Clinical Practice/Controversy: Approach to Noninvasive Testing After Presentation with Acute Myocardial Infarction

Introduction

Noninvasive testing after presentation with acute myocardial infarction (MI) plays an essential role in patient management. Noninvasive testing complements clinical assessment of risk stratification and can be used to aid management decisions. The major purposes of testing are measurement of left ventricular (LV) function in nearly all patients and assessment of ischemic burden, primarily among low-risk patients who are initially treated conservatively, to identify potential candidates for coronary angiography or nonculprit vessel revascularization. The most commonly used tests include resting echocardiography, standard stress testing with electrocardiography (ECG) alone, stress imaging with nuclear myocardial perfusion imaging (MPI) or echocardiography, and increasingly, resting and stress cardiac magnetic resonance imaging (CMR). The use of these tests is related to the temporal evolution of the MI. Early imaging (within the first 72 hours) is performed predominantly with resting echocardiography; intermediate testing (day 3 to 6 weeks) uses the standard stress test or stress imaging; and late imaging (beyond 6 weeks) is performed with any of the techniques in selected patient subsets to measure LV ejection fraction (LVEF) after stunning has resolved for assessment of implantable cardiac defibrillator (ICD) consideration and for viability assessment.

In this chapter, we discuss the role of noninvasive testing after MI, patient selection, and considerations for choosing among the alternatives for noninvasive testing. Each modality is discussed in detail elsewhere in the text. Echocardiography is reviewed in Chapter 31 , MPI in Chapter 32 , and CMR in Chapter 33 . Although computed tomographic angiography (CTA) is playing an increasingly important role in the early evaluation of the patient with acute chest pain in the emergency department (see Chapter 9 ), CTA currently is not widely used in patients with confirmed MI and is not discussed in this chapter.

Pathophysiology of Myocardial Infarction as the Basis for Noninvasive Testing

The pathophysiology of acute MI is discussed in detail in Chapter 3, Chapter 4 . Understanding the pathophysiology establishes the foundation for appreciating the rationale behind noninvasive testing. The amount of myocardium that is jeopardized by occlusion of a coronary artery is referred to as myocardium at risk (see Chapter 24 ). This is the amount of myocardium that is expected to become scarred in the absence of spontaneous reperfusion or treatment with reperfusion therapy. The amount of myocardium that ultimately turns into scar is referred to as the final infarct size. The difference between myocardium at risk and final infarct size is labeled myocardial salvage. Both final infarct size and myocardial salvage reflect, in part, the efficacy of reperfusion therapy (see Chapter 13 ). These measurements can be quantified by nuclear MPI or CMR techniques. This type of imaging has been applied as a surrogate endpoint in numerous research studies that have compared different reperfusion strategies or have examined the efficacy of new MI therapies. Measurement of myocardial salvage is somewhat logistically demanding and has not been shown to directly affect patient management; therefore, such measurements are not commonly performed in clinical practice. MI results in worsening wall motion in the infarct zone and commonly compensatory hyperkinesia in noninfarct zones (see Chapter 36 ). After spontaneous reperfusion or reperfusion therapy, partial or complete recovery may ensue in the motion of these stunned segments. The duration for resolution of stunning and resolution of compensatory hyperkinesia in noninfarct zones is highly variable and occurs within days up to 6 weeks.

Two of the most important prognostic variables in patients with acute MI are global LV function and the extent of coronary artery disease (CAD). Measurement of these variables is a primary objective of noninvasive testing after MI. Global LV function is most commonly expressed as the LVEF. Current professional society practice guidelines recommend measurement of LVEF in all patients with ST-elevation MI (STEMI) and recognize the relationship with the prognosis among patients with non–ST-elevation MI (NSTEMI). LVEF and regional wall motion can be measured in the catheterization laboratory by contrast ventriculography or by noninvasive methods. These measurements are increasingly being obtained noninvasively. Other indices of global LV structure and/or function, including end-diastolic and end-systolic volumes, wall motion score index, and diastolic function can also be measured, but these generally do not provide any incremental knowledge for patient management beyond that provided by LVEF. Because of the effects of stunning, repeated measurement of LVEF beyond 40 days may be required in selected patients, particularly those being considered for ICDs. Some patients with reduced LVEF undergo progressive enlargement of the LV, a process termed remodeling (see Chapter 36 ). Remodeling is associated with higher mortality and greater risk of future development of heart failure. Angiotensin-converting enzyme (ACE) inhibitors and angiotensin receptor blockers can favorably affect remodeling. An important reason to measure LVEF early in the course of acute MI is to identify patients who are candidates for these medications and aldosterone antagonists.

Noninvasive testing can approximate the extent of CAD and its functional significance. In patients with MI who are initially treated conservatively and do not undergo early coronary angiography, stress testing can be performed to identify patients who are candidates for coronary angiography and possible revascularization. Moreover, noninvasive testing may be useful for assessing the functional significance of residual CAD after an initial revascularization of the culprit artery (see Chapter 17 ).

Rational Use of Noninvasive Testing

Noninvasive testing should be viewed as an adjunct to clinical assessment for risk stratification and to aid in management decisions. Accurate risk assessment begins with clinical assessment of risk, which can be aided by calculating a clinical risk score (see Chapter 11 ). Clinical variables and the ECG can also be used to estimate LVEF. This clinical estimate can occasionally suffice for adequate risk assessment in selected patients without the need for further evaluation. In general, testing is least helpful for aiding clinical management at the two ends of the risk spectrum, in patients either at low or at high risk based on prognostic information that is already available. For instance, a young patient who presents early with first MI, and at angiography has single vessel right or circumflex CAD treated with successful PCI followed by an uncomplicated hospital course, also has a very high likelihood of a normal LVEF. Although measurement of LVEF is categorized as a class I indication in STEMI guidelines, the measurement reasonably could be avoided in this patient example, because of the high likelihood of normal LVEF on the basis of clinical assessment. At the other end of the risk spectrum, there are an increasing number of patients with end-stage CAD who are living longer and present with multiple MIs during their lifetime. If previous evaluation has demonstrated that coronary anatomy is not amenable to further revascularization, or if LVEF is severely reduced, and the patient is already taking an ACE inhibitor and has an ICD, there is little to be gained from noninvasive testing. Testing should be performed only when the results are likely to affect clinical management and in a cost-effective manner. Redundant testing should be avoided. If a patient undergoes left ventriculography as part of the early catheterization procedure, performance of echocardiography generally is not necessary.

Noninvasive Testing According to Temporal Sequence of Myocardial Infarction Evolution

The time course of recovery after MI can be separated into three general phases: early (within 72 hours); intermediate (day 3 to week 6); and late (beyond 6 weeks). These phases provide a useful framework in which to consider the goals and alternatives for noninvasive testing ( Table 30-1 ). Resting echocardiography is the most commonly performed test in the early phase ( Figure 30-1 ). The major goal is to provide information on LVEF and regional wall motion. Echocardiography (see Chapter 31 ) can also identify mechanical complications of MI (see Chapter 26 ) and aid in the recognition of conditions that mimic MI (see Chapter 6 ). Early submaximal stress testing (usually performed between days 3 and 5 and before hospital discharge) with or without imaging is performed primarily in the subset of low-risk patients who do not undergo early coronary angiography for risk stratification ( Figure 30-2 ). Delayed symptom-limited stress testing (usually between 3 and 6 weeks) can be helpful to guide additional revascularization decisions in patients who undergo early angiography and have evidence for significant CAD in vessels other than the infarct-related artery (see Figure 30-2 ). Delayed imaging (beyond 40 days) with any of the imaging techniques can be performed in selected patients primarily for two major purposes: measurement of LVEF to determine eligibility for ICD and assessment of viable myocardium ( Figure 30-3 ).

TABLE 30-1

Time Course and Imaging Strategies after Myocardial Infarction

Time	Main Modality ^∗	Goal	Impact on Management
Early (≤2 h)	Resting echo (MUGA or CMR)	Measure global and regional LV function Identify MI complications Identify conditions mimicking MI	Use of ACE inhibitor, ARB, aldosterone antagonist Selection of revascularization strategy Appropriate treatment for identified condition
Intermediate (days 3–5) Intermediate (weeks 3–6)	Submaximal stress test ^† Symptom limited stress test ^†	Assess residual ischemic burden Same as submax test (if not performed). Assess ischemia related to the noninfarct artery ^‡	Identify pts for cor angio Identify pts for cor angio Select pts for additional PCI/CABG
Late (≥40 days)	Echo (MUGA or CMR) Nuclear PET or CMR (echo)	Measure LVEF (after stunning resolves) Assess myocardial viability	Eligibility for ICD Revascularization (usually CABG)

ACE , Angiotensin-converting enzyme; ARB , angiotensin receptor blocker; CABG , coronary artery bypass graft; CMR, cardiac magnetic resonance imaging; ICD , implantable cardiac defibrillator; LV , left ventricular; LVEF , left ventricular ejection fraction; MI , myocardial infarction; MUGA , multigated analysis; PCI , percutaneous coronary intervention; PET , positron emission tomography.

∗ The generally preferred and most commonly applied modality is shown first. Modalities listed in parentheses indicate secondary choices.

† Selection between a standard stress test and stress imaging is based primarily upon ability to exercise and interpretability of the electrocardiogram.

‡ If testing is performed to assess ischemia in the noninfarct vessel, stress imaging is recommended over standard stress testing.

FIGURE 30-1, Imaging options in the acute phase of treatment in the setting of acute coronary syndrome.

FIGURE 30-2, In the intermediate phase of treatment, functional imaging is the main consideration and can be applied to both early invasive and conservative strategies of care.

FIGURE 30-3, In the late phase of treatment, decision making is targeted toward two groups.

Early Imaging (Within 72 Hours) After Myocardial Infarction

Resting Echocardiography

The mainstay of early imaging is resting echocardiography. Echocardiography (see also Chapter 31 ) possesses certain advantages over other imaging modalities, including its more widespread availability and portability. There are essentially no contraindications to the performance of an echocardiogram. Transthoracic echocardiography provides a comprehensive cardiac assessment that encompasses global and regional LV systolic function, global right ventricular function, chamber sizes, wall thickness, LV diastolic function, valve status, estimated right ventricular systolic pressure, and pericardial fluid and thickness. Myocardial contrast can be administered to enhance image quality in patients with technically poor images. When clinically necessary, resting echocardiography can be performed at the patient’s bedside. Transesophageal echocardiography provides an alternative to transthoracic echocardiography in critically ill patients who may have limited acoustic windows because of chest bandages or for other reasons. Performance of transesophageal echocardiography solely to assess cardiac function is an uncommon indication. Transesophageal echocardiography has particular use in the assessment of the thoracic aorta and main pulmonary arteries to diagnose conditions that can mimic MI. Myocardial strain imaging represents a newer method of assessing systolic function, but its incremental clinical value over routine measurement of LVEF and regional wall motion assessment remains to be determined. Myocardial contrast echocardiography with microbubbles has been used to assess myocardial perfusion, but this technique is not commonly performed clinically.

The major reason for performing resting echocardiography early in the course of MI is measurement of LVEF (see Figure 30-1 ). Knowledge of LVEF can influence medical decision-making. ACE inhibitors and aldosterone antagonists are class I guideline recommendations in patients with reduced LVEF (see Chapter 13, Chapter 25 ). Knowledge of LVEF may also influence selection of a specific revascularization procedure, particularly in patients with NSTEMI (see Chapter 16 ). For NSTEMI, or stabilized patients after STEMI, coronary artery bypass grafting (CABG) is preferred instead of multivessel PCI in patients with multivessel CAD if the LVEF is reduced. Assessment of regional wall motion can also provide an estimate of infarct size. Global LV function can also be measured as a wall motion score index, which is determined as the summation of regional wall motion in multiple LV segments. Some studies suggest that this measurement is a more accurate predictor of outcome than LVEF.

A second reason to perform early echocardiography is to aid in the identification of conditions that can mimic acute MI (see Figure 30-1 ), including pulmonary embolus, aortic dissection, myocarditis and/or pericarditis, and apical ballooning syndrome (see Chapter 6 ). All of these conditions can present with chest discomfort, ischemic-appearing ECG changes, and elevated troponin. Because these conditions occur much less frequently than MI, there is a higher likelihood that they will be misdiagnosed initially. Echocardiography can provide clues to the presence of these conditions. The echocardiographic findings are not always definitive, and additional imaging procedures are commonly necessary to confirm the alternative diagnosis.

A third major reason to perform early echocardiography is to identify complications of acute MI (see Figure 30-1 ), including LV thrombus; right ventricular infarction; pericardial effusion, especially when associated with tamponade; rupture of the LV free wall, papillary muscle, or interventricular septum; and valvular heart disease, especially new ischemic mitral regurgitation (see Chapter 26 ). Prompt and accurate identification of these complications can be critical to patient management and outcome.

Cardiac Magnetic Resonance and Nuclear Imaging

CMR (see also Chapter 33 ) is being increasingly used in the MI setting and possesses certain advantages over other imaging techniques. It provides high spatial resolution and is not limited by acoustic windows as occurs with echocardiography. CMR has been shown to be superior to echocardiography in the assessment of the LV apex, which may have important clinical implications in the setting of anterior infarction, where assessment of apical thrombi may be challenging with echocardiography. CMR can more accurately characterize the anatomy of the right ventricle and provide volumetric measures of right ventricular size and function. Knowledge of these variables may have clinical implications in the care of patients presenting with inferior MI or pure right ventricular infarction. A unique property of CMR is tissue characterization, which helps delineate the presence of inflammation. This property can be very useful to correctly identify the rare patient who presents with myocarditis masquerading as MI.

MPI may be useful in the initial diagnostic evaluation of patients presenting with chest pain suspicious for MI (see Chapter 9 ). However, there is little role for nuclear MPI (see Chapter 32 ) in the early setting for patients with confirmed MI. Radionuclide angiography, commonly referred to as multigated analysis (MUGA), can be useful for evaluating LV function when echocardiographic images are limited. This technique provides an accurate quantitative assessment of LVEF. It has the theoretical advantage over other techniques of being geometrically independent and is especially useful for measuring LVEF in patients with distorted LV anatomy, such as an aneurysm. Both CMR and radionuclide angiography apply ECG gating for assessment of LV function. Because accurate measurement of LVEF and regional wall motion by gated techniques depends upon a fairly regular heart rhythm, these techniques generally are not advised in patients with atrial fibrillation or frequent cardiac ectopy.

Intermediate Term Testing (Day 3 to Week 6) After Myocardial Infarction

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