing availability, the volume of cases in the laboratory may be insufficient for the team to acquire and maintain skills required for rapid PCI reperfusion strategies. A study from NRMI investigated the effect of volume on the outcomes of patients treated with PCI versus pharmacological reperfusion strategies (303). They studied 446 acute-care hospitals, with 112 classified as low-volume (fewer than or equal to 16 procedures), 223 as intermediatevolume (17 to 48 procedures), and 111 as high-volume (49 or more procedures) based on their annual primary angioplasty volume. They reported that patients hospitalized at intermediate- and high-volume centers had lower mortality with PCI reperfusion, whereas in the low-volume centers, there was no significant difference between the 2 reperfusion strategies. In another article from the NRMI investigators, the volume of primary PCI procedures, but not pharmacological treatment, was inversely associated with the mortality rate for patients with STEMI (304).

A decision must be made when a STEMI patient presents to a center without interventional cardiology facilities. Fibrinolytic therapy can generally be provided sooner than primary PCI (Figure 7) (180). As the time delay for performing PCI increases, the mortality benefit associated with expeditiously performed primary PCI over fibrinolysis decreases (305). Compared with a fibrin-specific lytic agent, a PCI strategy may not reduce mortality when a delay greater than 60 minutes is anticipated versus immediate administration of a lytic (Figure 15) (305).

The balance of risk/benefit between the transfer of patients for PCI and more immediate treatment with fibrinolytic therapy remains uncertain. The DANAMI-2 trial (DANish trial in Acute Myocardial Infarction), conducted in Denmark, found that patients treated at facilities without interventional cardiology capabilities had better composite outcomes with transfer for PCI within 2 hours of presentation than with pharmacological reperfusion treatment at the local hospital (306). Whether these results could be replicated elsewhere is not known. An alternative to transfer is for hospitals without on-site cardiac surgery to develop the capability to provide primary mechanical reperfusion therapy. A study by Aversano and colleagues with 11 hospitals in Massachusetts and Maryland suggested that this approach may improve outcomes (307). It can be expected, however, that only a limited number of hospitals could develop such a program, and it has yet to be determined whether a certain volume of cases would be necessary to maintain the effectiveness of the service. The economic implications of expansion of the number of PCI-capable centers that are able to maintain an inventory of the necessary catheters and other devices and provide 24-hour coverage, 7 days per week, deserve further evaluation from the perspectives of individual institutions and the global healthcare delivery system. See additional discussion in Section 6.3.1.6.2.1.

Given the current literature, it is not possible to say definitively that a particular reperfusion approach is superior for all patients, in all clinical settings, at all times of day (173,176,177) (Danchin N; oral presentation, American Heart Association 2003 Annual Scientific Sessions, Orlando, FL, November 2003). The main point is that some type of reperfusion therapy should be selected for all appropriate patients with suspected STEMI. The appropriate and timely use of some reperfusion therapy is likely more important than the choice of therapy, given the current literature and the expanding array of options. Clinical circumstances in which fibrinolytic therapy is generally preferred or an invasive strategy is generally preferred are shown in Table 11.

6.3.1.6.2.1. Available Resources

Class I
STEMI patients presenting to a facility without the capability for expert, prompt intervention with primary PCI within 90 minutes of first medical contact should undergo fibrinolysis unless contraindicated. (Level of Evidence: A)

The preferred reperfusion therapy for STEMI must take into account the location of the patient, the response time and expertise of the paramedical/ambulance personnel, their relationship to the regional healthcare facility(s), and the availability, capability, and expertise of the medical personnel at the facility. The most recent NRMI data continue to support advantages of primary PCI versus fibrinolysis in high-PCI–volume hospitals but not among those institutions with low volume (fewer than or equal to 16 procedures per year) (303). Approximately 20% of US hospitals have cardiac catheterization laboratories; and less than that number have the capacity for primary PCI. The C-PORT study (Atlantic Cardiovascular Patient Outcomes Research Team), which randomized 451 fibrinolysis-eligible patients with STEMI treated in 11 community hospitals with diagnostic catheterization but not onsite PCI facilities, is of interest. Patients were randomized within 12 hours of symptom onset to an accelerated alteplase regimen (median door-to-lytic time was 46 minutes) versus primary PCI (median door-to-balloon time 101.5 minutes). At 6 months, the incidence of death, re-MI, and stroke was 12.4% for PCI and 19.9% for fibrinolytic therapy (p equals 0.03). Because only 18% of the intended sample size was actually enrolled, this study is significantly underpowered, and its conclusion can only be hypothesis-generating rather than definitive (307). Importantly, most C-PORT patients were randomized between 0800 and 1600 hours, an experience consistent with NRMI data. The NRMI report also demonstrated a substantially longer door-to-balloon time when patients with STEMI undergo direct PCI outside of daylight hours (308). The Zwolle group evaluated 1702 consecutive patients and found that the 47% of patients who presented outside “routine duty hours” (i.e., 1800 to 0800 hours) had a higher rate of both PCI failure and 30-day mortality than those within the 0800 to 1800 period (6.9% and 4.2% versus 3.8% and 1.9%, respectively; p less than 0.01) (309). The reasons for these differences are unclear but could relate to both patient and process-of-care factors, including variations in both cognitive function and manual dexterity in sleep-deprived healthcare providers (308,310).

Two studies germane to STEMI care and resource utilization are noteworthy. The first, CAPTIM, a comparison of angioplasty and prehospital fibrinolysis (accelerated alteplase) in STEMI, fell short of its planned 1200-patient enrollment, and hence was underpowered (173). Eight hundred forty patients were randomized to prehospital fibrinolysis versus primary PCI. The primary end point was the composite of all-cause mortality, nonfatal recurrent MI, and nonfatal disabling stroke at 30 days, which occurred in 8.2% of patients assigned fibrinolytic therapy and 6.2% of patients assigned to PCI (p not significant [NS]). The components for death, reinfarction, and disabling stroke were 3.8%, 3.7%, and 1.0% for fibrinolytic therapy and 4.8%, 1.7%, and 0% for PCI. Unlike C-PORT, this trial liberally used rescue angioplasty (28%), which probably accounts for the relatively low reinfarction rate in the lytic-treated group. A subsequent analysis from CAPTIM of the 55% of patients treated within 2 hours of symptom onset revealed a mortality trend in favor of prehospital fibrinolysis versus primary PCI (2.2% versus 5.7%, p equals 0.058), whereas those patients treated beyond 2 hours had a 5.9% versus 3.7% (p equals 0.47) 30-day mortality rate, respectively (176). Interestingly, there was a significant reduction in the frequency of cardiogenic shock for patients treated within 2 hours with prehospital fibrinolysis (1.3% versus 5.3%, p equals 0.032), whereas the frequency of this event after 2 hours was similar (i.e., 3.9% versus 4.4%, respectively) (176).

The DANAMI-2 study, which compared primary PCI versus accelerated alteplase, enrolled 1572 patients versus the 2000 patients planned (306). Patients were eligible if they had a sum of greater than 0.4 mV of ST elevation in 2 contiguous leads on their presenting ECG within 12 hours of symptom onset; however, patient enrollment consisted of 37% of those screened, and patients deemed to be at high risk during ambulance transport were excluded (306). Twentynine hospitals, of which 5 conducted primary PCI and were located a mean of 35 miles from referring hospitals (maximum 95 miles), participated. The median door-to-needle time for patients randomized to fibrinolysis was approximately 50 minutes for patients presenting either to a community (referral) hospital or an invasive center. For patients who presented to a community hospital (where 1129 patients were enrolled), the time from initial presentation to balloon inflation at an invasive center was 108 minutes; the door-toballoon time was 93 minutes for patients presenting to an invasive center and randomized to PCI. The primary composite end point of death, reinfarction, and stroke through 30 days occurred in 14.2% of the fibrinolysis-treated patients and 8.5% of the PCI-treated patients (p less than 0.001). The individual end-point components of death, reinfarction, and stroke occurred in 7.8%, 6.3%, and 2.0% of the fibrinolysistreated patients and 6.6%, 1.6%, and 1.1% of the PCI-treated patients, respectively. In addition to the exclusion of highrisk patients for transport, some caveats in DANAMI-2 are noteworthy: 1) The antithrombotic dosing regimen was in excess of ACC/AHA guidelines. 2) The protocol specified that repeat fibrinolysis was to be used for failed reperfusion, reinfarction, and recurrent ST-elevation ischemia; this strategy was used in 26 patients within 12 hours after randomization, and only 1.9% underwent rescue PCI. 3) Patients with prior stroke were included, and an imbalance in this baseline characteristic was present, (i.e., 4.0% for fibrinolysis versus 2.7% for PCI ([1-sided p equals 0.06]). 4) The difference in reinfarction rates between the 2 groups was likely exaggerated by the exclusion of those patients associated with invasive procedures (311).

Hence, on the basis of the data, patients with STEMI presenting to a facility without the capability for expert, prompt intervention with primary PCI within 90 minutes of first medical contact should undergo fibrinolysis unless contraindicated. (See Sections 6.3.1.6.4.2, Primary PCI, and 6.3.1.6.4.2.4, Interhospital Transfer for Primary PCI.)

6.3.1.6.3. Pharmacological Reprefusion. Rationale For Fibrinolytic Therapy. Although the clinical features of coronary obstruction were described nearly a century ago (312,313), thrombotic obstruction of the infarct artery as a cause of STEMI was not proven until 1980 (20). The benefits of fibrinolytic therapy are maximal when there is prompt, adequate restoration of flow in the epicardial infarct artery and perfusion of the myocardium in the infarct zone. Controlled clinical trials have demonstrated the potential forfunctional, clinical, and mortality benefits only if fibrinolytic therapy is given within 12 hours. (See additional discussion on the use of antithrombins and antiplatelet agents as ancillary therapy in Sections 6.3.1.6.8.1 and 6.3.1.6.8.2.)

The reduction in mortality with fibrinolytic therapy is present regardless of sex, presence of diabetes, blood pressure (if less than 180 mm Hg systolic) (246,314), heart rate, or history of previous MI (156). The mortality benefit is greater in the setting of anterior STEMI, diabetes, low blood pressure, (less than 100 mm Hg systolic) or high heart rate (greater than 100 bpm) (Figure 13) (156). The earlier therapy begins, the better the outcome, with the greatest benefit decidedly occurring when therapy is given within the first 3 hours. Benefit occurs, however, up to at least 12 hours from the onset of symptoms. The absolute benefit is less with inferior STEMI, except for the subgroup with associated RV infarction or anterior ST-segment depression indicative of a greater territory at risk (Figure 16) (156).

6.3.1.6.3.1. Indications for Fibrinolytic Therapy

Class I
1. In the absence of contraindications, fibrinolytic therapy should be administered to STEMI patients with symptom onset within the prior 12 hours and ST elevation greater than 0.1 mV in at least 2 contiguous precordial leads or at least 2 adjacent limb leads. (Level of Evidence: A)

2. In the absence of contraindications, fibrinolytic therapy should be administered to STEMI patients with symptom onset within the prior 12 hours and new or presumably new LBBB. (Level of Evidence: A)

Class IIa
1. In the absence of contraindications, it is reasonable to administer fibrinolytic therapy to STEMI patients with symptom onset within the prior 12 hours and 12-lead ECG findings consistent with a true posterior MI. (Level of Evidence: C)

2. In the absence of contraindications, it is reasonable to administer fibrinolytic therapy to patients with symptoms of STEMI beginning within the prior 12 to 24 hours who have continuing ischemic symptoms and ST elevation greater than 0.1 mV in at least 2 contiguous
precordial leads or at least 2 adjacent limb leads. (Level of Evidence: B)

Class III
1. Fibrinolytic therapy should not be administered to asymptomatic patients whose initial symptoms of STEMI began more than 24 hours earlier. (Level of Evidence: C)

2. Fibrinolytic therapy should not be administered to patients whose 12-lead ECG shows only ST-segment depression except if a true posterior MI is suspected. (Level of Evidence: A)

Because the benefit of fibrinolytic therapy is directly related to the time from symptom onset, treatment benefit is maximized by the earliest possible application of therapy. The constellation of clinical features that must be present (although not necessarily at the same time) to serve as an indication for fibrinolysis includes symptoms of myocardial ischemia and ST elevation greater than 0.1 mV, in 2 contiguous leads, or new or presumably new LBBB on the presenting ECG (156,315). In the very early phase of STEMI, giant hyperacute T waves may precede ST elevation (316). True posterior MI may be manifested by tall R waves in the right precordial leads and ST-segment depression in leads V1 through V4, especially when T waves are upright (317). Repeat ECGs and incorporation of additional leads such as V7 through V9 are more specific for the detection of posterior infarction (225). Patients with LBBB or anterior ST elevation are at greater inherent risk from MI and achieve greater benefit with fibrinolytic therapy. Additional valuable information may be garnered from concurrent echocardiography to identify the location and extent of regional wallmotion abnormalities. Patients with inferior MI and ST elevation in V1, V4R, or both are more likely to have concomitant RV infarction (318). Attainment of additional ECG leads (right sided and/or posterior) or an echocardiogram may help clarify the location and extent of infarction and anticipated risk of complications, but it is important that acquisition of such ancillary information not interfere with the strategy of providing timely reperfusion in patients with STEMI (319).

6.3.1.6.3.2. Contraindications/Cautions

Class I
1. Healthcare providers should ascertain whether the patient has neurological contraindications to fibrinolytic therapy, including: any history of intracranial hemorrhage or significant closed head or facial trauma within the past 3 months, uncontrolled hypertension, or ischemic stroke within the past 3 months. (See Table 12 for a comprehensive list.) (Level of Evidence: A)

2. STEMI patients at substantial (greater than or equal to 4%) risk of ICH should be treated with PCI rather than with fibrinolytic therapy. (See Table 11 for further management considerations.) (Level of Evidence: A)

A detailed list of contraindications and cautions for the use of fibrinolytic therapy is shown in Table 12. Specific neurological considerations are addressed below.

Hemorrhage represents the most important risk of fibrinolytic therapy, especially ICH, which may be fatal in half to two thirds of patients. There is both legitimate concern and confusion surrounding the issue of whether fibrinolytic therapy should be contraindicated in patients with a history of prior cerebrovascular disease (2,320-322). The 1996 ACC/AHA Guidelines for the Management of Acute Myocardial Infarction (2) stated that “Previous hemorrhagic stroke at any time; other strokes or cerebrovascular events within 1 year” was a contraindication to use of thrombolytic therapy and that “...history of prior cerebrovascular accident or known intracerebral pathology not covered in contraindications” was a caution/relative contraindication. After the first 627 patients were enrolled in TIMI-II (320), a number of protocol changes were made: the dose of tPA was reduced from 150 to 100 mg, use of 80 mg of aspirin was postponed for 24 hours, patients who had a history of stroke or intermittent cerebral ischemic attacks were excluded, and patients with blood pressures greater than or equal to 180 mm Hg systolic or greater than or equal to 110 mm Hg diastolic were excluded. The reduction of ICH frequency by the exclusion of patients with any history of cerebrovascular disease was likely confounded by the influence of the other 3 protocol changes. The basis for the 1996 recommendation for a time frame of 1 year for ischemic stroke as a contraindication to coronary fibrinolysis was a consensus opinion without specific supporting data.

In subsequent trials (26-31,33,323,324), the use of prior TIA or stroke as an exclusion criterion has varied: stroke within 2 years (30), stroke within 6 months (323), TIA within 6 months/any history of stroke (33), any stroke (26,27,324), and any history of prior TIA or stroke (28,29,31) have each been used as exclusion criteria. In some studies, the frequency of ICH in patients older than 75 years ranged from 0.5% with streptokinase and heparin (33) to 2.5% with reteplase (26). Giugliano et al. (325) showed that the higher ICH frequencies with lanoteplase or tenecteplase may be explained in part by the effect of the UFH (InTIME-2 [Intravenous NPA for the Treatment of Infarcting Myocardium Early] equals 1.12%, InTIME-IIb equals 0.50%) and dose of the UFH infusion (ASSENT-1 and TIMI-10B: higher heparin dose equals 1.83%, lower heparin dose equals 0.74%). (See discussion on the use of LMWH in the elderly in Section 6.3.1.6.8.1.2.) In the Maximal Individual Therapy in Acute Myocardial Infarction (MITRA) registry (326), previous stroke within 3 months was the strongest predictor of stroke (OR equals 9.3, 95% CI 6.0 to 14.2) after STEMI. On the basis of these data, it appears that the effect of prior stroke/TIA per se on the frequency of ICH after fibrinolysis may be influenced by number of factors. However, in patients with STEMI with prior ischemic stroke and other ICH risk factors who have substantial risk for ICH, another reperfusion strategy should be pursued. Additional contraindications to fibrinolytic therapy include a recent history of significant closed head or facial trauma (327).

Estimation of risk of ICH. Several models have been developed for estimating the risk of ICH after fibrinolysis (246,328-330). These models incorporate baseline demographic features of the patient and also illustrate the impact of certain therapeutic decisions (e.g., selection of streptokinase versus tPA; dose of tPA used) (Table 13) (29,246,329,330). Streptokinase without heparin is the regimen associated with the lowest ICH rates (Figure 17) (29,246,329,330).

6.3.1.6.3.3. Effect on Mortality

Efficacy of intravenous fibrinolytic therapy in STEMI. It has now been well established that fibrinolytic therapy provides a survival benefit for patients with STEMI, based on large, well-controlled clinical trials (157,261,331,332). The mechanisms of benefit, which may have different time dependencies, include salvage of myocardium with reduced infarct size, favorable effect on infarct healing and myocardial remodeling, and reduced electrical heterogeneity and potential for life-threatening ventricular arrhythmia (333). An overview from 9 trials of fibrinolytic therapy (versus control) for STEMI has shown a highly significant 18% relative reduction in 35-day mortality (9.6% fibrinolysis versus 11.5% control), which corresponds to a reduction of 18 deaths per 1000 patients treated when data from all patient groups are pooled (156). In patients with ST elevation, a relative mortality reduction of 21% occurred. This survival benefit is maintained over the long term (up to 10 years) (334,335). Mortality reduction from fibrinolytic therapy is greatest within the first hour after symptom onset; thereafter, a decline in benefit of approximately 1.6 lives per 1000 patients treated is seen per 1-hour delay. Additionally, patients with presumed new LBBB, anterior infarction, and the greatest area of risk, as exemplified by the number of ECG leads affected and the extent of ST deviation, derived maximal benefit from fibrinolytic therapy (Figure 16) (156,336).

Elderly patients. Although the elderly constitute a minority of the general population, they are the fastest-growing segment of the population and account for the majority of patients presenting with MI and a disproportionately high component of death from MI (46,213,338). In persons older than 75 years, the overall risk of mortality from MI is high with and without therapy. Although the proportionate reduction in mortality for patients older than 75 years treated within 12 hours with ST elevation or LBBB is somewhat less for patients less than or equal to 75 years, the absolute number of lives saved per 1000 patients treated is actually greater (i.e., 34 lives saved per 1000 patients treated versus 28 for those less than 75 years) (339).

Registry observations from the Cooperative Cardiovascular Project (CCP) database by Thiemann and colleagues of 2673 patients between the age of 75 and 86 years suggested that the 1607 patients receiving fibrinolytics had a lower 30-day survival than those not treated with this therapy (340). Some caution in the interpretation of these observational data is appropriate because 1) a reversal of this effect toward benefit was seen in women between the ages of 65 and 75 years derived from a larger sample, and 2) a substantial proportion of the patients possessed conventional clinical trial fibrinolytic exclusion criteria (i.e., 11.8% had systolic blood pressure greater than 180 mm Hg, 18% had a history of recent trauma or a remote history of peptic ulcer or internal bleeding, and 6.9% had a history of stroke). Twice as many patients receiving fibrinolysis (i.e., 2.2% versus 0.9%) had CPR before arrival as opposed to those without fibrinolysis (340). In contrast to the CCP study by Thiemann et al., another CCP analysis in the elderly by Berger et al. indicated that both fibrinolytic therapy and primary angioplasty were associated with a survival benefit at 1 year compared with patients receiving neither (341). Data from the Swedish National Register on the use of fibrinolysis in 6891 patients 75 years and older with first registry-recorded STEMI also confirm a 13% adjusted relative risk reduction (95% CI 0.80 to 0.94; p equals 0.001; absolute risk reduction 4%) in the composite of mortality and cerebral bleeding after 1 year (Figure 18) (342).

6.3.1.6.3.4. Effect on LV Function

Early reperfusion of ischemic myocardium within the risk region of an occluded infarct-related artery interrupts the wave front of necrosis (18), reduces ultimate infarct size, preserves regional and global ventricular function, and improves survival. Clinical evidence for this paradigm was inconclusive until the GUSTO-I angiographic trial (343-348). Global LV ejection fraction (LVEF), a load-dependent measurement, is an imperfect surrogate for infarct size. Compensatory remote-segment hyperkinesis, the importantprognostic effect of ventricular dilation, and the potential effects of a patent infarct artery independent of myocardial salvage confound the relationship between early reperfusion, global LV function, and survival. Poor perfusion at the myocardial cellular level due to microvascular obstruction further confounds the relationship between early reflow in the epicardial coronary artery, wall-motion improvement, and survival. In patients with TIMI 3 flow, those with abnormal myocardial tissue perfusion have worse LV function and survival than those with normal perfusion. Myocardial blush on angiography, contrast perfusion on echocardiography, and prompt complete resolution of ST elevation are measures of tissue perfusion. Poor perfusion at the myocardial cellular level is associated with increased morbidity and mortality. However, the mechanism by which poor tissue perfusion confers an adverse prognosis is not clear. Evidence of poor tissue perfusion may be the result of extensive transmural infarction with tissue edema and increased microvascular resistance (349). Alternatively, poor microvascular flow may result from distal embolization of atherothrombotic debris and hence be a target for therapeutic interventions. Flow in the infarct artery before PCI is associated with smaller infarct size and better outcome. Infarct size can be measured with SPECT sestamibi imaging (350), and this has been done in more than a dozen randomized trials.

6.3.1.6.3.5. Complications of Fibrinolytic Therapy: Neurological and Other

Class I
1. The occurrence of a change in neurological status during or after reperfusion therapy, particularly within the first 24 hours after initiation of treatment, is considered to be due to ICH until proven otherwise. Fibrinolytic, antiplatelet, and anticoagulant therapies should be discontinued until brain imaging scan shows no evidence of ICH. (Level of Evidence: A)

2. Neurology and/or neurosurgery or hematology consultations should be obtained for STEMI patients who have ICH, as dictated by clinical circumstances. (Level of Evidence: C)

3. In patients with ICH, infusions of cryoprecipitate, fresh frozen plasma, protamine, and platelets should be given, as dictated by clinical circumstances. (Level of Evidence: C)

Class IIa
In patients with ICH it is reasonable to:
a. Optimize blood pressure and blood glucose levels (Level of Evidence: C)

b. Reduce intracranial pressure with an infusion of mannitol, endotracheal intubation, and hyperventilation (Level of Evidence: C)

c. Consider neurosurgical evacuation of ICH (Level of Evidence: C)

Hemorrhagic complications of fibrinolytic therapy primarily include ICH and other moderate or severe bleeding that may or may not require transfusion. The slight but definite excess risk of ICH occurs predominantly within the first day of therapy (156). Summaries of the incidence of ICH with various pharmacological reperfusion regimens are shown in Table 14 (26-31, 33, 158, 261, 320, 322, 324, 331, 351-369).

ICH may refer to parenchymal hemorrhage (PH), intraventricular hemorrhage, subarachnoid hemorrhage, subdural hematoma, and epidural hematoma. Between 65% and 77% of ICHs occur within 24 hours of initiation of treatment, up to 77% occur at lobar/subcortical lobar sites, 15% to 33% are multiple PHs, and up to 15% are combined PH and subdural hematoma. Typical presenting features include an acute change in level of consciousness, unifocal or multifocal neurological signs, coma, headache, nausea, vomiting, and seizures, at times with acute hypertension. In many cases, onset is catastrophic and rapidly fatal.

Management of suspected ICH. An algorithm for the management of ICH in the STEMI setting is provided in Figure 19 (370,371). Any change in neurological function, particularly in the first 24 hours after treatment, should be regarded as strongly indicative of PH/intraventricular hemorrhage/ subarachnoid hemorrhage/subdural hematoma/epidural hematoma until proven otherwise. Fibrinolytic, anticoagulant, antiplatelet, and combined therapies should be discontinued as soon as symptoms and signs are recognized. An emergency CT scan should be performed as soon as possible to identify the specific type of hemorrhagic complication and to measure the volume of hematoma (372,373). It is useful to document the severity of the coagulopathy, although emergency patient management should not await the results of laboratory testing. Immediate measures to reduce intracranial pressure are reasonable and include mannitol infusion, elevation of the head of the bed to 30 degrees, endotracheal intubation, and hyperventilation to achieve a pCO2 of 25 to 30 mm Hg. Early involvement of neurologists, neurosurgeons, and hematologists will optimize treatment decisions.

Once PH, intraventricular hemorrhage, subarachnoid hemorrhage, subdural hematoma, or epidural hematoma is documented, the patient should be given 10 U of cryoprecipitate, which will increase the fibrinogen level by approximately 0.70 grams per liter and the factor VIII level by approximately 30% in a 70-kg adult. Fresh frozen plasma can be used as a source of factors V and VIII and as a volume expander. In patients who are receiving UFH, 1 mg of protamine for every 100 U of UFH given in the preceding 4 hours may be administered. If the bleeding time is abnormal, infusion of 6 to 8 U of platelets is indicated. In rare cases, antifibrinolytic agents, such as epsilon-aminocaproic acid, may be necessary (374). These replacement/reversal therapies may theoretically be accompanied by reocclusion of the infarctrelated artery. Control of blood pressure and blood glucose levels may require a compromise between competing cardiologic and neurological concerns. The decision to use various measures to reduce increased intracranial pressure, such as elevation of the head of the bed to 30 degrees, mannitol, hyperventilation, and ventriculostomy, may be based on the consensus of the management team. The use of mannitol and hyperventilation are reserved for incipient brain herniation syndromes. After the patient is stabilized, catheter-based angiography may be necessary if a ruptured berry aneurysm or arteriovenous malformation is suspected.

In GUSTO-I (375), 46 (17.2%) of 268 PH/subdural hematoma patients underwent neurosurgical evacuation by open craniotomy or burr-hole craniectomy. Patients who underwent neurosurgical evacuation had significantly higher 30-day survival rates than patients who did not (65.2% versus 35.1%, p less than 0.001), particularly in patients with PH. Patients with both PH and subdural hematoma had a very poor prognosis regardless of surgical treatment. There was a trend for improved functional status in patients who underwent neurosurgical evacuation compared with those who did not (nondisabling stroke 20% versus 12%, p equals 0.15). Although not definitive, these data suggest that physicians actively consider neurosurgical interventions in selected patients. For patients with spinal epidural hematoma and significant neurological deficits occurring after fibrinolysis, early multilevel decompressive laminectomy should be performed to minimize long-term disability (376). Survivors of PH/subdural hematoma/epidural hematoma should receive supportive care measures, including physical therapy, occupational therapy, speech therapy, swallowing evaluation, aspiration precautions, deep vein thrombosis (DVT) prophylaxis (pneumatic compression device), antibiotic therapy, nutritional support, and rehabilitation, where appropriate.

The risk of 30-day mortality from ICH after coronary fibrinolysis may be predicted on the basis of prior trial experience. In GUSTO-I (322), the ICH mortality rate was 59.7%. Glasgow Coma Scale score, age, time from fibrinolysis to ICH onset, hydrocephalus, herniation, mass effect, intraventricular hemorrhage, and volume and location of ICH were significant univariable predictors, with a strong trend (p equals 0.0546) for neurosurgical evacuation. The multivariable model showed that Glasgow Coma Scale score, time from thrombolysis to ICH onset, ICH volume, and age were significant predictors of mortality (377). A nomogram has been developed to calculate the risk of dying of ICH (Figure 20) (377). Prospective studies are needed to confirm the utility of this nomogram.

6.3.1.6.3.6. Comparison of Fibrinolytic Agents

All of the fibrinolytic agents currently available and under investigation are plasminogen activators (378). They work enzymatically, directly or indirectly, to expose the active enzymatic center of plasmin. Some comparative features of the approved fibrinolytic agents for intravenous therapy are presented in Table 15 (379-381).

Data from GUSTO-I (25) and GUSTO-III (26) suggest that accelerated alteplase and reteplase (administered as a double bolus) with intravenous heparin are effective therapies for achieving early coronary reperfusion and may provide an advantage over streptokinase; however, both are substantially more expensive and confer a slightly greater risk of ICH. Thus, the cost-benefit ratio is most favorable for alteplase or reteplase in patients who present early after onset of chest pain or symptoms and in those with a large area of injury (e.g., anterior infarction) and at low risk of ICH. In ASSENT- 2, weight-adjusted TNK-tPA (tenecteplase) and alteplase were compared in 16 949 patients. Covariate-adjusted 30-day mortality was virtually identical (i.e., 6.18% for tenecteplase and 6.15% for alteplase), which met the predefined criteria for equivalence. The rates of ICH were also similar (i.e., 0.93% for tenecteplase and 0.94% for alteplase), but in patients receiving tenecteplase, there were fewer systemic mild-to-moderate bleeding complications (26.3% versus 28.95%, p equals 0.0003) and less requirement for blood transfusion (4.25% versus 5.49%, p equals 0.0002) (28).

There is considerable ongoing investigation into the effectiveness of fibrinolytic therapy with various ancillary therapies (see Section 6.3.1.6.3.8). In 2 studies that evaluated the combination of hirudin (desirudin) with alteplase and streptokinase, there was no improvement in mortality rate, and the therapeutic-to-severe bleeding window appeared to be very narrow (382,383). See Section 6.3.1.6.8.1.3 for further discussion.

A number of proposals for selection of fibrinolytic regimens after GUSTO-I have been suggested (384-387). Additional considerations include avoiding the reuse of streptokinase, preferably indefinitely because of a high prevalence of potentially neutralizing antibody titers. Alternatively, Simoons and Arnold (386) proposed considering primary PCI for those at highest risk (approximately 10% of patients), alteplase for those at moderate to high risk (40%), streptokinase for those at low to moderate risk (40%), and no lytic therapy for those at lowest risk (10%). All of these recommendations await prospective testing, and no data are available to determine the best modes for routine clinical practice.

Current use rates for fibrinolytic therapy. Because many patients have contraindications or other exclusions for fibrinolytic agents, it has been difficult to ascertain the proportion of patients with ST elevation who fail to receive fibrinolytic therapy who actually should have received such therapy (388). Critical to any such assessment of appropriateness of care, however, is whether the diagnosis of STEMI was suspected on entry into the healthcare system or whether a diagnosis made after 12 to 24 hours in the hospital or at some later point before hospital discharge. Some increase in use rates probably can be achieved, but contraindications prohibit a vast increase in the rate of use of fibrinolysis.

6.3.1.6.3.7. Net Clinical Benefit

The decision to use reperfusion therapy is based on an estimate of the patient’s underlying risk without treatment, the expected benefit of the treatment, and the risk of the therapy. In general, the higher the underlying risk, the more benefit that can be gained and the fewer the number of patients who need to be treated to save 1 life.

Because decisions about reperfusion must be made rapidly in order for the intervention to be maximally effective, it is not possible to take the time to confirm the diagnosis of STEMI before administration of therapy. Data from the Multicenter Chest Pain Study suggest that approximately 80% of patients with chest pain and ST-segment elevation who present to the ED are having a STEMI (227).

Several prediction models for short-term (30 days) (240,242,298,389-393) and long-term (1 to 6 years) (392,393) mortality after reperfusion therapy for STEMI have been developed. These models have been derived from clinical trials (240,242,389,394), administrative data sets (298,390,392), and registries (391), and some have been validated in other clinical trials (242) or registries (391, 394). Performance for some of these risk-prediction models, as defined by the area under the receiver operating characteristic curve, c-index, or standardized mortality ratio, is similar, with c-indices ranging from 0.74 to 0.80 and correlation coefficients for the standardized mortality ratios ranging from 0.89 to 0.92 (298). The TIMI risk score developed in the InTIME-II trial (242) performs well compared with data from the TIMI-9 trial and NRMI-3 (394). In NRMI-3, prognostic discriminatory capacity was similar between patients who received fibrinolytics and primary PCI (c-index equals 0.80). Substantial differences in predicted mortality rates (greater than 5%) between those patients who did or did not receive reperfusion therapy were observed if the TIMI risk score was greater than or equal to 7 (394).

The expected benefit of fibrinolytic therapy can be estimated from the clinical trials (156,282). The fibrinolytic trials showed “absolute mortality reductions of about 30 per 1000 for those presenting within 0-6 h and of about 20 per 1000 for those presenting 7 to 12 h from onset, and a statistically uncertain benefit of about 10 per 1000 for those presenting at 13 to 18 h (with more randomized evidence needed in this latter group to assess reliably the net effects of treatment)” (156). The relative benefit, however, appeared to vary by age, with a smaller relative reduction in risk for the oldest patients.

The major risk of pharmacological reperfusion therapy is life-threatening hemorrhage (105). (See Section 6.3.1.6.3.2 for further information.) A study among Medicare patients identified older age, female sex, black race, prior stroke, systolic blood pressure greater than or equal to 160 mm Hg, lower weight (less than or equal to 65 kg for women, less than or equal to 80 kg for men), excessive anticoagulation (international normalized ratio [INR] greater than or equal to 4, prothrombin time greater than or equal to 24 sec), and choice of fibrinolytic therapy (tPA associated with greater risk than streptokinase) as risk factors for intracranial bleeding (246). Patients with none or 1 of these factors had a risk of 0.69% for intracranial bleeding, whereas those with 5 or more factors had a risk of 4.1%. Simoons et al., using data primarily from trials, identified older age, lower body weight (less than 70 kg), systolic blood pressure greater than or equal to 170 mm Hg or diastolic blood pressure greater than or equal to 95 mm Hg, and the use of tPA (versus streptokinase) as risk factors (329). Using these factors, a risk score was developed that classified patients with a risk of hemorrhage from 0.26% to 2.2% (for zero to 4 risk factors). Although this score uses dichotomous cutpoints for the risk factors, it is likely that the risk is a continuous function of the factor (e.g., the higher the blood pressure or the older the patient, the higher the risk) (322). Also, the studies of risk were based on older regimens of fibrinolytic therapy and higher dosages of UFH than are used currently. There is some evidence that newer agents, with increased fibrin specificity and bolus administration, may not increase the risk of ICH, but this issue deserves continued evaluation (156). In addition, the use of ancillary therapies may influence the risk of bleeding with fibrinolytic therapy.

6.3.1.6.3.8. Combination Therapy With GP IIb/IIIa Inhibitors

Class IIb
1. Combination pharmacological reperfusion with abciximab and half-dose reteplase or tenecteplase may be considered for prevention of reinfarction (Level of Evidence: A) and other complications of STEMI in selected patients: anterior location of MI, age less than 75 years, and no risk factors for bleeding. In two clinical trials of combination reperfusion, the prevention of reinfarction did not translate into a survival benefit at either 30 days or 1 year (394a) (Level of Evidence: B).

2. Combination pharmacological reperfusion with abciximab and half-dose reteplase or tenecteplase may be considered for prevention of reinfarction and other complications of STEMI in selected patients: anterior location of MI, age less than 75 years, and no risk factors for bleeding in whom an early referral for angiography and PCI (i.e., facilitated PCI) is planned. (Level of Evidence: C)

Class III
Combination pharmacological reperfusion with abciximab and half-dose reteplase or tenecteplase should not be given to patients aged greater than 75 years because of an increased risk of ICH. (Level of Evidence: B)

Studies evaluating the use of glycoprotein IIb/IIIa inhibitors as the sole means of reperfusion (i.e., without a fibrinolytic or in conjunction with PCI) do not suggest that the isolated use of a GP IIb/IIIa inhibitor restores TIMI 3 flow in a sufficient proportion of patients to make it a viable pharmacologic strategy (395a). To improve rates of achieving TIMI 3 flow by pharmacological rapy is used, the dose of fibrinolytic agent is reduced by 50%. A large-scale mortality study, GUSTO-V (30), tested half-dose reteplase (5 U and 5 U) and full-dose abciximab (abciximab 0.25 mg/kg bolus and 0.125 mcg/kg/min [maximum of 10 mcg/min] for 12 hours) compared with full-dose reteplase (10 U and 10 U) in 16 588 patients in the first 6 hours of STEMI. Thirty-day mortality rates were similar in the 2 groups (5.9% versus 5.6%). However, nonfatal reinfarction rates were reduced in the combination therapy group (2.3% versus 3.5%, p less than 0.0001), as were other complications of MI, including VF and tachycardia, high-grade AV block, and septal or freewall rupture. ICH rates were the same (0.6%), but moderate to severe bleeding was significantly increased from 2.3% to 4.6% (p less than 0.001). Excess bleeding risks appear to be limited to those over the age of 75 years, and the greatest mortality benefit was seen for those with anterior MI. ICH rates for those older than 75 years were 2.1% versus 1.1% (p equals 0.069) for combination versus full-dose eteplase. In contrast, the rates were similar for those younger than 75 years (0.5% versus 0.4%). However, there was an interaction between age and risk of ICH with therapy. Younger patients (age less than 70 years) appeared to have significantly lower ICH rates with combination therapy (398). Despite the reduction in reinfarction by combination therapy, the 1-year mortality rates were the same (8.38%) in both groups (399). Although early reinfarction was associated with a marked increase in 1-year mortality, (22.6% versus 8.0% without reinfarction), this did not result in an overall mortality difference owing to the low reinfarction rates. For those younger than 75 years with anterior MI, 30-day mortality was 4.4% for combination therapy versus 5.8% (p equals 0.029) for full-dose rPA, and 1-year mortality was 7.1% versus 8.0% (p equals 0.260), respectively.

ASSENT-3 (31) randomized 6095 patients with STEMI to full-dose tenecteplase with UFH versus full-dose tenecteplase with enoxaparin or half-dose tenecteplase plus abciximab plus weight-adjusted, reduced-dose UFH. Similar to the GUSTOV trial, combination of abciximab (abciximab 0.25 mg/kg bolus and 0.125 mcg/kg/min [maximum of 10 mcg/min] for 12 hours) and half-dose tenecteplase did not reduce mortality compared with full-dose tenecteplase but did result in significantly reduced in-hospital infarction and refractory ischemia. Notably, the major bleeding rate other than ICH, which was the same in the 2 groups, was increased from 2.2% to 4.3% (p less than 0.0005). Those over the age of 75 years were at greatest risk for excess bleeding, with a 3-fold increase in major bleeding complications. The tenecteplase plus enoxaparin arm showed superiority compared with UFH (see Section 6.3.1.7.8.2.1). The need for urgent PCI was reduced in the GP IIb/IIIa antagonist and fibrinolytic combination therapy arms in both trials. The heparin regimen, when combination therapy is used, is a weight-adjusted bolus of 40 U/kg (ASSENT-3) or 60 U/kg (GUSTO-V) followed by a reduced infusion dose of 7 U/kg/h. The lower bolus dose is preferable for patients who have an increased risk for bleeding.

Given the observation that patients with TIMI 3 flow before primary PCI have the best outcomes (346) and given the role of GP IIb/IIIa antagonists in PCI, some have hypothesized that administration of combination GP IIb/IIIa antagonists and half-dose fibrinolytics will facilitate primary PCI, particularly when it cannot be accomplished very rapidly. This remains to be tested prospectively in appropriately sized trials. Combination pharmacological reperfusion regimens may be associated with a slightly higher frequency of ICH and a slightly lower frequency of cerebral infarction and stroke of unknown cause than other reperfusion regimens (Table 14) (26-30, 31, 33, 158, 261, 320, 322, 324,1331, 351-369, 400).

6.3.1.6.4. PERCUTANEOUS CORONARY INTERVENTION

Percutaneous coronary intervention is a very effective method for re-establishing coronary perfusion and is suitable for at least 90% of patients. Considerable data (40,282,401) support the use of PCI for patients with STEMI. Reported rates of achieving TIMI 3 flow range from 70% to 90%. There is a 15% reocclusion rate after PTCA and a 5% reocclusion rate after stenting (402). Although most evaluations of PCI have been in patients who are eligible to receive fibrinolytic therapy, considerable experience supports the value of PCI for patients who may not be suitable for fibrinolytic therapy because of an increased risk of bleeding (403).

6.3.1.6.4.1. Coronary Angiography

Class I
Diagnostic coronary angiography should be performed:
a. In candidates for primary or rescue PCI. (Level of Evidence: A)

b. In patients with cardiogenic shock who are candidates for revascularization. (Level of Evidence: A)

c. In candidates for surgical repair of ventricular septal rupture (VSR) or severe MR. (Level of
Evidence: B)

d. In patients with persistent hemodynamic and/or electrical instability. (Level of Evidence: C)

Class III
Coronary angiography should not be performed in patients with extensive comorbidities in whom the risks of revascularization are likely to outweigh the benefits. (Level of Evidence: C)

Acute cardiac catheterization has been proposed as an anatomic risk stratification strategy. A subset of patients will have severe 3-vessel or left main disease or anatomic features unfavorable for PCI and may be candidates for urgent or emergency CABG. Another subset of patients will have spontaneously reperfused and will have minimal evidence of atherosclerotic obstruction. They can be treated medically, which avoids the risks of fibrinolytic therapy or PCI. Additionally, identification of high-risk patients may facilitate additional strategies that will improve outcome, whereas low-risk patients may be eligible for early hospital discharge. Coronary angiography should not be performed in patients with extensive comorbidities or who will not consent to coronary revascularization regardless of the findings.

6.3.1.6.4.2. Primary PCI

See Table 11 for additional consideration for selecting reperfusion therapy.

Class I
1. General considerations: If immediately available, primary PCI should be performed in patients with STEMI (including true posterior MI) or MI with new or presumably new LBBB who can undergo PCI of the infarct artery within 12 hours of symptom onset, if performed in a timely fashion (balloon inflation within 90 minutes of presentation) by persons skilled in the procedure (individuals who perform more than 75 PCI procedures per year). The procedure should be supported by experienced personnel in an appropriate laboratory environment (a laboratory that performs more than 200 PCI procedures per year, of which at least 36 are primary PCI for STEMI, and has cardiac surgery capability). (Level of Evidence: A)

2. Specific considerations:
a. Primary PCI should be performed as quickly as possible with a goal of a medical contact–to-balloon or door-to-balloon interval of within 90 minutes. (Level of Evidence: B)

b. If the symptom duration is within 3 hours and the expected door-to-balloon time minus the expected door-to-needle time is:
i) within 1 hour, primary PCI is generally preferred. (Level of Evidence: B)

ii) greater than 1 hour, fibrinolytic therapy (fibrinspecific agents) is generally preferred. (Level of Evidence: B)

c. If symptom duration is greater than 3 hours, primary PCI is generally preferred and should be performed with a medical contact–to-balloon or door-to-balloon interval as short as possible and a goal of within 90 minutes. (Level of Evidence: B)

d. Primary PCI should be performed for patients less than 75 years old with ST elevation or LBBB who develop shock within 36 hours of MI and are suitable for revascularization that can be performed within 18 hours of shock unless further support is futile because of the patient’s wishes or contraindications/unsuitability for further invasive care. (Level of Evidence: A)

e. Primary PCI should be performed in patients with severe CHF and/or pulmonary edema (Killip class 3) and onset of symptoms within 12 hours. The medical contact–to-balloon or door-to-balloon time should be as short as possible (i.e., goal within 90 minutes). (Level of Evidence: B)

Class IIa
1. Primary PCI is reasonable for selected patients 75 years or older with ST elevation or LBBB or who develop shock within 36 hours of MI and are suitable for revascularization that can be performed within 18 hours of shock. Patients with good prior functional status who are suitable for revascularization and agree to invasive care may be selected for such an invasive strategy. (Level of Evidence: B)

2. It is reasonable to perform primary PCI for patients with onset of symptoms within the prior 12 to 24 hours and 1 or more of the following:
a. Severe CHF (Level of Evidence C)

b. Hemodynamic or electrical instability (Level of Evidence: C)

c. Persistent ischemic symptoms. (Level of Evidence: C)

Class IIb
The benefit of primary PCI for STEMI patients eligible for fibrinolysis is not well established when performed by an operator who performs fewer than 75 PCI procedures per year. (Level of Evidence: C)

Class III
1. PCI should not be performed in a noninfarct artery at the time of primary PCI in patients without hemodynamic compromise. (Level of Evidence: C)

2. Primary PCI should not be performed in asymptomatic patients more than 12 hours after onset of STEMI if they are hemodynamically and electrically stable. (Level of Evidence: C)

Primary PCI has been compared with fibrinolytic therapy in 22 randomized clinical trials (173, 177, 306, 306, 404-421). An additional trial, SHOCK (301), which compared medical stabilization with immediate revascularization for cardiogenic shock, was included along with the above 22 trials in an overview of primary PCI versus fibrinolysis (40). These investigations demonstrate that PCI-treated patients experience lower short-term mortality rates (5.0% versus 7.0%, RR 0.70, 95% CI 0.58 to 0.85, p equals 0.0002), less nonfatal reinfarction (3.0% versus 7.0%, RR 0.35, 95% CI 0.27 to 0.45, p equals 0.0003), and less hemorrhagic stroke (0.05% versus 1.0%, RR 0.05, 95% CI 0.006 to 0.35, p equals 0.0001) than those treated by fibrinolysis but with an increased risk for major bleeding (7.0% versus 5.0%, RR 1.3, CI 1.02 to 1.65, p equals 0.032) (40). These results were achieved in medical centers with experienced providers and under circumstances in which PCI could be performed promptly after patient presentation (Figure 14) (40).

Additional considerations that affect the magnitude of the difference between PCI- and fibrinolysis-treated patients include the fact that UFH was used as the antithrombin with fibrinolytics as opposed to other antithrombins such as enoxaparin (see Section 6.3.1.6.8.1.1) or bivalirudin (see Section 6.3.1.6.8.1.2) that are associated with a reduction in the rate of recurrent MI after fibrinolysis; a smaller but statistically significant advantage for PCI compared with a fibrn-specific fibrinolytic versus streptokinase; and variation among the PCI arms as to whether a stent was implanted or GP IIb/IIIa antagonists were administered. Figure 14 shows the short-term and long-term outcomes of patients with STEMI treated by fibrinolysis versus PCI and the number of patients who need to be treated to prevent 1 event or cause 1 harmful complication when selecting PCI instead of fibrinolysis as the reperfusion strategy (Figure 14) (40). When primary PCI is compared with tPA and the SHOCK trial is excluded, the mortality rate is 5.5% versus 6.7% (OR 0.81%, 95% CI 0.64 to 1.03, p equals 0.081) (421a).

There is serious and legitimate concern that a routine policy of primary PCI for patients with STEMI will result in unacceptable delays in achieving reperfusion in a substantial number of cases and produce less than optimal outcomes if performed by less-experienced operators. The mean time delay for PCI instead of fibrinolysis in the randomized studies was approximately 40 minutes (40). Strict performance criteria must be mandated for primary PCI programs so that long door-to-balloon times and performance by low-volume or poor-outcome operators/laboratories do not occur. Interventional cardiologists and centers should strive for outcomes to include 1) medical contact–to-balloon or door-to-balloon times less than 90 minutes, 2) TIMI 2/3 flow rates obtained in more than 90% of patients, 3) emergency CABG rate less than 2% among all patients undergoing the procedure, 4) actual performance of PCI in a high percentage of patients (85%) brought to the laboratory, and 5) risk adjusted in-hospital mortality rate less than 7% in patients without cardiogenic shock. This would result in a risk-adjusted mortality rate with PCI comparable to that reported for fibrinolytic therapy in fibrinolytic-eligible patients (40) and would be consistent with previously reported registry experience (422-425). Otherwise, the focus of treatment should be the early use of fibrinolytic therapy (Figure 14) (40).

PCI appears to have its greatest mortality benefit in high-risk patients. In patients with cardiogenic shock, an absolute 9% reduction in 30-day mortality with coronary revascularization instead of immediate medical stabilization was reported in the SHOCK trial (301). In NRMI-II, patients with CHF had a 33% relative risk reduction with primary PCI compared with a 9% relative risk reduction with fibrinolytic therapy (302). Primary PCI in patients with anterior STEMI reduces mortality compared with fibrinolytic therapy, but there is no difference in patients with nonanterior STEMI (426,427).

Time from symptom onset to reperfusion is an important predictor of patient outcome. Two studies (294,295) have reported increasing mortality rates with increasing door-to-balloon times. Other studies have shown smaller infarct size, better LV function, and fewer complications when reperfusion occurs before PCI (345,346,428). An analysis of the randomized controlled trials that compared fibrinolysis with a fibrin-specific agent versus primary PCI suggests that the mortality benefit with PCI exists when treatment is delayed by no more than 60 minutes (Figure 15) (305). Mortality increases significantly with each 15-minute delay in the time between arrival and restoration of TIMI 3 flow (door-0=to –TIMI 3 flow time), further underscoring the importance of timely reperfusion in patients who undergo primary PCI (429). Importantly, after adjustment for baseline characteristics, time from symptom onset to balloon inflation is significantly correlated with 1-year mortality in patients undergoing primary PCI for STEMI (RR equals 1.08 for each 30-minute delay from symptom onset to balloon inflation, p equals 0.04) (Figure 21) (275). Given that the door-to-needle time goal is 30 minutes, this Writing Committee joins the Task Force on the Management of Acute Myocardial Infarction of the European Society of Cardiology in lowering the recommended medical contact–to balloon or door-to-balloon time goal from 120 to 90 minutes in an attempt to maximize the benefits for reperfusion by PCI (297) (Figure 22) (294).

If the expected door-to-balloon time exceeds the expected door-to-needle time by more than 60 minutes, fibrinolytic treatment with a fibrin-specific agent should be considered unless it is contraindicated. This is particularly important when symptom duration is less than 3 hours but is less important with longer symptom duration, when less ischemic myocardium can be salvaged. In both the CAPTIM trial (173), which showed lower mortality with prehospital fibrinolysis than with primary PCI, and the PRAGUE-2 trial (177), which showed lower mortality with primary PCI after interhospital transfer than with on-site fibrinolysis, PCI was superior to fibrinolysis when symptom duration was greater than 2 to 3 hours but not when symptom duration was shorter (see Section 6.3.1.6.2.1). In the early hours of STEMI, prompt fibrinolytic therapy can decrease infarct size and the risk of developing cardiogenic shock (176).

6.3.1.6.4.2.1. Complications of primary PCI.

Potential complications of an invasive strategy for treating STEMI include problems with the arterial access site; adverse reactions to volume loading, contrast medium, and antithrombotic medications; technical complications; and reperfusion events. Reocclusion occurs in 10% to 15% of patients after PTCA but in fewer than 5% after stent implantation. Likewise, angiographic restenosis occurs in 30% to 40% of patients after PTCA but in 15% to 20% after stent implantation. The management of these complications is beyond the scope of this guideline (430-432).

6.3.1.6.4.2.2. Primary PCI in fibrinolytic-ineligible patients.

Class I
Primary PCI should be performed in fibrinolyticineligible patients who present with STEMI within 12 hours of symptom onset. (Level of Evidence: C)

Class IIa
It is reasonable to perform primary PCI for fibrinolytic-ineligible patients with onset of symptoms within the prior 12 to 24 hours and 1 or more of the following:
a. Severe CHF (Level of Evidence: C)

b. Hemodynamic or electrical instability (Level of Evidence: C)

c. Persistent ischemic symptoms. (Level of Evidence: C)

Randomized controlled trials evaluating the outcome of PCI for patients who present with STEMI but who are ineligible for fibrinolytic therapy have not been performed. Few data are available to characterize the value of primary PCI for this subset of patients with STEMI; however, the recommendations in Section 4.2 are applicable to these patients. Nevertheless, these patients are at increased risk for mortality (433), and there is a general consensus that PCI is an appropriate means for achieving reperfusion in those who cannot receive fibrinolytics because of increased risk of bleeding (403,434-436).

6.3.1.6.4.2.3. Primary PCI without on-site cardiac surgery.

Class IIb
Primary PCI might be considered in hospitals without on-site cardiac surgery, provided that a proven plan for rapid transport to a cardiac surgery operating room exists in a nearby hospital with appropriate hemodynamic support capability for transfer. The procedure should be limited to patients with STEMI or MI with new, or presumably new, LBBB on ECG, and should be done in a timely fashion (balloon inflation within 90 minutes of presentation) by persons skilled in the procedure (at least 75 PCIs per year) and at hospitals performing a minimum of 36 primary PCI procedures per year. (Level of Evidence: B)

Class III
Primary PCI should not be performed in hospitals without on-site cardiac surgery capabilities and without a proven plan for rapid transport to a cardiac surgery operating room in a nearby hospital or without appropriate hemodynamic support capability for transfer. (Level of Evidence: C)

Reports on emergency primary PCI from hospitals without established open heart surgery or elective PCI programs have demonstrated generally favorable results (307,437-450). PCI in the early phase of an acute STEMI can be difficult and requires even more skill and experience than routine PCI in the stable patient. The need for an experienced operator and experienced laboratory technical support with availability of the broad range of catheters, guidewires, stents, and other devices (e.g., intra-aortic balloon pump [IABP]) required for optimum results in an acutely ill patient is of major importance. Careful patient selection and continuous quality improvement are critical components of a successful program. If these complex patients are treated by interventionalists with limited experience at hospitals with low volume, then the gains of early intervention may be lost because of increased complications. In such circumstances, transfer to a center that routinely performs complex PCI will often be a more effective and efficient course of action. Fibrinolysis is an acceptable form of therapy and is preferable to primary PCI by an inexperienced team.

Criteria have been suggested for the performance of primary PCI at hospitals without on-site cardiac surgery (432,445) (Tables 16 and 17). Large-scale registries have shown an inverse relationship between the number of primary PCI procedures performed and in-hospital mortality (295,303,304). The data suggest that both door-to-balloon time and in-hospital mortality are significantly lower in institutions that perform a minimum of 36 primary PCI procedures per year (295). Suboptimal results may relate to operator/staff inexperience and capabilities and to delays in performing PCI for logistical reasons. From clinical data and expert consensus, the Committee recommends that primary PCI for acute STEMI performed at hospitals without established elective PCI programs should be restricted to those institutions capable of performing a requisite minimum number of primary PCI procedures (36 per year) with a proven plan for rapid and effective PCI and rapid access to cardiac surgery in a nearby hospital. The benefit of primary PCI is not well established for operators who perform fewer than 75 PCIs per year or in a hospital that performs fewer than 36 primary PCI procedures per year. In addition, the benefit of timely reperfusion of the infarct artery by primary PCI at sites without on-site surgery must be weighed against the small but finite risk of harm to the patient related to the time required to transfer the patient to a site with CABG surgery capabilities (452,453).

6.3.1.6.4.2.4. Interhospital transfer for primary PCI.

The enthusiasm for primary PCI has led to the concept of emergency interhospital transfer for catheter-based reperfusion rather than fibrinolytic therapy in the initial hospital (454-456). Complication rates are low during transport, but time to reperfusion is delayed, which results in larger infarct size and lower LVEF (457). However, as noted in Section 6.3.1.6.2.1, selection bias of patients enrolled in randomized trials likely resulted in an underestimation of the risk of interhospital transfer expected in routine practice. Five randomized trials enrolled 2466 patients, with favorable results for PCI versus fibrinolytic therapy (177,306,408,419,421). Mortality was reduced with PCI (6.8% versus 9.6%, RR 0.69, 95% CI 0.51 to 0.0.92, p equals 0.01), as was the combined end point of death, nonfatal reinfarction, and stroke (8.5% versus 15.5%, RR 0.51, 95% CI 0.39 to 0.65, p less than 0.0001). Importantly, mean time to treatment was delayed only 44 minutes in these studies (Figure 23) (177,306). In contrast, the time from presentation at the door of the first hospital to balloon inflation in the second hospital, as recorded in 1346 patients in NRMI-4, was 185 minutes in the United States in 2002 (Figure 24) (458). Emergency transport in Europe is centrally organized and more efficient than in the United States (Table 18) (177, 306, 408, 419, 421, 459) (Van de Werf; oral presentation, American College of Cardiology 52nd Annual Scientific Session, Chicago, IL, March 2003). Delays in door-to-balloon time versus door-to-needle time of more than 60 minutes because of interhospital transfer might negate the potential mortality benefit of transfer for primary PCI over immediate intravenous fibrinolysis with a fibrin-specific agent as shown in these trials (305). To achieve optimal results, time from the first hospital door to the balloon inflation in the second hospital should be as short as possible, with a goal of within 90 minutes. Significant reductions in door-to-balloon times might be achieved by directly transporting patients to PCI centers rather than transporting them to the nearest hospital, if interhospital transfer will subsequently be required to obtain primary PCI.

6.3.1.6.4.3. Primary Stenting

Of the 22 randomized trials that compared primary PCI with fibrinolytic therapy, 12 involved a comparison of primary PCI with stenting and fibrinolytic therapy (40, 173, 177, 306, 307, 408, 409, 414, 417-421). These investigations demonstrate that PCI-treated patients experience lower mortality rates (5.9% versus 7.7%, OR 0.75, 95% CI 0.60 to 0.94, p equals 0.013), less reinfarction (1.6% versus 5.1%, OR 0.31, 95% CI 0.21 to 0.44, p equals 0.0001), and less hemorrhagic stroke than those treated by fibrinolysis (40). Compared with PTCA, intracoronary stents achieve a better immediate angiographic result with a larger arterial lumen, less reocclusion and restenosis of the infarct-related artery, and fewer subsequent ischemic events.

Primary stenting has been compared with primary angioplasty in 9 studies (38,37,460-467). There were no differences in mortality (3.0% versus 2.8%) or reinfarction (1.8% versus 2.1%) rates. However, major adverse cardiac events were reduced, driven by the reduction in subsequent targetvessel revascularization with stenting (Figure 25) (37).

Preliminary reports suggest that compared with conventional bare metal stents, drug-eluting stents are not associated with increased risk when used for primary PCI in patients with STEMI (468). Postprocedure vessel patency, biomarker release, and the incidence of short-term adverse events were similar in patients receiving sirolimus (n equals 186) or bare metal (n equals 183) stents. Thirty-day event rates of death, reinfarction, or revascularization were 7.5% versus 10.4%, respectively (p equals 0.4) (468).

6.3.1.6.4.4. Facilitated PCI

Class IIb
Facilitated PCI might be performed as a reperfusion strategy in higher-risk patients when PCI is not immediately available and bleeding risk is low. (Level of Evidence: B)

Facilitated PCI refers to a strategy of planned immediate PCI after an initial pharmacological regimen such as fulldose fibrinolysis, half-dose fibrinolysis, a GP IIb/IIIa inhibitor, or a combination of reduced-dose fibrinolytic therapy and a platelet GP IIb/IIIa inhibitor. Facilitated PCI should be differentiated from primary PCI without fibrinolysis or GP IIb/IIIa inhibitor therapy, from primary PCI with a GP IIb/IIIa inhibitor started at the time of PCI, and from rescue PCI after unsuccessful fibrinolysis. Potential advantages include earlier time to reperfusion, improved patient stability, greater procedural success rates, higher TIMI flow rates, and improved survival rates (36, 346, 428, 469, 470). However, preliminary studies have not demonstrated any benefit in reducing infarct size or improving outcomes (471-473). It is unlikely that this strategy would be beneficial in low-risk patients. A strategy of facilitated PCI holds promise in higher-risk patients when PCI is not immediately available. Potential risks include increased bleeding complications, especially in those 75 years of age or older (see Section 6.3.1.6.3.8), and potential limitations include added cost. Several randomized trials of facilitated PCI with a variety of pharmacological regimens are in progress (473a).

6.3.1.6.4.5. Rescue PCI

Class I
1. Rescue PCI should be performed in patients less than 75 years old with ST elevation or LBBB who develop shock within 36 hours of MI and are suitable for revascularization that can be performed within 18 hours of shock unless further support is futile because of the patient’s wishes or contraindications/unsuitability for further invasive care. (Level of Evidence: B)

2. Rescue PCI should be performed in patients with severe CHF and/or pulmonary edema (Killip class 3) and onset of symptoms within 12 hours. (Level of Evidence: B)

Class IIa
1. Rescue PCI is reasonable for selected patients 75 years or older with ST elevation or LBBB or who develop shock within 36 hours of MI and who are suitable for revascularization that can be performed within 18 hours of shock. Patients with good prior functional status who are suitable for revascularization and who agree to invasive care may be selected for such an invasive strategy. (Level of Evidence: B)

2. It is reasonable to perform rescue PCI for patients with 1 or more of the following:
a. Hemodynamic or electrical instability (Level of Evidence: C)

b. Persistent ischemic symptoms. (Level of Evidence: C)

Immediately after failed fibrinolysis. Intravenous fibrinolytic therapy successfully restores coronary TIMI 2/3 flow at 90 minutes in 50% to 85% of patients with STEMI (474). In those in whom fibrinolysis is unsuccessful, antegrade coronary flow can usually be restored with PCI. Several studies have demonstrated the marked beneficial effect of infarctrelated artery patency (obtained via endogenous, pharmacological, or mechanical recanalization) on survival in patients with STEMI (475,476). Survivors of STEMI with a patent infarct-related artery demonstrated at 90 minutes after treatment have an improved long-term outcome compared with those with an occluded infarct-related artery, even when LV systolic function is similar (476). Rescue (also known as salvage) PCI is defined as PCI within 12 hours after failed fibrinolysis for patients with continuing or recurrent myocardial ischemia. Rescue PCI has resulted in higher rates of early infarct artery patency, improved regional infarct-zone wall motion, and greater freedom from adverse in-hospital events than with a deferred PCI strategy or medical therapy. The Randomized Evaluation of Rescue PCI with Combined Utilization End Points (RESCUE) trial demonstrated a reduction in rates of in-hospital death and a combined end point of death and CHF that was maintained up to 1 year after study entry for patients presenting with anterior STEMI who failed fibrinolytic therapy, when PCI was performed within 8 hours after the onset of symptoms (477). Improvement in TIMI grade flow from less than or equal to 2 to 3 may offer additional clinical benefit. Similar data are not available for patients with nonanterior STEMI.

A major problem in adopting a strategy of rescue PCI lies in the limitation of accurate identification of patients for whom fibrinolytic therapy has not restored antegrade coronary flow. Unless unsuccessful fibrinolysis is recognized and corrected quickly (within 3 to 6 hours of onset of symptoms), salvage of ischemic myocardium is unlikely. Unfortunately, clinical markers of reperfusion, such as relief of ischemictype chest discomfort, partial resolution of ST-segment elevation, and reperfusion arrhythmias, have limited predictive value in identifying failure of fibrinolysis (478). In a prior era in which the practice of PCI was less mature, immediate catheterization of all patients after fibrinolytic therapy to identify those with an occluded infarct artery was found to be impractical, costly, and often associated with bleeding complications (479, 480). This strategy is being re-evaluated in clinical trials testing facilitated PCI in the contemporary PCI setting.

Even in the patient with documented failure of fibrinolysis, rescue PCI has limitations. Because extensive myocardial necrosis occurs when coronary occlusion has been present for more than 3 hours (18), PCI may not salvage a substantial amount of myocardium, considering the time delay associated with presentation of the patient to the hospital after onset of symptoms, infusion of the fibrinolytic agent, recognition of failed fibrinolysis, and subsequent initiation of PCI. Rescue PCI fails to reestablish antegrade coronary flow in approximately 10% of patients, and reocclusion of the infarct artery occurs in as many as 20% of the remainder (481), although use of GP IIb/IIIa inhibitors and stent implantation may improve these results. Unsuccessful rescue PCI is associated with a high mortality rate (482,483). Finally, coronary reperfusion occurs over the subsequent hours after fibrinolytic therapy in many patients. Although infarct artery patency is achieved in only 50% to 85% of patients 90 minutes after fibrinolytic therapy, it rises to 90% by 24 hours (474). Such late reperfusion may improve survival without the risk of invasive procedures coupled with fibrinolytic therapy. Confounding the issue, both fibrinolytic therapy and PCI may successfully restore flow in the epicardial artery but fail to improve microvascular perfusion.

Hours to days after failed fibrinolysis. Patency of thee infarctrelated artery is an important predictor of mortality in survivors of STEMI (475,476). Compared with those with a patent infarct artery, survivors of STEMI with a persistently occluded artery after fibrinolysis, PCI, or no reperfusion therapy have 1) increased LV dilatation (484), 2) a greater incidence of spontaneous and inducible ventricular arrhythmias (485), and 3) a poorer prognosis (486). On the basis of observational and experimental data, it has been hypothesized that infarct artery patency may favorably influence LV remodeling and electrical stability, even if accomplished at a time when salvage of ischemic myocardium is unlikely (i.e., more than 12 hours to days after coronary artery occlusion). Five small randomized trials, which enrolled a total of 562 patients, have directly tested the hypothesis that mechanical opening of persistent total occlusions late after MI will improve long-term LV remodeling and clinical outcomes (the late open-artery hypothesis). Most studies enrolled a combination of patients that included those who had failed fibrinolysis and those who had not received reperfusion therapy (487-489), with a range from almost no fibrinolytic therapy (490) to fibrinolytic therapy in nearly all patients (491). There was wide variation in the effect of routine PCI compared with only medical therapy on LV size and function. Most studies showed no significant differences between the treatment groups (487,488). One single-center study of 83 patients with occlusions of the left anterior descending coronary artery (LAD) reported improved LV volumes and clinical outcomes (composite of CHF, MI, and death) at 6 months in the PCI group (490). In contrast, a multicenter study of 66 patients with LAD occlusions reported significantly worse LV remodeling, with progressive LV dilation at 1 year and more clinical events in the PCI group than in those assigned to optimal medical therapy alone (491). The latter included very high rates of beta-blocker and ACE inhibitor use. The largest multicenter study, DECOPI, enrolled 212 patients and reported no difference in the primary end point, the composite of death, VT, and MI at 6 months (Steg PG; oral presentation, European Society of Cardiology Congress 2003, Vienna, Austria, September 2003). Stents were used in 80% of patients in the PCI group, and GP IIb/IIIa antagonists were used in 9%. The study reached fewer than one third of the target sample size and was severely underpowered, as were all the other studies, to assess clinical events.

There are no convincing data to support the routine use of adjuvant PCI days after failed fibrinolysis or for patients who do not receive reperfusion therapy. Nevertheless, this is being done in some patients with STEMI as an extension of the invasive strategy for patients with NSTEMI. The Occluded Artery Trial (OAT) is currently randomizing patients to test whether routine PCI days to weeks after MI improves longterm clinical outcomes in asymptomatic high-risk patients with an occluded infarct related artery (493).

6.3.1.6.4.6. PCI for Cardiogenic Shock

Class I
Primary PCI is recommended for patients less than 75 years old with ST elevation or LBBB who develop shock within 36 hours of MI and are suitable for revascularization that can be performed within 18 hours of shock unless further support is futile because of the patient’s wishes or contraindications/unsuitability for further invasive care. (Level of Evidence: A)

Class IIa
Primary PCI is reasonable for selected patients 75 years or older with ST elevation or LBBB who develop shock within 36 hours of MI and are suitable for revascularization that can be performed within 18 hours of shock. Patients with good prior functional status who are suitable for revascularization and agree to invasive care may be selected for such an invasive strategy. (Level of Evidence: B)

Observational studies support the value of PCI for patients who develop cardiogenic shock in the early hours of STEMI. For patients who do not have mechanical causes of shock, such as acute MR or septal or free wall rupture, mortality among those having PCI is lower than for those treated medically. However, undergoing cardiac catheterization alone, with or without PCI, is associated with a lower mortality owing to patient selection bias (494).

Two small randomized clinical trials (301,495) have further clarified the role of emergency revascularization in STEMI complicated by cardiogenic shock. Both showed a statistically insignificant but clinically important absolute 9% reduction in 30-day mortality. In the SHOCK trial (301), the survival curves continued to progressively diverge such that at 6 months and 1 year, there was a significant mortality reduction with emergency revascularization (53% versus 66%, p less than 0.03) (184). The prespecified subgroup analysis of patients less than 75 years old showed an absolute 15% reduction in 30-day mortality (p less than 0.02), whereas there was no apparent benefit for the small cohort (n equals 56) of patients more than 75 years old. These data strongly support the approach that patients younger than 75 years with STEMI complicated by cardiogenic shock should undergo emergency revascularization and support measures.Three registries (496-498) have demonstrated a marked survival benefit for elderly patients who are clinically selected for revascularization (approximately 1 of 5 patients), so age alone should not disqualify a patient for early revascularization. (See Section 7.6.5.)

Several additional discussions elsewhere in this guideline are important to consider in these patients. Intra-aortic balloon pump support or ventricular assist devices can stabilize hemodynamics so that revascularization procedures can be performed (see Section 7.6.7.6). Post hoc analyses (499-501) have suggested that GP IIb/IIIa inhibitors reduce mortality, but the studies are limited by lower than expected mortality rates, larger than expected mortality reduction, and small sample sizes (see Section 6.3.1.6.8.2.3). Although PCI in a noninfarct artery is not recommended in stable patients, it can be beneficial in hemodynamically compromised patients if the stenotic artery perfuses a large area of myocardium and the procedure can be done efficiently. In patients with significant left main disease or severe 3-vessel disease and without RV infarction or major comorbidities such as renal insufficiency or severe pulmonary disease, CABG can be considered as the revascularization strategy (see Section 6.3.1.6.5) (Figure 26) (502).

6.3.1.6.4.7. Percutaneous Coronary Intervention After Fibrinolysis

Class I
1. In patients whose anatomy is suitable, PCI should be performed when there is objective evidence of recurrent MI. (Level of Evidence: C)

2. In patients whose anatomy is suitable, PCI should be performed for moderate or severe spontaneous or provocable myocardial ischemia during recovery from STEMI. (Level of Evidence: B)

3. In patients whose anatomy is suitable, PCI should be performed for cardiogenic shock or hemodynamic instability. (See Section 6.3.1.6.4.6.) (Level of Evidence: B)

Class IIa
1. It is reasonable to perform routine PCI in patients with LVEF less than or equal to 0.40, CHF, or serious ventricular arrhythmias. (Level of Evidence: C)

2. It is reasonable to perform PCI when there is documented clinical heart failure during the acute episode, even though subsequent evaluation shows preserved LV function (LVEF greater than 0.40). (Level of Evidence: C)

Class IIb
Routine PCI might be considered as part of an invasive strategy after fibrinolytic therapy. (Level of Evidence: B)

Immediately after successful fibrinolysis. Randomized prospective trials examined the efficacy and safety of immediate PCI after fibrinolysis (479,480,503). These trialsshowed no benefit of routine PCI of the stenotic infarct-related artery immediately after fibrinolytic therapy. The strategy did not appear to salvage myocardium, improve LVEF, or prevent reinfarction or death. Those subjected to this approach appeared to have an increased incidence of adverse events, including bleeding, recurrent ischemia, emergency CABG, and death. These studies have not been repeated in the modern interventional era with improved equipment, improved antiplatelet and anticoagulant strategies, and coronary stents, thus leaving the question of routine PCI early after successful fibrinolysis unresolved in contemporary practice. Studies of facilitated PCI are presently enrolling patients (36,396,471,504).

Hours to days after successful fibrinolysis. It was initially suggested that elective PCI of the stenotic infarct-related artery hours to days after fibrinolysis might allow sufficient time for development of a more stable hemostatic milieu at the site of previous thrombotic occlusion. In this setting, PCI would be safer and more effective in reducing the incidence of reocclusion and improving survival. Two large randomized, prospective trials from an earlier PCI era tested this hypothesis, with both concluding that 1) there are fewer complications if PCI is delayed for several days after fibrinolytic therapy and 2) routine PCI in the absence of spontaneous or provocable ischemia does not improve LV function or survival (268,505-507). Thus, in unselected patients receiving fibrinolytic therapy, PCI of the stenotic infarctrelated artery in the absence of evidence of recurrent ischemia within 48 hours did not appear to be beneficial.

Great improvements in equipment, operator experience, and adjunctive pharmacotherapy have increased PCI success rates and decreased complications. More recently, the invasive strategy for patients with NSTEMI has been given a Class I recommendation by the ACC/AHA 2002 Guideline Update for the Management of Patients With Unstable Angina/NSTEMI (4). Patients with STEMI are increasingly being treated similarly as an extension of this approach. Although 6 published reports (472,508-512) and 1 preliminary report (Lablanche JM; oral presentation, American Heart Association 2002 Annual Scientific Sessions, November 2002, Chicago, IL) support this strategy, randomized studies similar to those in NSTEMI need to be performed.

One study supports the policy of performing catheterization and subsequent revascularization for patients who do have spontaneous or inducible angina after STEMI. The DANAMI trial (515) randomly assigned 1008 survivors of a first acute MI treated with fibrinolytic therapy within 12 hours of onset of symptoms to catheterization and subsequent revascularization or standard medical therapy if they showed evidence of spontaneous or inducible angina. Those who underwent revascularization had less unstable angina and fewer nonfatal MIs during a 2.5-year period of follow-up compared with those patients randomly assigned to medical treatment only (18% and 5.6% versus 30% and 10.5%, respectively).

Days to weeks after successful fibrinolysis. Continued thrombus lysis and remodeling of the infarct artery stenosis occur over the days to weeks after successful fibrinolysis, which makes the underlying residual coronary stenosis more stable and less prone to rethrombosis and reocclusion. Thus, delaying PCI for days to weeks after fibrinolysis might improve survival, even though earlier routine PCI does not. To date, there have not been adequately sized trials to evaluate this treatment strategy. Two older, small, randomized trials (516,517) demonstrated similar LV function, rates of reinfarction, and mortality in patients randomized to PCI or conservative therapy.

6.3.1.6.5. Acute Surgical Reperfusion.

Class I
Emergency or urgent CABG in patients with STEMI should be undertaken in the following circumstances:
a. Failed PCI with persistent pain or hemodynamic instability in patients with coronary anatomy suitable for surgery. (Level of Evidence: B)

b. Persistent or recurrent ischemia refractory to medical therapy in patients who have coronary anatomy suitable for surgery, have a significant area of myocardium at risk, and are not candidates for PCI or fibrinolytic therapy. (Level of Evidence: B)

c. At the time of surgical repair of postinfarction VSR or mitral valve insufficiency. (Level of Evidence: B)

d. Cardiogenic shock in patients less than 75 years old with ST elevation or LBBB or posterior MI who develop shock within 36 hours of STEMI, have severe multivessel or left main disease, and are suitable for revascularization that can be performed within 18 hours of shock, unless further support is futile because of the patient’s wishes or contraindications/unsuitability for further invasive care (Level of Evidence: A)

e. Life-threatening ventricular arrhythmias in the presence of greater than or equal to 50% left main stenosis and/or triple-vessel disease. (Level of Evidence: B)

Class IIa
1. Emergency CABG can be useful as the primary reperfusion strategy in patients who have suitable anatomy and who are not candidates for fibrinolysis or PCI and who are in the early hours (6 to 12 hours) of an evolving STEMI, especially if severe multivessel or left main disease is present. (Level of Evidence: B)

2. Emergency CABG can be effective in selected patients 75 years or older with ST elevation, LBBB, or posterior MI who develop shock within 36 hours of STEMI, have severe triple-vessel or left main disease, and are suitable for revascularization that can be performed within 18 hours of shock. Patients with good prior functional status who are suitable for revascularization and agree to invasive care may be selected for such an invasive strategy. (Level of Evidence: B)

Class III
1. Emergency CABG should not be performed in patients with persistent angina and a small area of risk who are hemodynamically stable. (Level of Evidence: C)

2. Emergency CABG should not be performed in patients with successful epicardial reperfusion but unsuccessful microvascular reperfusion. (Level of Evidence: C)

These recommendations are supplementary to those published recently in a more complete set of general guidelines and indications for CABG (518) and are restricted to patients with STEMI and associated complications. The basis for recommending surgery in emergency circumstances is the documented benefit of CABG for severe multivessel disease or left main coronary artery stenosis, particularly with reduced LV function (518-521), with the recognition that risk of emergency CABG is greater than that for elective operation.

The widespread use of fibrinolysis and primary PCI has largely superseded CABG for acute reperfusion of patients with STEMI. However, CABG still plays an integral role in the early reperfusion strategy for some patients. In the PAMI (Primary Angioplasty in Myocardial Infarction)-2 trial (522), of 1100 patients with MI and without cardiogenic shock, 5% underwent CABG as the primary reperfusion strategy with STEMI. Mortality was 6.4% if surgery was undertaken on an urgent or emergency basis versus 2.0% if elective. Major risk factors for death included poor LV function and advanced age. In the setting of cardiogenic shock complicating STEMI, emergency CABG has been used where other interventions have failed or have not been indicated. In the SHOCK registry (523), of 136 patients undergoing emergency CABG for cardiogenic shock due to LV failure, mortality was 27.9% compared to 45.5% in 268 patients undergoing PTCA. For patients undergoing CABG within 18 hours of the onset of shock, mortality was 39.6%. In a review of 25 papers reporting the outcome of CABG in 391 patients with cardiogenic shock, mortality was 35% (524). In GUSTO-I, mortality in a similar group of patients was 29% (98 of 340) after CABG and 29% (165 of 567) (422,525,526) after PTCA. On the basis of these studies, emergency CABG should only be considered for patients with STEMI with severe coronary artery disease. In the SHOCK trial, emergency CABG was performed at a median of 14 hours after the onset of STEMI in 40% of those who underwent early revascularization; most of the patients undergoing CABG had significant left main or 3-vessel coronary artery disease. The 30-day mortality rate was similar to those with less severe coronary artery disease who underwent PTCA (42% versus 45%).

6.3.1.6.6. Patients With STEMI Not Receiving Reperfusion

Many patients with suspected STEMI do not receive reperfusion therapy. For some of these patients, the lack of treatment represents a missed opportunity. For others, patient preference led to a decision that the clinical benefit was not worth the risk of the therapy. Other patients may have contraindications to treatment owing to comorbid disease. Few studies have examined the care and outcomes of patients with suspected STEMI who do not receive reperfusion therapy. Many of the studies (e.g., beta-blocker trials) that established therapies for MI patients preceded the reperfusion era, and so their efficacy in patients with STEMI who did not receive reperfusion is clear. The acute use of aspirin was shown to be effective in patients who did and did not receive fibrinolytic therapy. Guideline-based recommendations for nonreperfusion treatments should not vary whether or not patients received reperfusion therapy. The major difference is that patients not receiving reperfusion therapy are considered to have a higher risk for future adverse events (261). (See Section 6.3.1.6.8.1.2 for discussion of the TETAMI trial.)

6.3.1.6.7. Assessment Of Reperfusion

Class IIa
It is reasonable to monitor the pattern of ST elevation, cardiac rhythm, and clinical symptoms over the 60 to 180 minutes after initiation of fibrinolytic therapy. Noninvasive findings suggestive of reperfusion include relief of symptoms, maintenance or restoration of hemodynamic and or electrical stability, and a reduction of at least 50% of the initial ST-segment elevation injury pattern on a follow-up ECG 60 to 90 minutes after initiation of therapy. (Level of Evidence: B)

A high priority exists for the development of simple, accurate, readily available noninvasive techniques to assess the success of pharmacological reperfusion early, i.e., 60 to 90 minutes after administration of therapy. Prior studies evaluating clinical and ECG outcome measures of reperfusion used angiographic TIMI 2 or 3 flow as the “gold standard”; angiographic assessment of epicardial flow is now considered inadequate to completely assess myocardial perfusion. Indeed, it is now clear that microvascular perfusion may be impaired despite achievement of TIMI 3 flow and less than 50% coronary narrowing; moreover, abnormal microperfusion has negative prognostic implications (395,527,528).

Myocardial contrast echocardiography, myocardial angiographic perfusion with assessment of angiographic blush in the myocardium, and ECG assessment of ST resolution are recognized as useful techniques for assessing myocardial perfusion. The relatively simple and readily available evaluation of the ECG ST-segment resolution that exceeds 50% at 60 to 90 minutes after reperfusion is a good indicator of enhanced myocardial perfusion (527). This finding is also associated with enhanced recovery of LV function, reduced infarct size, and improved prognosis (277,349,395,529-531). In the TIMI-14 study of 888 patients, those with TIMI 3 perfusion and greater than 70% ST-segment resolution had substantial enhancement of survival compared with those without ST-segment resolution and angiographically patent infarct arteries (531).

Santoro and colleagues (532) evaluated 158 consecutive patients with STEMI referred for direct angioplasty within 6 hours of symptom onset. In their observational study of patients with TIMI grade 3 flow and less than 30% residual stenosis, 42 patients had less than 50% reduction in maximal ST elevation in a single lead versus 75 patients with at least 50% reduction in ST elevation. Those with ST-segment resolution had enhanced infarct-zone functional recovery and improved ejection fraction. The reduction of ST-segment elevation was the only independent predictor of functional recovery.

Persistence of unrelenting ischemic chest pain, absence of resolution of the qualifying ST-segment elevation, and hemodynamic or electrical instability are generally indicators of failed pharmacological reperfusion and the need to consider rescue PCI. Aggressive medical support may be necessary in the interim. (See Section 6.3.1.6.4.5.)

6.3.1.6.8. Ancillary Therapy

Ancillary therapy plays a key role in the overall management of patients with STEMI and can be usefully categorized as conjunctive, in which case it facilitates and maintains coronary reperfusion, or adjunctive, which aims to limit the consequences of myocardial ischemia, enhance myocardial healing, and reduce the likelihood of recurrent events.

6.3.1.6.8.1. Antithrombins as Ancillary Therapy to Reperfusion Therapy

After rupture of a vulnerable or high-risk plaque, its contents are exposed to the passing bloodstream. Vulnerable plaques are laden with both lipid and collagen and are rich in tissue factor, thereby resulting in activation of the coagulation cascade, which ultimately results in the deposition f fibrin strands. In addition, platelets are activated and aggregate. Thrombin that is generated as a consequence of activation of the coagulation cascade is a pivotal molecule not only for the formation of fibrin strands but also for activation of platelets. Therefore, there is considerable rationale for ancillary therapy to inhibit the coagulation cascade in patients with STEMI, including both those who do and do not receive reperfusion therapy. The general term used to include agents that alter the function of 1 or more proteins in the coagulation cascade is antithrombins (533). However, such a broad term does not do justice to the biochemical complexities of agents that may inhibit the coagulation cascade at multiple positions (e.g., UFH and LMWH) or in a single position (e.g., direct antithrombins). In addition to establishing and maintaining patency of the infarct-related artery, the rationale for prescribing antithrombins in selected patients with STEMI includes prevention of DVT, pulmonary embolism, LV mural thrombus formation, and cerebral embolization.

6.3.1.6.8.1.1. Unfractionated heparin as ancillary therapy to reperfusion therapy.

Class I
1. Patients undergoing percutaneous or surgical revascularization should receive UFH. (Level of Evidence: C)

2. Unfractionated heparin should be given intravenously to patients undergoing reperfusion therapy with alteplase, reteplase, or tenecteplase with dosing as follows: bolus of 60 U/kg (maximum 4000 U) followed by an infusion of 12 U/kg/hr (maximum 1000 U) initially adjusted to maintain activated partial thromboplastin time (aPTT) at 1.5 to 2.0 times control (approximately 50 to 70 seconds). (Level of Evidence: C)

3. Unfractionated heparin should be given intravenously to patients treated with nonselective fibrinolytic agents (streptokinase, anistreplase, urokinase) who are at high risk for systemic emboli (large or anterior MI, atrial fibrillation (AF), previous embolus, or known LV thrombus). (Level of Evidence: B)

4. Platelet counts should be monitored daily in patients taking UFH. (Level of Evidence: C)

Class IIb
It may be reasonable to administer UFH intravenously to patients undergoing reperfusion therapy with streptokinase. (Level of Evidence: B)

Despite the use of UFH (533) in STEMI for over 40 years, there is continued controversy regarding its role. In patients who are treated with fibrinolytic therapy, recommendations for UFH therapy depend on the fibrinolytic agent chosen. The nonspecific fibrinolytic agents (streptokinase, anistreplase, and urokinase) that produce a systemic coagulopathy, including depletion of factors V and VIII and massive production of fibrin(ogen) degradation products, are themselves anticoagulants. From this perspective, the need for conjunctive systemic anticoagulation with these agents conceptually is less compelling. However, the procoagulant potential of streptokinase, which induces extensive plasmin-mediated thrombin activity, has been noted as the rationale for antithrombotics (534). The rationale for UFH is clear for the more fibrin-specific agents, such as alteplase, reteplase, and tenecteplase. They induce less effect on the systemic coagulation system, and in many patients, very little breakdown of fibrinogen or depletion of coagulation factors is evident (535,536). Furthermore, the same procoagulant increase in thrombin activity is seen (534).

Over 60 000 patients were enrolled in the randomized ISIS-3 (357) and GISSI-2 (Gruppo Italiano per lo Studio della Streptochinasi nell’Infarto Miocardico)/International (353,354) trials comparing subcutaneous UFH with no routine heparin in conjunction with streptokinase, anistreplase, and alteplase. During the period in which UFH was given, a small reduction in mortality (4 to 5 lives per 1000 treated) was observed in ISIS-3; however, by 30 days, the 2 to 3 lives saved per 1000 treated was no longer statistically significant. A small excess rate of hemorrhagic stroke (1 to 2 per 1000 treated patients) was observed together with a larger excess in systemic bleeding (3 to 5 per 1000 patients), although total stroke rate was not significantly increased. A meta-analysis of these and several smaller studies enrolling a total of 68 000 patients showed that 5 lives were saved per 1000 patients treated with UFH in addition to streptokinase (537). In the GUSTO-I trial (25), more than 20 000 patients treated with streptokinase were randomly assigned to routine intravenous versus routine subcutaneous UFH. No significant differences were observed in death, reinfarction, or non-hemorrhagic stroke rates, whereas excess rates of systemic bleeding and hemorrhagic strokes (trend) were observed in the intravenous UFH group. There was a 36% crossover rate from subcutaneous to intravenous UFH in this trial.

Several angiographic studies have evaluated coronary perfusion as a function of UFH therapy (538-540). More rapid resolution of ST-segment elevation has been reported in patients treated with intravenous UFH immediately at the time of streptokinase infusion than in those treated with intravenous heparin started at a later time, but the OSIRIS study (Optimization Study of Infarct Reperfusion Investigated by ST Monitoring) showed no difference in perfusion at 24 hours (539). In the GUSTO-I angiographic substudy, patients treated with intravenous UFH had an 88% patency rate at 5 to 7 days compared with a 72% rate in patients treated with subcutaneous UFH (p less than 0.05), although less reinfarction occurred in the subcutaneous UFH group (3.4% versus 4.0%, p less than 0.05) (538). When these angiographic studies are viewed as a whole, intravenous UFH appears to have no clinical advantage over subcutaneous administration when used with a nonspecific fibrinolytic agent, and the evidence for use of subcutaneous UFH is equivocal (541). There are few data comparing intravenous UFH to placebo.

The clinical importance of the procoagulant increase in thrombin activity after streptokinase administration is supported by the beneficial effect of newer antithrombins used in conjunction with streptokinase (see Section 6.3.1.6.8.1.3). The HERO (Hirulog and Early Reperfusion or Occlusion)-2 trial demonstrated reduced reinfarction with intravenous bivalirudin compared with intravenous UFH (33). The AMI-SK study demonstrated in patients treated with streptokinase improved ST-segment resolution at 180 minutes and higher rates of infarct-related artery patency at 8 days for enoxaparin compared with placebo. The composite of death, MI, and recurrent angina was reduced, but severe bleeding was increased (1.6% versus 0.8%), with no difference in ICH (0% to 0.4%) (542). Additionally, a preliminary report of 5- year GUSTO-I follow-up data demonstrated similar survival rates for streptokinase with UFH versus alteplase-assigned patients. In the context of these new data and the event reduction (5 fewer deaths per 1000 patients) demonstrated in the meta-analysis (537), the recommendation for intravenous UFH administration with non–fibrin-specific fibrinolytic agents was changed from Class III to Class IIb.

When alteplase is the fibrinolytic agent, the empirical information to confirm the pathophysiological reasoning discussed above is primarily inferential. In a series of angiographic trials (543-545), intravenous UFH led to higher rates of infarct-related artery perfusion in conjunction with alteplase. A direct relation between duration of aPTT and the likelihood of infarct-related artery perfusion was observed (544,545). An overview (546) points out, however, that the effects of intravenous UFH on clinical outcomes from these studies are not so convincing; a significant increase in the rate of bleeding and nonsignificant increases in rates of reinfarction and hemorrhagic and nonhemorrhagic stroke are evident (546). These negative findings are tempered by a point estimate of an 18% reduction in mortality with broad confidence limits. Until the uncertainty is resolved, it appears judicious to use UFH for at least 48 hours with alteplase and to target the aPTT to 1.5 to 2.0 times control (approximately 50 to 70 seconds).

When primary PCI is chosen as the route of reperfusion, weight-adjusted boluses of heparin of 70 to 100 U/kg are recommended. This recommendation does not come specifically from empirical data in the setting of STEMI but from general observations in the setting of angioplasty that an activated clotting time of at least 250 to 350 seconds with the HemoTec device and 300 to 350 seconds with the Hemochron device is associated with a lower rate of complications than lower activated clotting times (432,547,548).

When GP IIb/IIIa antagonists are used (see Section 6.3.1.6.8.2.3), the UFH bolus should be reduced to 50 to 70 U/kg to achieve a target activated clotting time of 200 seconds with either the HemoTec or Hemochron device (432). UFH doses used during PCI for failed fibrinolysis should be similarly reduced and further lowered if used with GP IIb/IIIa antagonists as well.

The dose of UFH in the fibrinolytic-treated patient remains somewhat controversial. Given the infarct-related artery perfusion results just described, it would be reasonable to recommend an aPTT value more than 3-fold higher than the median control value. However, observational data strongly support a lower aPTT, because death, stroke, reinfarction, and bleeding were found to be lowest in the aPTT range of 50 to 70 seconds, or approximately 1.5 to 2.0 times the control value (549). Because of the evidence that the measured effect of UFH on the aPTT is important for patient outcome and that the predominant variable mediating the effect of a given dose of heparin is weight (549), it is important to administer the initial doses of UFH as a weight-adjusted bolus (541). For fibrin-specific (alteplase, reteplase, and tenecteplase) fibrinolytic-treated patients, a 60 U/kg bolus followed by a maintenance infusion of 12 U/kg/h (with a maximum of 4000 U bolus and 1000 U/h initial infusion for patients weighing more than 70 kg) is recommended. The recommended weight adjusted dose of UFH, when it is administered without fibrinolytics, is a 60 to 70 U/kg IV bolus and a 12 to 15 U/kg/h infusion (4). Higher UFH doses are required for DVT and pulmonary embolism (80 U/kg and 18 U/kg/h) (550,551). Other factors that prolong aPTT include age, sex, and creatinine level. Elderly women may require lower bolus doses. Diabetics, smokers, and very heavy patients (weight more than 100 kg) may require higher UFH doses (550,552). When used with fibrinolytic therapy, an aPTT goal of 60 to 90 seconds is associated with an unacceptably high rate of ICH (359,553). The recommendation of an aPTT of 50 to 70 seconds was based on the GUSTO trials and supported by an overview of several fibrinolytic trials (325,380). ASSENT-3 was the first large-scale trial that used the recommended reduced-dose weight-adjusted UFH regimen (31). This regimen resulted in similar ICH rates but less bleeding than the higher dose used in ASSENT-2, without an increase in ischemic events. An aPTT measurement and dose adjustment are required beginning at 3 hours for those who receive UFH with fibrinolytics (28). The aPTT should be remeasured 6 hours after each dose adjustment until it is in the target range and daily thereafter. There is wide variability in aPTT measurement between laboratories, and it is not known what UFH level, as measured by anti-Xa activity, corresponds with an aPTT of 50 to 70 seconds. However, for most thromboplastin reagents, this corresponds to 0.2 to 0.5 U/mL heparin by anti-Xa activity.

Once UFH has been started, the appropriate duration of therapy is uncertain. The only randomized trial to address this issue found that discontinuation of UFH after 24 hours after fibrinolytic therapy with alteplase resulted in no measurable increase in ischemic events (554), although this study did not have adequate power to detect modest differences. A reasonable approach is to use intravenous UFH for 48 hours and then to use UFH according to the clinical characteristics of the patient. UFH may be discontinued in low-risk patients, given subcutaneously in patients at high risk of systemic embolization, and given intravenously in patients at high risk for coronary reocclusion.

There is concern that when UFH is discontinued abruptly, the patient undergoes a high-risk period for recurrent thrombosis (heparin rebound) because of increased thrombin activity (555,556). Despite this concern, no specific policy has been tested to attempt to reduce this clinical rebound effect. Several ongoing studies, however, are reducing UFH infusions in a gradual fashion (e.g., by half within 6 hours, then discontinuing over the subsequent 12 hours).

Platelet counts should be monitored daily in patients being treated with UFH. Evidence suggests the incidence of heparin-induced thrombocytopenia is 3% and that this is associated with a substantial risk of prothrombotic events (557). If the platelet count drops below 100 000, a test for heparin-induced thrombocytopenia should be obtained, and the clinician should be vigilant for thrombotic complications,because the prognosis in patients with thrombocytopenia is substantially worse (558).

6.3.1.6.8.1.2. Low-molecular-weight heparin as ancillary therapy to reperfusion therapy.

Class IIb
Low-molecular-weight heparin might be considered an acceptable alternative to UFH as ancillary therapy for patients aged less than 75 years who are receiving fibrinolytic therapy, provided that significant renal dysfunction (serum creatinine greater than 2.5 mg/dL in men or 2.0 mg/dL in women) is not present. Enoxaparin (30-mg IV bolus followed by 1.0 mg/kg SC every 12 hours until hospital discharge) used in combination with full-dose tenecteplase is the most comprehensively studied regimen in patients aged less than 75 years of age. (Level of Evidence: B)

Class III
1. Low-molecular-weight heparin should not be used as an alternative to UFH as ancillary therapy in patients aged more than 75 years who are receiving fibrinolytic therapy. (Level of Evidence: B)

2. Low-molecular-weight heparin should not be used as an alternative to UFH as ancillary therapy in patients less than 75 years who are receiving fibrinolytic therapy but have significant renal dysfunction (serum creatinine greater than 2.5 mg/dL in men or 2.0 mg/dL in women). (Level of Evidence: B)

There have been no definitive phase III randomized trials of LMWH in patients with STEMI to provide a firm basis for recommendations. However, a number of phase II clinical trials provide encouraging information that suggests that LMWH may be an attractive alternative to UFH. These clinical trials include those with LMWH as ancillary therapy to fibrinolysis and those in patients not receiving fibrinolysis (31,158,542,559-567). These 2 broad categories of trials with LMWH involve either enoxaparin or dalteparin, the 2 LMWHs studied most extensively in patients with STEMI. Clinical evaluation of LMWH as ancillary therapy to most of the commonly prescribed fibrinolytics has been reported with the exception of reteplase (Table 19) (31,158,542,559-567).

The available data suggest that the rate of early (60 to 90 minutes) reperfusion of the infarct artery either assessed angiographically or by noninvasive means is not enhanced by administration of a LMWH. However, a generally consistent theme of a lower rate of reocclusion of the infarct artery, reinfarction, or recurrent ischemic events emerges in patients receiving LMWH regardless of whether the control group was given placebo or UFH.

The most comprehensive data available are from the ASSENT-3 trial, in which patients received tenecteplase and either UFH (bolus 60 U/kg; initial infusion 12 U/kg/h; duration of treatment equals 48 hours) or enoxaparin (bolus 30 mg; subcutaneous injections 1.0 mg/kg every 12 hours; duration of treatment equals duration of hospital stay) (31). Eachof the elements of the composite end point of 30-day mortality, in-hospital reinfarction, or in-hospital recurrent ischemia were reduced with enoxaparin treatment. This was associated with a slight, nonsignificant increase in noncerebral bleeding complications. In patients aged more than 75 years, the rate of noncerebral major bleeds was 4.1% with UFH and 7.2% with enoxaparin. Patients with significant renal dysfunction (serum creatinine greater than 2.5 mg/dL for men and greater than 2 mg/dL for women) were excluded from ASSENT-3, and therefore enoxaparin cannot be recommended for use in combination with tenecteplase in patients with severe renal dysfunction until more data are available. At 1 year, no difference was noted in the composite end point noted above between the UFH and enoxaparin groups in ASSENT-3 (31).

However, results from the third Assessment of the Safety and Efficacy of a New Thrombolytic PLUS (ASSENT-3 PLUS) trial underscore the need for continued evaluation of the safety of LMWH as an adjunct to fibrinolysis (158). Among 1639 patients with STEMI receiving tenecteplase and either enoxaparin or UFH in a prehospital setting, higher rates of both major bleeding (4.0% versus 2.8%; p equals 0.18) and ICH (2.2% versus 1.0%; p equals 0.05) were seen in the enoxaparin group than in the UFH group. There was a significant interaction between patient age and risk of bleeding because almost all cases of excess ICH were confined to patients older than 75 years (158,568). The Enoxaparin and Thrombolysis Reperfusion for Acute Myocardial Infarction Treatment-Thrombolysis In Myocardial Infarction - Study 25 (EXTRACT-TIMI-25) trial is evaluating enoxaparin versus UFH in patients receiving fibrinolytic therapy and will provide information on the efficacy and safety of reduced doses of enoxaparin in the elderly.

The combination of tirofiban and enoxaparin was studied in 1224 patients presenting with STEMI in the Treatment of Enoxaparin and Tirofiban in Acute Myocardial Infarction (TETAMI) trial (566). Patients ineligible for fibrinolysis were randomized in a 2×2 fashion to receive either enoxaparin (intravenous 30 mg bolus and subcutaneous injection of 1 mg/kg twice daily) or UFH (intravenous 70 U/kg bolus and 15 U/kg/h infusion) with or without tirofiban (intravenous 10 mcg/kg bolus and 0.1 mcg/kg/min infusion) for 2 to 8 days. There were no differences noted in the primary efficacy end point (30-day combined incidence of death, reinfarction, or recurrent angina) between either enoxaparin and UFH monotherapy groups (15.4% versus 17.3%) or between enoxaparin and UFH combination groups (16.1% versus 17.2%). Major bleeding was rare and not statistically different among all 4 groups.

6.3.1.6.8.1.3. Direct antithrombins as ancillary therapy to reperfusion therapy.

Class IIa
In patients with known heparin-induced thrombocytopenia, it is reasonable to consider bivalirudin as a useful alternative to heparin to be used in conjunction with streptokinase. Dosing according to the HERO 2 regimen (a bolus of 0.25 mg/kg followed by an intravenous infusion of 0.5 mg/kg/h for the first 12 hours and 0.25 mg/kg/h for the subsequent 36 hours) (33) is recommended, but with a reduction in the infusion rate if the partial thromboplastin time is above 75 seconds within the first 12 hours. (Level of Evidence: B)

A number of direct thrombin inhibitors are now available for use in heparin-induced thrombocytopenia and DVT but have not yet been approved for the treatment of acute coronary syndrome (Table 20) (39,359,368,382,383,553,569-573). One, (bivalirudin) has been approved for use in patients with unstable angina undergoing PCI. A meta-analysis evaluated 11 trials that collectively enrolled more than 35 000 patients, comparing direct thrombin inhibitors with UFH (39). There was an approximately 25% reduction in the incidence of MI in patients with STEMI treated with either hirudin or bivalirudin, but there was less evident efficacy for univalent thrombin inhibitors (argatroban, efegatran, and inogatran). Major bleeding was reduced with bivalirudin compared with heparin (4.2% versus 9.0%; OR 0.44 [0.34 to 0.56]). There was an excess of bleeding after the use of hirudin and no difference with univalent inhibitors; statistical heterogeneity among these 3 groups of trials existed (39). Subsequent to the meta-analysis, a large phase 3 study (HERO-2) of 17 073 patients with STEMI who presented within 6 hours of onset of chest pain was performed to evaluate the efficacy of bivalirudin versus UFH administered in conjunction with streptokinase (33). In the HERO-2 trial, bivalirudin did not reduce mortality compared with UFH (10.8% versus 10.9%) but was associated with a lower rate of adjudicated myocardial reinfarction within 96 hours (1.6% versus 2.3%, p equals 0.005). Although it was anticipated there would be fewer hemorrhagic complications with bivalirudin, severe bleeding occurred in 0.7% of the bivalirudin group versus 0.5% for heparin (p equals 0.07), and intracerebral bleeding occurred in 0.6% versus 0.4% (p equals 0.09), respectively, possibly related to higher aPTT levels in the bivalirudin group. The frequency of moderate and mild bleeding was also greater with bivalirudin (33,323). Bivalirudin is currently indicated only for anticoagulation in patients with unstable angina who are undergoing percutaneous coronary angioplasty (574). On the basis of the data in the HERO-2 trial, the Writing Committee believes that bivalirudin could be considered an acceptable alternative to UFH in those patients with STEMI who receive fibrinolysis with streptokinase, have heparin-induced thrombocytopenia, and who, in the opinion of the treating physician, would benefit from anticoagulation.

6.3.1.6.8.1.4. Other

A phase 2 angiographic trial Pentasaccharide as an Adjunct in ST-Segment Myocardial Infarction (PENTALYSE) evaluated fondaparinux, a synthetic pentasaccharide that is a highly selective inhibitor of factor Xa. Fondaparinux selectively binds antithrombin III, inducing a conformational change that increases the anti-Xa activity of antithrombin III more than 300 times, which results in dose-dependent inhibition of factor Xa (575). A total of 333 patients with evolving STEMI were treated with aspirin and alteplase and randomized to UFH given intravenously for 48 to 72 hours or to a low, medium, or high dose of fondaparinux. The percentage of patients achieving TIMI grade 3 flow at 90 minutes was 68% in the UFH control group and ranged between 60% and 69% with fondaparinux. Thus, selective factor Xa inhibition appears to be an attractive therapeutic concept in patients presenting with STEMI; however, further study is required before it can be recommended for routine administration.

6.3.1.6.8.2. Antiplatelets

6.3.1.6.8.2.1. Aspirin

Class I
A daily dose of aspirin (initial dose of 162 to 325 mg orally; maintenance dose of 75 to 162 mg) should be given indefinitely after STEMI to all patients without a true aspirin allergy. (Level of Evidence: A)

As discussed in Section 7.4.4 and Section 6.3.1.4, aspirin should be given to the patient with suspected STEMI as early as possible and continued indefinitely, regardless of the strategy for reperfusion and regardless of whether additional antiplatelet agents are administered. True aspirin allergy is the only exception to this recommendation.

6.3.1.6.8.2.2. Thienopyridines

Class I
1. In patients who have undergone diagnostic cardiac catheterization and for whom PCI is planned, clopidogrel should be started and continued for at least 1 month after bare metal stent implantation, for several months after drug-eluting stent implantation (3 months for sirolimus, 6 months for paclitaxel), and up to 12 months in patients who are not at high risk for bleeding. (Level of Evidence: B)

2. In patients taking clopidogrel in whom CABG is planned, the drug should be withheld for at least 5 days, and preferably for 7 days, unless the urgency for revascularization outweighs the risks of excess bleeding. (Level of Evidence: B)

Class IIa
Clopidogrel is probably indicated in patients receiving fibrinolytic therapy who are unable to take aspirin because of hypersensitivity or major gastrointestinal intolerance. (Level of Evidence: C)

Ticlopidine and clopidogrel are ADP-receptor antagonists and are quite similar chemically. Ticlopidine can cause neutropenia and thrombotic thrombocytopenia. Clopidogrel is preferred because of fewer side effects, lack of need for laboratory monitoring, and once-daily dosing. Clopidogrel combined with aspirin is recommended for patients with STEMI who undergo coronary stent implantation (576-580). There are no safety data available regarding the combination of fibrinolytic agents and clopidogrel, but ongoing trials will provide this information in the future. However, in patients in whom aspirin is contraindicated because of aspirin sensitivity, clopidogrel is probably useful as a substitute for aspirin to reduce the risk of occlusion (581). There are no safety data comparing 300 and 600 mg as loading doses for clopidogrel. We do not recommend routine administration of clopidogrel as pretreatment in patients who have not yet undergone diagnostic cardiac catheterization and in whom CABG surgery would be performed within 5 to 7 days if warranted (431).

6.3.1.6.8.2.3. Glycoprotein IIb/IIIa inhibitors

Class IIa
It is reasonable to start treatment with abciximab as early as possible before primary PCI (with or without stenting) in patients with STEMI. (Level of Evidence: B)

Class IIb
Treatment with tirofiban or eptifibatide may be considered before primary PCI (with or without stenting) in patients with STEMI. (Level of Evidence: C)

The use of intravenous GP IIb/IIIa receptor inhibitors in combination with fibrinolytic agents is discussed in Section 6.3.1.6.3.8. Intravenous GP IIb/IIIa receptor inhibitors have also been studied as supportive antiplatelet therapy in patients undergoing PCI. Five randomized trials compared abciximab to placebo control in a collective total of 3666 patients undergoing primary PCI for STEMI (34-36,38,582). A total of 1843 patients received abciximab, a relatively small data set on which to base recommendations for treatment. In addition, in the setting of primary PCI, periprocedural recurrent MI is not easily measured, so the benefit of antiplatelet therapy with GP IIb/IIIa inhibitors is harder to determine. Finally, only 1 of the trials, CADILLAC (Controlled Abciximab and Device Investigation to Lower Late Angioplasty Complications), provided data on the effect of abciximab on patients who underwent PTCA without stenting and on patients who had a stent implanted at the time of PCI (38).

The ADMIRAL study (Abciximab Before Direct Angioplasty and Stenting in Myocardial Infarction Regarding Acute and Long-Term Follow-Up) (36) enrolled 300 patients with STEMI undergoing primary stenting; half received placebo and half received abciximab in the mobile intensive care unit or the ED before arrival at the catheterization laboratory. Abciximab-treated patients had higher infarct artery patency (TIMI 2/3 flow) rates (25.9% versus 10.8%) before revascularization and a better LVEF (0.61 versus 0.57) 6 months after revascularization. Abciximab-treated patients had a lower rate of death, reinfarction, or need for subsequent target-vessel revascularization at 30 days (6.0% versus 14.6%, p equals 0.01) and at 6 months (7.4% versus 15.9%, p equals 0.02); the majority of the benefit of abciximab on the composite primary end point in ADMIRAL was driven by a reduction in urgent target-vessel revascularization. The CADILLAC study (38) enrolled 2082 patients (88% with STEMI) undergoing primary PTCA or stenting; half received placebo, and half were treated with abciximab in the catheterization laboratory. At 30 days, the incidence of the primary composite end point of death, reinfarction, revascularization, or disabling stroke was highest in the group assigned to receive PTCA alone (8.3%), and the lower rates in the other 3 groups were not significantly different from one another (4.8% PTCA plus abciximab, 5.7% stenting alone, 4.4% stenting plus abciximab). The Anticoagulation for Cardioversion using Enoxaparin (ACE) study (582) randomized 400 patients to stenting alone or stenting plus abciximab (administered immediately before the procedure). At 30 days, the incidence of the primary composite end point of death, reinfarction, target-vessel revascularization, or stroke was reduced in the stent-plus-abciximab group (4.5%) versus the stent alone group (10.5%; p equals 0.023); the majority of the benefit of abciximab on the primary end point in the ACE study was driven by a reduction in the rate of reinfarction. It is unclear whether the different 30-day results in the studies described above are related to patient selection and risk, timing of abciximab administration, or patency rates before revascularization (583). Assessment of the benefit of abciximab at 6 months varies depending on the composite end point, with evidence in favor of its use derived from composite end points of death/reinfarction or death/reinfarction/ urgent target-vessel revascularization, whereas evidence of long-term benefit of abciximab is lost if elective revascularization is added to the end point (34,36,583).

The Writing Committee believes that it is reasonable to start treatment with abciximab as early as possible in patients undergoing primary PCI (with or without stenting), but given the size and limitations of the available data set, assigned a Class IIa recommendation. The data on tirofiban and eptifibatide in primary PCI are far more limited than for abciximab. However, given the common mode of action of the agents, a modest amount of angiographic data (584), and general clinical experience to date, tirofiban or eptifibatide may be useful as antiplatelet therapy to support primary PCI for STEMI, with or without stenting (Class IIb recommendation).

6.3.1.6.9. Other Pharmacological Measures.

6.3.1.6.9.1. Inhibition of Renin-Angiotensin- Aldosterone System

Class I
1. An ACE inhibitor should be administered orally within the first 24 hours of STEMI to patients with anterior infarction, pulmonary congestion, or LVEF less than 0.40, in the absence of hypotension (systolic blood pressure less than 100 mm Hg or less than 30 mm Hg below baseline) or known contraindications to that class of medications. (Level of Evidence: A)

2. An angiotensin receptor blocker (ARB) should be administered to STEMI patients who are intolerant of ACE inhibitors and who have either clinical or radiological signs of heart failure or LVEF less than 0.40. Valsartan and candesartan have established efficacy for this recommendation. (Level of Evidence: C)

Class IIa
An ACE inhibitor administered orally within the first 24 hours of STEMI can be useful in patients without anterior infarction, pulmonary congestion, or LVEF less than 0.40 in the absence of hypotension (systolic blood pressure less than 100 mm Hg or less than 30 mmHg below baseline) or known contraindications to that class of medications. The expected treatment benefit in such patients is less (5 lives saved per 1000 patients treated) than for patients with LV dysfunction. (Level of Evidence: B)

Class III
An intravenous ACE inhibitor should not be given to patients within the first 24 hours of STEMI because of the risk of hypotension. (A possible exception may be patients with refractory hypertension.) (Level of Evidence: B)

A number of large, randomized clinical trials have assessed the role of ACE inhibitors early in the course of acute MI. All trials in which ACE inhibitors were administered orally demonstrated a benefit in mortality. In the ISIS-4 trial, 58000 patients with suspected acute MI were randomly assigned within the first 24 hours (median 8 hours) to receive either oral captopril or placebo; a significant 7% relative reduction was observed in 5-week mortality among those randomly assigned to captopril (absolute difference of 4.9 fewer deaths per 1000 patients treated for 1 month) (152). The largest benefit was among those with an anterior infarction. Among the 143 fewer deaths in the group allocated captopril, 44 occurred in days 0 through 1 and 37 in days 2 through 7 (585), which demonstrates that early therapy is important. In the GISSI-3 trial, more than 19 000 patients with either STsegment elevation or depression were randomly assigned to lisinopril or open control (586). There was a significant reduction in 6-week mortality (OR 0.88; 95% CI 0.79 to 0.99); 60% of the lives were saved during the first 5 days of treatment. The SMILE (Survival of Myocardial Infarction: Long-Term Evaluation) study involved 1556 patients randomly assigned within 24 hours to receive either placebo or zofenopril (587). The patient population was restricted to those with anterior MI who had not received fibrinolytic therapy. Use of an early ACE inhibitor in this trial suggested a trend of more lives saved in the first 6 weeks (RRR 25%, p equals 0.19). A Chinese captopril study involving more than 13 600 patients with suspected acute MI also revealed an approximate 0.5% absolute mortality benefit among those who were randomly assigned to the ACE inhibitor compared with the control population (588). A meta-analysis of these major trials along with 11 smaller trials that collectively enrolled more than 100 000 patients revealed a 6.5% overall odds reduction (p equals 0.006) with an absolute benefit of 4.6 fewer deaths per 1000 patients treated among those who received the ACE inhibitor (585). These data conclusively support a role for ACE inhibitors in the early and convalescent phases of STEMI.

All trials with oral ACE inhibitors have shown benefit from its early use, including those in which early entry criteria included clinical suspicion of acute infarctions. Data from these trials indicate that ACE inhibitors should generally be started within the first 24 hours, ideally after fibrinolytic therapy has been completed and blood pressure has stabilized. ACE inhibitors should not be used if systolic blood pressure is less than 100 mm Hg or less than 30 mm Hg below baseline, if clinically relevant renal failure is present, if there is a history of bilateral stenosis of the renal arteries, or if there is known allergy to ACE inhibitors.

The meta-analyses of the large ACE inhibitor trials have been useful in defining those patient subgroups most likely to demonstrate the greatest benefit from early post-MI ACE inhibitor therapy. According to a meta-analysis of nearly 100000 randomized patients, the benefits of early oral ACE inhibitors are greatest among those aged 55 to 74 years, with an anterior infarct, and with a heart rate of 80 bpm or higher (589).

ACE inhibitor therapy after STEMI should start with lowdose oral administration and increase steadily to achieve a full dose within 24 to 48 hours. For example, in ISIS-4, an initial 6.25-mg dose of captopril was given and, if tolerated, was followed by 12.5 mg 2 hours later, 25 mg 10 to 12 hours later, and then 50 mg twice per day. GISSI-3 patients received 5 mg or oral lisinopril at the time of randomization, 5 mg after 24 hours, 10 mg after 48 hours, and then 10 mg daily for 6 weeks or open control. Similar graded-dose schedules should be used with other ACE inhibitors such as ramipril, zofenopril, enalapril, and quinapril. Regarding the potential for aspirin to blunt the effect of ACE inhibitors, the Writing Committee thought that any adverse drug interaction between aspirin and ACE inhibitors was of a small magnitude and was far outweighed by the benefit of the combined administration of both drugs to patients recovering from STEMI (430,590,591). Lower doses of aspirin are likely to minimize any potential interaction.

Finally, the only trial that did not show a benefit with ACE inhibitors was the Cooperative New Scandinavian Enalapril Survival Study (CONSENSUS) II, in which patients were randomly assigned within the first day to receive either intravenous enalaprilat or placebo followed by increasing oral dosages of either enalapril or placebo (592). This trial was terminated early by its Safety Committee because of the high probability that a significant benefit of enalapril over placebo was unlikely to be demonstrated with continuation of the trial, as well as concern over an adverse effect among elderly patients who experienced an early hypotensive reaction. The 95% confidence limits ranged from showing a 7% benefit to 29% harm. Thus, intravenous enalaprilat should be avoided.

The use of ARBs has not been explored as thoroughly as ACE inhibitors in patients with STEMI. However, clinical experience in the management of patients with heart failure and data from clinical trials in patients with STEMI (see Sections 7.4.3 and 7.6.4) suggest that ARBs may be useful in patients with depressed LV function or clinical heart failure who are intolerant of an ACE inhibitor. Use of aldosterone antagonists in patients with STEMI is discussed in Sections 7.4.3 and 7.6.4.

6.3.1.6.9.2. Metabolic Modulation of the Glucose-Insulin Axis

Metabolic modulation of patients with STEMI was originally proposed by Sodi-Pallares et al. (593) in 1962. A metaanalysis of 1932 patients in trials conducted between 1965 and 1987 demonstrated a 28% relative mortality reduction, with an absolute benefit of 49 lives saved per 1000 patients treated (Table 21) (594-597). Subsequent trials in the reperfusion era show promising but variable results. High-dose infusions of glucose-insulin-potassium (GIK) (25% glucose, 50 IU/L soluble insulin, and 80 mmol/L KCl at a rate of 1.5 mL/kg/h for 24 hours) or a low-dose infusion (10% glucose, 20 IU/L soluble insulin, and 40 mmol/L KCl at a rate of 1 mL/kg/h for 24 hours) were compared to usual care. The ECLA (Estudios Cardiológicos Latinoamérica) pilot suggested a relationship between the time from symptom onset and impact of GIK infusion; a significant reduction in mortality rate was observed in patients treated 12 hours or less after symptom onset (595). The high-dose GIK regimen is being tested in large, ongoing international trials. The potential beneficial effect of GIK in high-risk patients with acute ischemic syndromes who have been revascularized is supported by a study of 322 post–cardiac surgery patients with postoperative cardiogenic shock (598). Those assigned to GIK had a 34% (p less than 0.02) reduction in in-hospital mortality. GIK was not superior to placebo in a study of 940 patients who underwent primary PCI (597). There appeared to be an interaction between treatment and Killip class, with possible mortality reduction at 30 days in Killip class I patients and excess mortality for those in Killip class II or higher. No definitive recommendations regarding GIK can be formulated until ongoing trials are completed.

6.3.1.6.9.2.1. Strict glucose control during STEMI

Class I
An insulin infusion to normalize blood glucose is recommended for patients with STEMI and complicated courses. (Level of Evidence: B)

Class IIa
1. During the acute phase (first 24 to 48 hours) of the management of STEMI in patients with hyperglycemia, it is reasonable to administer an insulin infusion to normalize blood glucose even in patients with an uncomplicated course. (Level of Evidence: B)

2. After the acute phase of STEMI, it is reasonable to individualize treatment of diabetics, selecting from a combination of insulin, insulin analogs, and oral hypoglycemic agents that achieve the best glycemic control and are well tolerated. (Level of Evidence: C)

The acute phase of STEMI is associated with a dramatic increase in catecholamine levels in the blood and ischemic myocardium. The insulin level remains low while cortisol and glucagon levels increase, which leads to decreased insulin sensitivity that contributes to impaired glucose utilization. Free fatty acid levels and the concentration of their metabolites increase, potentiating ischemic injury through several mechanisms: direct myocardial toxicity, increased oxygen demand, and direct inhibition of glucose oxidation. It has been suggested that agents that support glucose oxidation could reduce postischemic contractile dysfunction. Insulin promotes glucose oxidation, increases adenosine triphosphate levels, and may improve the fibrinolytic profile of patients with STEMI (599,600). Insulin reduces free fatty acids by reducing lipolysis and enhances glycolysis. Insulin specifically enhances glucose, lactate, and pyruvate uptake and switches the reliance of the myocardium from fat to carbohydrate without a change in oxygen consumption. The oxygen requirement of the heart is stimulated by free fatty acids without an improvement in mechanical activity (601).

Intensive insulin management of endogenous elevation of glucose in diabetics, supplemented by potassium as needed, has potential metabolic benefits similar to GIK for nondiabetics. The DIGAMI study randomized 620 diabetic patients to intensive insulin therapy with an insulin-glucose infusion for 24 hours followed by 3 months of subcutaneous injections of insulin 4 times daily or usual care (602). With continuous insulin infusion, blood glucose decreased in the first 24 hours from 15.4 to 9.6 mmol/L in the infusion group versus 15.7 to 11.7 mmol/L in the control group (p less than 0.0001). There was a trend toward lower 30-day mortality and significantly lower 1-year mortality (18.6% versus 26.1%, p equals 0.027).

Compelling evidence for tight glucose control in intensive care unit patients (a large proportion of whom were there after cardiac surgery) supports the importance of intensive insulin therapy to achieve a normal blood glucose (80 to 110 mg/dL) in critically ill patients (603,603a). Van den Berghe et al. reported that 12-month mortality rates were reduced from 8.0% to 4.6% (p less than 0.04; n equals 1548) for critically ill patients assigned to intensive insulin therapy (604). Goldberg et al. reported successful implementation of a nursing protocol with an insulin infusion to achieve a target blood glucose of 100 to 139 mg/dL in an intensive care setting (605). The studies by Van den Berghe et al. and Goldberg et al. underscore the importance and feasibility of intensive infusion therapy in the intensive care setting. The precise target blood glucose range requires further study.

Management of diabetic patients with STEMI should also involve consideration of long-term hypoglycemic therapy. A review of the oral hypoglycemic therapy of type 2 diabetes mellitus indicated that with few exceptions, the available oral antidiabetic agents are equally effective in lowering glucose levels. Their mechanisms of action are different. As a result, they appear to have distinct metabolic effects that may influence their profile and affect cardiovascular risk (606). As suggested by Inuzzuchi, in terms of hypoglycemic effect alone, there is no compelling reason to favor one of the major classes of oral antidiabetic agents (606). The overarching principle is that diabetic patients with STEMI should ultimately receive a regimen that achieves the best glycemic control, is well tolerated, and is likely to be maintained by the patient over the long term.

Although it is well appreciated that type I diabetic patients require insulin, most type 2 diabetics will also eventually need insulin to achieve the target of a HbA1C level less than 7%, a value that has been shown to be associated with reduced cardiovascular complications. It is reasonable that the prescription for care of diabetics with STEMI be individualized, selected from an armamentarium of insulin, insulin analogs, and oral hypoglycemic agents alone or in combination (607). A popular combination is metformin with insulin because it results in similar metabolic control, less weight gain, lower insulin doses, and fewer hyperglycemic episodes than insulin alone or insulin plus sulfonylurea therapy (607). The use of metformin must be tempered with the knowledge that metformin is contraindicated in the presence of CHF and renal failure. It should be withheld for 48 hours after intravenous contrast injection (608).

6.3.1.6.9.3. Magnesium

Class IIa
1. It is reasonable that documented magnesium deficits be corrected, especially in patients receiving diuretics before the onset of STEMI. (Level of Evidence: C)

2. It is reasonable that episodes of torsade de pointestype VT associated with a prolonged QT interval be treated with 1 to 2 grams of magnesium administered as an IV bolus over 5 minutes. (Level of Evidence: C)

Class III
In the absence of documented electrolyte deficits or torsade de pointes-type VT, routine intravenous magnesium should not be administered to STEMI patients at any level of risk. (Level of Evidence: A)

Meta-analyses of 7 randomized trials published between 1984 and 1991 suggested a significant mortality benefit of magnesium (4.4% absolute risk difference [ARD]; OR 0.44, CI 0.27 to 0.71) (609,610). The Second Leicester Intravenous Magnesium Intervention Trial (LIMIT-2) subsequently reported a significant reduction in mortality with magnesium treatment (2.5% ARD; 24% RRR; p equals 0.03) (611).

The ISIS-4 investigators enrolled 58 050 patients, of whom 29 011 were allocated to magnesium and 29 039 to control (152). There were 2216 deaths (7.64%) by 35 days in the magnesium group and 2103 deaths (7.24%) in the control group (OR 1.06; CI 0.99 to 1.13), which suggests no mortality benefit of magnesium administration and even the possibility of slight harm. Critiques of ISIS-4 raised the possibility that the null effect of magnesium resulted from late administration of treatment to patients who were predominantly at low risk (612,613).

The MAGIC (Magnesium in Coronaries) trial investigated the benefits of early administration of intravenous magnesium to high-risk patients with STEMI (stratum I: age 65 years or older and eligible for reperfusion therapy; stratum II: patients of any age who were not eligible for reperfusion therapy) (614). At 30 days, 475 (15.3%) patients in the magnesium group and 472 (15.2%) in the placebo group had died (OR 1.0, 95% CI 0.9 to 1.2, p equals 0.96). Potential explanations for the null effect of magnesium in MAGIC include the possibility that publication bias and an inadequate sample size in several earlier trials could have led to an overestimation of the benefit of magnesium through a large type I error and that the combination of mechanisms proposed for the benefits of magnesium overlapped with and were superseded by aspirin, beta-blockers, and ACE inhibitors (prescribed infrequently in earlier trials but commonly in ISIS-4 and MAGIC).

Between 1980 and 2002, a total of 68 684 patients were studied in a series of 15 randomized trials (Table 22) (614- 628). On the basis of the totality of available evidence, in current coronary care practice, there is no indication for the routine administration of intravenous magnesium to patients with STEMI at any level of risk. Magnesium can continue to be administered for repletion of documented electrolyte deficits and life-threatening ventricular arrhythmias such as torsade de pointes (629).

6.3.1.6.9.4. Calcium Channel Blockers

Class IIa
It is reasonable to give verapamil or diltiazem to patients in whom beta-blockers are ineffective or contraindicated (e.g., bronchospastic disease) for relief of ongoing ischemia or control of a rapid ventricular response with AF or atrial flutter after STEMI in the absence of CHF, LV dysfunction, or AV block. (Level of Evidence: C)

Class III
1. Diltiazem and verapamil are contraindicated in patients with STEMI and associated systolic LV dysfunction and CHF. (Level of Evidence: A)

2. Nifedipine (immediate-release form) is contraindicated in the treatment of STEMI because of the reflex sympathetic activation, tachycardia, and hypotension associated with its use. (Level of Evidence: B)

Nifedipine. In patients with STEMI, immediate-release nifedipine does not reduce the incidence of reinfarction or mortality when given early (less than 24 hours) or late. Immediate-release nifedipine may be particularly detrimental in patients with hypotension or tachycardia; in these patients, it may induce a reduction in coronary perfusion pressure, disproportionate dilatation of the coronary arteries adjacent to the ischemic area (so-called “steal”), and/or reflex activation of the sympathetic nervous system, with an increase in myocardial oxygen demands (630-637).

Verapamil. Although the overall results of trials with verapamil showed no mortality benefits, subgroup analysis showed that immediate-release verapamil initiated several days after STEMI in patients who were not candidates for a beta-blocking agent may have been useful in reducing the incidence of the composite end point of reinfarction and death, provided LV function was well preserved with no clinical evidence of heart failure. Verapamil is detrimental to patients with heart failure or bradyarrhythmias during the first 24 to 48 hours after STEMI (638-641). One randomized study of 1700 patients less than 75 years of age using verapamil within 2 weeks of STEMI showed a significant reduction in major events (death or reinfarction) over 18 months (3.6% ARD; 17% RRR; p equals 0.03) (642).

Diltiazem. Data from the Multicenter Diltiazem Postinfarction Trial (MDPIT; Q-wave and non–Q-wave infarction) (643) and the Diltiazem Reinfarction Study (DRS; non–Q-wave infarction) (639, 640, 644, 645) suggest that patients with non–Q-wave MI or those with Q-wave infarction, preserved LV function, and no evidence of heart failure may benefit from immediate-release diltiazem. Diltiazem was begun in MDPIT 3 to 15 days after STEMI and in DRS 24 to 72 hours afterward. The results of MDPIT may be confounded by the fact that 53% and 55% of placebo- and diltiazem-treated patients, respectively, received concomitant beta-blocker therapy (643). Also, both the MDPIT and DRS projects were conducted in an era when the use of aspirin was not as prevalent as it is today, which raises further uncertainty about the relevance of their findings for contemporary management of STEMI. Of particular clinical importance is the detrimental mortality effect of diltiazem in patients with LV dysfunction. Diltiazem was tested in patients with STEMI but without CHF who were undergoing fibrinolytic therapy in the INTERCEPT trial (Incomplete Infarction Trial of European Research Collaborators Evaluating Prognosis post-Thrombolysis) (646). No effect on the cumulative occurrence of fatal and nonfatal end points was demonstrated during a 6-month follow-up, but there was a modest decrease in nonfatal cardiac events, in large part due to reductions in recurrent ischemia.