Noninvasive Cardiac Imaging: Echocardiography, Nuclear Cardiology, and Magnetic Resonance/Computed Tomography Imaging
1841CHAPTER 241
It is important to highlight that most studies included in metaanalyses of the diagnostic accuracy of cardiac imaging modalities for
the diagnosis of CAD were retrospective, small, single-center studies,
comprising predominantly male patients with a high prevalence of
CAD (>50–60%). Multicenter studies assessing the performance of
individual modalities or comparing different modalities have consistently resulted in more modest diagnostic accuracies, tracking more
closely with how these tests perform in clinical practice.
Stress Echocardiography The hallmark of myocardial ischemia
during stress echocardiography is the development of new regional
wall motion abnormalities and reduced systolic wall thickening (Video
241-3). Stress echocardiography can be performed in conjunction
with exercise or dobutamine stress. Stress echocardiography is best at
identifying inducible wall motion abnormalities in previously normally
contracting segments. In a patient with wall motion abnormalities at
rest, the specificity of stress echocardiography is reduced, and worsening regional function of a previously abnormal segment might reflect
worsening contractile function in the setting of increased wall stress
rather than new evidence of inducible ischemia.
The advantages of stress echocardiography over other stress imaging
techniques include its relatively good diagnostic accuracy, widespread
availability, no use of ionizing radiation, and relatively low cost. Limitations of stress echocardiography include (1) the technical challenges
associated with image acquisition at peak exercise because of exertional
hyperpnea and cardiac excursion, (2) the fact that rapid recovery of
wall motion abnormalities can be seen with mild ischemia (especially
with one-vessel disease, which limits sensitivity), (3) difficulty detecting residual ischemia within an infarcted territory because of resting
wall motion abnormality, (4) high operator dependence for acquisition
of echocardiographic data and analysis of images, and (5) the fact
that good-quality complete images viewing all myocardial segments
occur in only 85% of patients. Newer techniques, including second
harmonic imaging and the use of intravenous contrast agents, improve
image quality, but their effect on diagnostic accuracy has not been well
documented.
As with nuclear perfusion imaging, stress echocardiography is often
used for risk stratification in patients with suspected or known CAD. A
negative stress echocardiogram is associated with an excellent prognosis, allowing identification of patients at low risk. Conversely, the risk
of adverse events increases with the extent and severity of wall motion
abnormalities on stress echocardiography.
Stress Radionuclide Imaging SPECT
myocardial perfusion imaging is the most common form of stress imaging tests for CAD evaluation. The presence of a reversible myocardial
perfusion defect is indicative of ischemia (Fig.
241-9, left panel), whereas a fixed perfusion defect
generally reflects prior myocardial infarction
(Fig. 241-9, right panel). As discussed above, PET
has advantages compared to SPECT, but it is not
widely available and is more expensive and, thus,
considered an emerging technology in clinical
practice.
Nuclear perfusion imaging is another robust
approach to diagnose obstructive CAD, quantify
the magnitude of inducible myocardial ischemia,
assess the extent of tissue viability, and guide therapeutic management (i.e., selection of patients for
revascularization). One of the most valuable clinical applications of radionuclide perfusion imaging is for risk stratification. It is well established
that patients with a normal SPECT or PET study
exhibit a low rate of major adverse cardiac events
of <1% annually. Importantly, the risks of death
and myocardial infarction increase linearly with
increasing magnitude of perfusion abnormalities,
reflecting the extent and severity of CAD.
Despite the widespread use and clinical acceptance of radionuclide
imaging in CAD evaluation, a recognized limitation of this approach
is that it often uncovers only coronary territories supplied by the most
severe stenoses. Consequently, it is relatively insensitive to accurately
delineate the extent of obstructive angiographic CAD, especially in
the setting of multivessel disease. The use of quantitative myocardial
blood flow and coronary flow reserve with PET can help mitigate this
limitation. In patients with so-called “balanced” ischemia or diffuse
CAD, measurements of coronary flow reserve uncover areas of myocardium at risk that would generally be missed by performing only
relative assessments of myocardial perfusion (Fig. 241-10). Conversely,
a normal coronary flow reserve is associated with a very high negative
predictive value for excluding high-risk angiographic CAD. These
measurements of coronary flow reserve also contribute to risk stratification across the spectrum of ischemic changes, including patients
with visually normal myocardial perfusion.
HYBRID CT AND NUCLEAR PERFUSION IMAGING Because many of
the newer generation nuclear medicine scanners integrate CT and
a gamma camera in the same acquisition gantry, it is now possible
to acquire and quantify myocardial scar and ischemia and CAC
scoring from a single dual-modality study (SPECT/CT or PET/CT)
(Fig. 241-11). The rationale for this integrated approach is predicated
on the fact that the perfusion imaging approach is designed to uncover
only obstructive atherosclerosis. Conversely, CAC scoring provides a
quantitative measure of the anatomic extent of atherosclerosis. This
provides an opportunity to improve the conventional models for risk
assessment using nuclear imaging alone, especially in patients without
known CAD.
Cardiac CT Voluminous plaques are more prone to calcification,
and stenotic lesions frequently contain large amounts of calcium.
Indeed, there is evidence that high CAC scores are generally predictive
of a higher likelihood of obstructive CAD, and the available data support
the concept of a threshold phenomenon governing this relationship (i.e.,
Agatston score >400). However, given the fact that CAC scores are not
specific markers of obstructive CAD, one should be cautious in using
this information as the basis for referral of patients to coronary angiography, especially in symptomatic patients with low-risk stress tests.
Conversely, CAC scores <400, especially in symptomatic patients with
intermediate-high likelihood of CAD, as in those with typical angina,
may be less effective in excluding CAD, especially in young symptomatic
men and women who may have primarily noncalcified atherosclerosis
(Fig. 241-12).
Stress
Stress
Stress
Rest
Rest
Rest
Reversible perfusion defect Fixed perfusion defect
FIGURE 241-9 Selected technetium-99m sestamibi myocardial perfusion single-photon emission
computed tomography images of two different patients demonstrating a reversible perfusion defect
involving the anterior and septal left ventricular wall, reflecting ischemia in the left anterior descending
coronary territory (arrows in left panel) and a fixed perfusion defect involving the inferior and
inferolateral walls consistent with myocardial scar in the right coronary territory (arrow in right panel).
1842 PART 6 Disorders of the Cardiovascular System
As discussed above, the improved temporal and spatial resolution
of modern multidetector CT scanners offers a unique noninvasive
approach to delineate the extent and severity of coronary atherosclerosis with coronary CTA. The extremely high sensitivity of this
approach offers a very effective means for excluding the presence of
CAD (high negative predictive value) (Table 241-3). In the setting
of high coronary calcium scores (e.g., >400), however, specificity
is reduced because the blooming artifact of calcium does not allow
one to evaluate the vessel lumen accurately. Given the high negative
predictive value of CTA, a normal scan result effectively excludes
Stress
21 22 23 24 25 26 27 28 29 30 31
23 24 25 26 27 28 29 30 31 32 33
35 36 37 38 39 40 41 42 43 44 45
37 38 39 40 41 42 43 44 45 46 47
67 66 65 64 63 62 63 64 65 66
67 66 65 64 63 62 63 64 65 66
Stress
Stress
Stress
LCX
LM
LAD
RCA
Rest
Rest
Ant
Sep Lat
Inf
Rest
Rest
FIGURE 241-10 Coronary angiographic (left panel) and rubidium-82 myocardial perfusion positron emission tomography images (right panel) in an 85-year-old female with
diabetes presenting with chest pain. The coronary angiogram demonstrates significant stenoses of the left main and circumflex coronary arteries. However, the perfusion
images demonstrate only a reversible lateral wall defect. Quantification of stress and rest myocardial blood flow demonstrated a significant, global reduction on coronary
flow reserve (estimated at 1.2, normal value >2.0), reflecting extensive myocardium risk that was underestimated by the semiquantitative estimates of myocardial perfusion.
LAD, left anterior descending artery; LCX, left circumflex artery; LM, left main artery; RCA, right coronary artery.
Stress
ANT
LAT
INF
SEP
STRESS(G)
ANT
LAT
INF
SEP
REST(G)
PA
aAo
dAo
Calcium score: 1330
Stress
Stress
Rest
Rest
Rest
FIGURE 241-11 Stress and rest rubidium-82 myocardial perfusion positron emission tomography (PET) images (left) and noncontrast gated computed tomography
(CT) images (right) delineating the extent and severity of coronary artery calcifications obtained with integrated PET/CT imaging. The images demonstrate extensive
atherosclerosis (Agatston coronary calcium score = 1330) without flow-limiting disease based on the normal perfusion study. aAo, ascending aorta; dAo, descending aorta;
PA, pulmonary artery.
Noninvasive Cardiac Imaging: Echocardiography, Nuclear Cardiology, and Magnetic Resonance/Computed Tomography Imaging
1843CHAPTER 241
Stress
23 24 25 26 27 28 29 30 31 32 33
24 25 26 27 28 29 30 31 32 33 34
64 65 66 67 68
65 66 67 68 69
64 63 62 61 60
64 63 62 61 60
Stress
Rest
LM
LAD
Rest
FIGURE 241-12 Stress and rest rubidium-82 myocardial perfusion positron emission tomography images (top), noncontrast gated computed tomography images (lower
right), and selected coronary angiographic images obtained on a 59-year-old male patient with atypical angina. Despite the absence of significant coronary calcifications
(Agatston calcium score = 0), the perfusion images demonstrated a dense and reversible perfusion defect involving the anterior and anteroseptal walls (arrows), reflecting
significant obstructive disease in the left anterior descending coronary artery (LAD), confirmed on angiography. LM, left main artery.
obstructive CAD and abolishes the need for further investigation.
As discussed below, this may be quite useful in patients with lowintermediate clinical risk presenting to the emergency department
(ED) for chest pain. However, the limited capability of this technique to
determine which coronary plaques are flow limiting can make abnormal scan results more difficult to interpret, especially in terms of the
possible need of revascularization. There are emerging data suggesting
that by adding a stress myocardial perfusion CT evaluation (similar to
stress perfusion CMR) (Fig. 241-13, top panel) or an estimated fractional flow reserve (so-called FFRCT) (Fig. 241-13, lower panel), one
can define the hemodynamic significance of anatomic stenosis. FFRCT
is beginning to enter routine clinical practice. However, CT myocardial
perfusion remains an emerging technology.
As with invasive coronary angiography, assessments of the extent of
CAD by CTA can also provide useful prognostic information. A low
1-year cardiac event rate has been reported for patients without coronary atherosclerosis on CTA. For patients with obstructive CAD, the
risk of adverse cardiac events increases proportionally with the extent
of angiographically obstructive CAD. There is new evidence that even
the presence of nonobstructive atherosclerosis increases the risk of
adverse cardiac events.
Although CTA can be helpful in assessing patency of bypass grafts,
the assessment of stents is somewhat more challenging because the
limited spatial resolution of CT and stent diameter (<3 mm being
associated with the highest number of partial lumen visualization and
nondiagnostic scans) both contribute to limited clinical results.
CMR Imaging CMR evaluates for ischemia from CAD by assessing regional myocardial perfusion or regional wall motion at rest
and during pharmacologic stress with an intravenous infusion of
vasodilator agent or dobutamine. Myocardial perfusion is evaluated
by injecting a GBCA bolus followed by imaging data acquisition as
the contrast passes through the cardiac chambers and into the myocardium. Relative perfusion deficits are recognized as regions of low
signal intensity (black) within the myocardium (Video 241-4). Several
minutes after GBCA injection, LGE imaging allows detection of bright
areas of myocardial scar (white), which permits comparison of regions
of hypoperfusion and infarction to quantify myocardial ischemia
(Fig. 241-14).
With better delineation of the endocardial borders, dobutamine
CMR has better diagnostic accuracy than dobutamine echocardiography for detection of CAD, especially in patients with poor acoustic
window (Table 241-3). High-dose dobutamine carries the risk of serious ventricular arrhythmias (~1%), but most cases can be prevented
with proper monitoring of vital signs and regional cine function. The
advantages of stress perfusion CMR over SPECT include its higher
spatial resolution, which allows detection of subendocardial ischemia
or infarction that may be missed by SPECT. As with other imaging
modalities, stress CMR studies also provide robust risk stratification. In
a recent randomized controlled trial, a stress CMR–guided strategy was
shown to improve the guidance toward the use of invasive investigation
and coronary revascularization.
Selecting a Testing Strategy in Patients without Known
CAD As discussed above, there are many options for the evaluation
of a patient with suspected CAD presenting with chest pain symptoms.
The critical questions to be answered by a testing strategy include the
following: (1) Does the chest pain reflect obstructive CAD? (2) What
are the short- and long-term risks? (3) Does the patient need to be
considered for revascularization? With improved guideline-directed
1844 PART 6 Disorders of the Cardiovascular System
medical therapy (GDMT), large-scale clinical trials have indicated the
benefits of GDMTs in which the majority of the patients with stable
CAD are at low risk of serious cardiac events on the basis of GDMT
alone, with coronary revascularization best reserved for patients with
severe symptoms despite adequate medical therapy. Imaging, however,
will continue to play a significant role in diagnosing the etiology of
chest pain and risk assessment of individual patients.
For symptomatic patients without a prior history of CAD and a normal
or nearly normal resting ECG who are able to exercise, the American
College of Cardiology/American Heart Association guidelines recommend standard exercise treadmill testing (ETT) as the initial testing
strategy. The guidelines further suggest that patients who are categorized as low risk by ETT (e.g., those achieving >10 metabolic equivalents [METS] without chest pain or ECG changes) be treated initially
with medical therapy, and those with high-risk ETT findings (i.e.,
typical angina with >2 mm ST-segment depression in multiple leads,
ST elevation during exercise, drop in blood pressure, or sustained ventricular arrhythmias) be referred for coronary angiography.
The use of exercise testing in women presents difficulties that are
not seen in men, reflecting the differences in the lower prevalence
of obstructive CAD in women and the different accuracy of exercise
testing in men and women. Compared with men, the lower pretest
probability of disease in women means that more test results are false
positive. In some of these patients, a positive ETT may reflect true
myocardial ischemia caused by microvascular coronary artery dysfunction (so-called microvascular disease). In addition, the inability
of many women to exercise to maximum aerobic capacity, the greater
prevalence of mitral valve prolapse and microvascular disease, and
possibly other reasons may contribute to the differences with men as
well. The difficulties of using exercise testing for diagnosing obstructive CAD in women have led to speculation that stress imaging may be
preferred over standard stress testing. However, recent data from the
WOMEN study suggest that in symptomatic, low-risk women who can
exercise, standard ETT is a very effective initial diagnostic strategy as
compared to stress radionuclide imaging. Indeed, the 2-year outcomes
were similar in both diagnostic strategies, and the ETT-first approach
resulted in 48% lower costs compared to exercise radionuclide imaging.
Patients who cannot undergo an ETT or those at intermediate-high
risk after ETT (e.g., low exercise capacity, chest pain, and/or ST-segment
depression without high-risk features) will often require additional
testing, either stress imaging or coronary CTA, to more accurately
characterize clinical risk. Most common stress imaging strategies in
intermediate-risk patients include stress echocardiography and radionuclide imaging. However, CMR and PET in experienced centers have
both been shown to have higher test accuracy than SPECT, and CMR
has been shown to be more cost-effective than SPECT. In patients
FIGURE 241-14 The image shows the late gadolinium enhancement image of a mid
short-axis view. There is no evidence of infarction in the anterior wall, which would
be seen as bright white areas, indicating that the stress perfusion defect primarily
represents myocardial ischemia. This patient had a significant stenosis of the left
anterior descending coronary artery.
FFRCT0.64
LAD
FFRCT
FFR 0.57
0.9
0.8
0.7
FIGURE 241-13 Examples of novel approaches to the assessment of flow-limiting coronary artery disease (CAD) with cardiac computed tomography (CT). In the top
panel, representative views of coronary CT angiogram (CTA; left), coronary angiogram (middle), and stress myocardial perfusion CT (right) images in a patient with CAD and
prior stenting of the left anterior descending coronary artery (LAD) are presented. On the CTA, the stent (arrows) is totally occluded as evidenced by the loss of contrast
enhancement distal to the stent. The coronary angiogram demonstrates a concordant total occlusion of the LAD. On the perfusion CT images, there is a black rim (arrows)
involving the anterior and anterolateral walls, indicating the lack of contrast opacification during stress consistent with myocardial ischemia. (Images courtesy of CORE 320
investigators.) The lower panel illustrates an example of fractional flow reserve (FFR) estimates with coronary CTA (left) compared to the reference standard of invasive FFR.
The FFR reflects the pressure differential between a coronary segment distal to a stenosis and the aorta. In normal coronary arteries, there is no gradient, and FFR is 1. An
FFR <0.80 is consistent with a hemodynamically significant stenosis. (Images courtesy of Dr. James Min, Cornell University, New York.)
Noninvasive Cardiac Imaging: Echocardiography, Nuclear Cardiology, and Magnetic Resonance/Computed Tomography Imaging
1845CHAPTER 241
with intermediate clinical risk, stress imaging with either SPECT or
echocardiography has been shown to accurately reclassify patients who
are initially classified as intermediate risk by ETT as low or high risk
(Fig. 241-15). Following this staged strategy of applying the low-cost
ETT first and reserving more expensive imaging to refine risk stratification to patients initially classified as intermediate risk by ETT is
more cost-effective than applying stress or anatomic imaging as the
initial test routinely.
An imaging strategy is the recommended first step for patients who
are unable to exercise to an adequate workload and/or those with abnormal resting ECGs (e.g., left ventricular hypertrophy with strain, left
bundle branch block). Importantly, the most recent documents regarding appropriate use of imaging also considered that an imaging strategy
may be an appropriate first step in patients with intermediate-high
likelihood of CAD (e.g., diabetics, renal impairment) due to increased
overall sensitivity for diagnosis of CAD and improved risk stratification.
In considering an imaging strategy, the evidence supporting the role of
ischemia assessment versus anatomy must be considered. From the discussion above, for patients with atypical chest pain and a low pretest risk
of CAD, a normal coronary CTA is helpful because it effectively excludes
the presence of obstructive CAD and the need for further testing, defines
a low clinical risk, and makes management decisions regarding referral
to coronary angiography straightforward. However, in patients with
an intermediate or higher pretest risk, coronary CTA is less effective
in excluding obstructive CAD owing to its limited accuracy to define
stenosis severity and predict ischemia; however, abnormal CTA results
are more problematic to interpret and to use as the basis for defining the
potential need of invasive coronary angiography and revascularization.
In such patients, a follow-up stress test is usually required to determine
the possible need of revascularization (Fig. 241-16).
The justification of stress imaging in testing strategies
has hinged on the identification of which patients may
benefit from a revascularization strategy by means of noninvasive estimates of jeopardized myocardium rather than
angiography-derived anatomic stenoses. However, recent
evidence from the ISCHEMIA trial suggests that optimal
medical therapy provides comparable prognostic benefit to
coronary revascularization in patients with moderate myocardial ischemia. Coronary revascularization is reserved
for patients with very extensive evidence of ischemia by
stress imaging and/or inadequate symptom control by
optimal medical therapy. While the available data suggest
similar diagnostic accuracy for SPECT and echocardiography but higher for PET and CMR, the choice of strategy
depends on availability and local expertise.
Selecting a Testing Strategy in Patients with
Known CAD Use and selection of testing strategies
in symptomatic patients with established CAD (i.e.,
prior angiography, prior myocardial infarction, prior
revascularization) differ from those in patients without
prior CAD. Although standard ETT may help distinguish cardiac from noncardiac chest pain, exercise ECG
has several limitations following myocardial infarction
and revascularization (especially coronary artery bypass
grafting). These patients frequently have rest ECG abnormalities. In addition, there is a clinical need to document
both the magnitude and localization of ischemia to be
able to direct therapy, especially the potential need for
targeted revascularization. Consequently, imaging tests
are preferred for evaluating patients with known CAD.
There are also important differences in the effectiveness of imaging tests in these patients. As discussed
above, coronary CTA is limited in patients with prior
revascularization. While CTA provides excellent visualization of the bypass grafts, the native circulation tends
to get heavily calcified and is generally not a good target
for imaging with CTA. Likewise, blooming artifacts from
metallic stents also limit the application of coronary
Duke treadmill score
Low
Event rate (%/year)
0
2
4
6
8
10
12
Intermediate High
10
9.1
3.6
8.9
6.4
0.4
7.8
1.8
0.3
Exercise SPECT
Normal
Mild
Severe
Duke treadmill score
Low Intermediate High
11
5.7
2.7
6.7
3.6
1.7
2.9
1.5 0.7
Exercise Echo
Normal
Single VD
Multi VD
FIGURE 241-15 Incremental risk stratification of stress imaging over Duke treadmill score in patients with suspected coronary artery disease. Stress imaging is most
valuable in the intermediate-risk group. SPECT, single-photon emission computed tomography; VD, vessel disease. (Reproduced with permission from R Hachamovitch
et al: Exercise myocardial perfusion SPECT in patients without known coronary artery disease. Circulation 93:905, 1996; https://www.ahajournals.org/doi/full/10.1161/01.
CIR.93.5.905.)
Stress
Stress
Stress
Rest
Rest
Rest
FIGURE 241-16 Selected views from coronary computed tomography angiographic (CTA) images
(top panel) and stress and rest rubidium-82 myocardial perfusion positron emission tomography
images (lower panel) obtained on a 64-year-old male patient with atypical angina. The CTA
images demonstrate dense focal calcifications in the left main (LM) and left anterior descending
(LAD) coronary arteries and a significant noncalcified plaque in the mid right coronary artery (RCA;
arrow). The myocardial perfusion images demonstrated no evidence of flow-limiting stenosis. LCx,
left circumflex artery; OM, obtuse marginal branch.
1846 PART 6 Disorders of the Cardiovascular System
CTA in patients with prior percutaneous coronary intervention. If an
anatomic strategy is indicated, direct referral to invasive angiography
is preferred.
Stress imaging approaches are especially useful and preferred in
symptomatic patients with established CAD. As in patients without
prior CAD, normal imaging studies in symptomatic patients with
established CAD also identify a low-risk cohort. In those with abnormal stress imaging studies, the degree of abnormality relates to posttest
risk. In addition, stress imaging approaches can localize and quantify
the magnitude of ischemia, thereby assisting in planning targeted
revascularization procedures. As in patients without prior CAD, the
choice of stress imaging strategy depends on availability and local
expertise.
Testing Strategy Considerations in Patients Presenting with
Chest Pain to the ED Although acute chest pain is a frequent reason for patient visits to the ED, only a small minority of those presentations represent an acute coronary syndrome (ACS). Strategies used in
the evaluation of these patients include novel cardiac biomarkers (e.g.,
serum troponins), conventional stress testing (ETT), and noninvasive
cardiac imaging. It is generally accepted that the primary goal of this
evaluation is exclusion of ACS and other serious conditions rather than
detection of CAD.
The routine evaluation of acute chest pain in most centers in the
United States includes admission to a chest pain unit to rule out
ACS with the use of serial ECGs and cardiac biomarkers. In selected
patients, stress testing with or without imaging may be used for further
risk stratification. Stress echocardiography and radionuclide imaging
are among the most frequently used imaging approaches in these
patients. Multiparametric CMR imaging has also been used successfully in patients with acute chest pain (Video 241-5). Due to its ability
to probe multiple aspects of myocardial physiology, cardiac anatomy,
and tissue characterization with LGE imaging, CMR is useful in diagnosing conditions that mimic ACS (e.g., acute myocarditis, takotsubo
cardiomyopathy, pericarditis) (Fig. 241-17).
As discussed above, coronary CTA is a rapid and accurate imaging
technique to exclude the presence of CAD and is well suited for the
evaluation of patients with acute chest pain (Fig. 241-18). Four randomized clinical trials have demonstrated the feasibility, safety, and
accuracy of coronary CTA in the ED as compared to usual care (which
typically includes stress imaging). Patients in these trials had a very low
clinical risk. Overall, there were no deaths and very few myocardial
infarctions without differences between the groups. Likewise, there
were no differences in postdischarge ED visits or rehospitalizations.
These studies showed decreased length of stay with coronary CTA, and
most but not all reported cost savings. An observation from a recent
meta-analysis was that, compared to usual care, more patients assigned
to coronary CTA underwent cardiac catheterization (6.3% vs 8.4%,
respectively) and revascularization (2.6% vs 4.6%, respectively). The
relative increased frequency in the referral to cardiac catheterization
and revascularization after coronary CTA compared to stress imaging
testing strategies has also been observed in patients with stable chest
pain syndromes.
Taken together, the available data clearly suggest that not all patients
presenting with acute chest pain require specialized imaging testing.
Patients with very low clinical risk and negative biomarkers (especially
high-sensitivity troponin assays) can be safely triaged. The use of
imaging tests in patients with low-intermediate risk should be carefully
considered, especially given the trade-offs discussed above.
■ VALVULAR HEART DISEASE
Abnormalities of any of the four valvular structures in the heart can
lead to significant cardiac dysfunction, heart failure, or even death.
Echocardiography, CMR, and cardiac CT can be used for the evaluation of valvular heart disease, although echocardiography is generally
considered the first imaging test for the assessment of valvular heart
disease. In addition, echocardiography is the most cost-effective
screening method for valvular heart disease. In some cases, CMR
can complement echocardiography when echocardiographic acoustic
window is inadequate, to quantify blood flow data more precisely, or
to provide complimentary assessment of adjacent vascular structures
relevant to the valvular condition.
Echocardiography can be used to assess both regurgitant and
stenotic lesions of any of the cardiac valves. Typical indications for
echocardiography to assess valvular heart disease include cardiac murmurs identified on physical examination, symptoms of breathlessness
that may represent valvular heart disease, syncope or presyncope, and
preoperative exams in patients undergoing bypass surgery. A standard
echocardiographic examination should include qualitative and quantitative assessment of all valves regardless of indication and should serve
as an adequate screening test for significant valvular disease.
Assessment of Aortic Stenosis Aortic stenosis, one of the most
common forms of valvular heart disease, most often occurs because
of gradual progression of valvular calcification in both normal and
congenitally abnormal valves. Assessment of aortic stenosis is most
commonly performed with echocardiography, although techniques for
quantitative assessment of aortic stenosis with CMR have been developed and increasingly used over the past decade. Echocardiographic
assessment generally begins with visual inspection of the valve. This
allows for assessment of valvular morphology, whether it is tricuspid,
bicuspid, or some variant; degree of leaflet calcification; and leaflet
excursion.
The normal aortic valve consists of three leaflets or cusps: the right
coronary, the left coronary, and the noncoronary cusps. Abnormalities
of cusp development are some of the most common congenital heart
anomalies, the most common of which is bicuspid aortic valve, with
two opening leaflets rather than three (Fig. 241-19). The aortic valve
can be visualized on echocardiography, although sometimes it can be
difficult to distinguish true bicuspid aortic valve from variants, including the presence of a vestigial commissure (raphe). Bicuspid aortic
valve, one of the most common congenital anomalies, predisposes to
both aortic stenosis and aortic insufficiency.
FIGURE 241-17 A four-chamber long-axis late gadolinium enhancement (LGE)
image of a patient with acute myocarditis. Note that the LGE primarily involved the
epicardial aspect of the myocardium (arrows), sparing the endocardium, which is a
feature that distinguishes myocarditis from myocardial infarction, which affects the
endocardium. Also note the multiple foci of LGE in this case affecting the lateral wall
of the left ventricle. Viral myocarditis often presents with this pattern.
Noninvasive Cardiac Imaging: Echocardiography, Nuclear Cardiology, and Magnetic Resonance/Computed Tomography Imaging
1847CHAPTER 241
The degree of aortic stenosis is assessed by estimating both the
pressure gradient across the valve and the valve area. Patients with
moderate aortic stenosis or higher generally have peak instantaneous
velocities of 3.0 m/s and higher, and often higher than 4.0 m/s, corresponding to pressure gradients of 36 and 64 mmHg, respectively.
Because pressure gradients across the aortic valve can be underestimated in patients with severe left ventricular dysfunction, estimation of
valve area by the continuity principle is the most accurate technique for
assessing the severity of the stenosis. However, evaluation of the patient
with so-called low-flow or low-gradient aortic stenosis can be challenging and sometimes requires provocative testing such as dobutamine
echocardiography. In these cases, it is important to distinguish whether
the valve is indeed capable of opening further or simply behaving like a
stenotic valve because of the low-pressure gradient.
Aortic valve areas <1.0 cm2
are generally considered severe, and
valve areas <0.6 cm2
are considered critical. Because patients with good
left ventricular function can often tolerate severe aortic stenosis for a
considerable period of time, valve areas or gradients alone should not
be used to determine whether an individual patient should undergo
aortic valve surgery as this remains a clinical decision.
Some patients with apparent aortic stenosis have subvalvular or even
supravalvular obstruction. Hypertrophic cardiomyopathy represents
the classic form of subvalvular aortic stenosis, but this is usually easily
distinguished from aortic stenosis on echocardiography as the valve
leaflets can be seen opening during systole. Subaortic membranes can
behave very similarly to leaflet aortic stenosis, and the membranes
themselves can be very thin and difficult to visualize, although the
presence of a murmur, a gradient across the valve with aortic leaflets
that appear to open normally, is highly suggestive of a membrane.
Supravalvular aortic stenosis, although exceedingly rare, also occurs.
The emergence of transcatheter aortic valve intervention as a therapeutic option for patients with severe aortic stenosis who are not
optimal candidates for surgical replacement has resulted in a very
important clinical role for multimodality imaging. Imaging plays a critical role in preprocedural planning, intraprocedural implantation optimization, and follow-up of these patients. CT plays an important role
in defining the eligibility of the proposed access site (CTA of the aorta
and iliac arteries) and in defining the anatomic relationships between
the aortic valve and aortic root, left ventricle, and coronary ostia. Cardiac CT and transesophageal echocardiography are also used to define
the device size. Transesophageal echocardiography is used during the
device implantation to ensure the best prosthesis–patient match, to
assess prosthesis position and function after deployment, and to identify immediate complications (e.g., aortic insufficiency, paravalvular
leak resulting from patient–prosthesis mismatch). Echocardiography is
the imaging modality of choice for long-term surveillance.
Assessment of Aortic Regurgitation Assessment of aortic
regurgitation requires qualitative assessment of the aortic valve structure. Aortic regurgitation is common with congenital abnormalities of
the aortic valve, the most common of which is bicuspid aortic valve.
Aortic regurgitation often coexists with aortic stenosis, and it is not
uncommon for patients to have both severe aortic stenosis and regurgitation. Congenital abnormalities of the aortic leaflets, such as bicuspid
aortic valve, are common causes of aortic insufficiency. Dilatation
of the aortic root, as occurs in patients with hypertension and other
disorders in which aortic dilatation can occur, can also lead to aortic
regurgitation even when the valve leaflets are intrinsically normal due
to malcoaptation of the leaflets. Aortic root dilatation is common in
patients with aortic regurgitation, both as a cause or coexisting lesion,
and the aortic root and ascending aorta should be measured and followed in these patients (Fig. 241-20).
Because aortic regurgitation can result in dilatation of the left ventricle over time with ultimate reduction in ventricular function, caring
for the patient with aortic regurgitation requires serial assessment of
ventricular size and function. Patients whose ventricles dilate beyond
an end-systolic diameter of 5.5 cm or whose LVEF declines below
normal are at significantly higher risk of death or heart failure, and
these measures are often used to decide the need for valve surgery.
Quantitation of regurgitation itself can be performed using a number
of methods. Semiquantitative visual assessment of aortic regurgitant jet
width and depth by color flow Doppler remains the most used. The jet
diameter as a ratio of the left ventricular outflow tract diameter proximal to the valve represents one of the most reliable indices of severity
A
RCA
B C
FIGURE 241-18 Representative coronary computed tomography angiographic (CTA) images of two patients presenting to the emergency department with chest pain
and negative biomarkers. The patient in A had angiographically normal coronary arteries; the panel shows a representative view of the right coronary artery (RCA). B
and C show a corresponding significant stenosis in the mid portion of the RCA on both the CTA (B) and invasive angiographic view (C). (Images used with permission from
Dr. Quynh Truong, Massachusetts General Hospital, Boston, MA.)
A B C
FIGURE 241-19 Normal aortic valve in the parasternal long-axis view (A) and short-axis view (B), and bicuspid aortic valve showing typical 10 o’clock to 4 o’clock leaflet
orientation (C).
1848 PART 6 Disorders of the Cardiovascular System
A B
FIGURE 241-20 Aortic regurgitation visualized by color flow Doppler in the parasternal long-axis view (A) and
the parasternal short-axis view (B).
–200
–100
0
100
200
300
400
500
600
700
200 400 600 800 1000 1200
Time (ms)
Forward flow volume 123 mL
Flow (ml/s)
Regurgitant volume 67 mL
FIGURE 241-21 The resultant flow curve generated from phase contrast imaging
demonstrates a forward flow of 123 mL and a regurgitant volume of 67 mL, yielding a
regurgitant fraction of 54% indicating severe aortic regurgitation.
and correlates well with angiographic assessment. Similarly, the vena
contracta, which represents the smallest diameter of the regurgitant
flow at the level of the valve, can be used to assess the severity of aortic
regurgitation. Other Doppler-based methods include assessing the
pressure half-time, or rate of decline of the pressure gradient between
the aorta and left ventricle, a measure of acuity of aortic regurgitation, and assessing aortic flow reversal in the descending aorta. The
regurgitant volume can be calculated by comparing the flow across the
aortic and pulmonic valves, assuming the pulmonic valve is competent.
Central or perivalvular aortic regurgitation is common in patients following TAVR and is generally assessed immediately after the procedure
and on follow-up echocardiography.
CMR offers several advantages over echocardiography in the
assessment of aortic regurgitation. CMR is more accurate than
echocardiography for assessing small changes in cardiac size or function longitudinally in patients with aortic insufficiency. In addition,
CMR can accurately quantify aortic regurgitant volume secondary to
aortic insufficiency better than echocardiography. CMR can also capture aortic size in 3D that may be helpful in determining the etiology of
the aortic regurgitation or in monitoring progression of the condition
(Fig. 241-21 and Video 241-6).
Assessment of Mitral Regurgitation The normal mitral valve
consists of an anterior and posterior leaflet in a saddle shape configuration (Fig. 241-22). The leaflets are attached to the papillary muscles
via chordae tendineae that insert on the ventricular side of the leaflets.
Mitral regurgitation can occur due to abnormalities of the leaflets,
the chordal structures, or the ventricle, or any combination of these
(Fig. 241-23).
Mitral valve prolapse, in which one leaflet moves behind the plane of
the other leaflet, can be due to myxomatous degeneration of the valves
and leaflet redundancy, disruption of chordal structures secondary
to degenerative disease, or papillary muscle rupture or dysfunction
following myocardial infarction. Regurgitant jets can be visualized
using color flow Doppler. The velocity of regurgitant jets is driven
by the pressure gradient between the two chambers. This velocity
tends to be quite high for left-sided regurgitant lesions, including mitral regurgitation and
aortic regurgitation, resulting in turbulent jets
on color flow Doppler (Fig. 241-23). Visual
estimation of color flow Doppler is generally
sufficient for qualitative assessment of regurgitant severity but can dramatically under- or
overestimate regurgitation severity, particularly
when regurgitant jets are quite eccentric. For
this reason, quantitative assessment is generally recommended, especially when making
clinical decisions about surgical intervention.
The proximal isovelocity surface area (PISA)
method is generally used for quantitative
assessment of severity of mitral regurgitation. This method relies on
estimation of the velocity of flow acceleration at a specific distance
proximal to the valve with the assumption that the flow accelerates in
concentric hemispheres.
As with aortic insufficiency, assessment of ventricular structure
and function is also integral in the evaluation of mitral regurgitation.
Although some patients have mitral regurgitation due to intrinsic
abnormalities of the valve itself, in others, the valve can be relatively
normal but the mitral regurgitation can be secondary to dilatation and
remodeling of the left ventricle. So-called functional mitral regurgitation is generally secondary to apical displacement of the papillary
muscles in a dilated ventricle, resulting in the leaflets of the mitral valve
being pulled toward the apex of the heart, resulting in poor coaptation
during systole and resultant relatively central mitral regurgitation. This
type of mitral regurgitation can generally be distinguished from intrinsic mitral valve disease, and the surgical or procedural treatment of
these conditions can be different. Knowledge of the etiology of mitral
regurgitation can be important for a surgeon planning mitral valve
surgery. Moreover, new procedural approaches to mitral valve disease
may be different depending on the etiology.
Ventricular dilatation is an important predictor of outcome in
patients with mitral regurgitation of any cause. It is important to realize
that in a patient with significant mitral regurgitation, a large portion
of the blood being ejected from the left ventricle with every beat is
regurgitant, thus artificially increasing the ejection fraction. Thus, an
ejection fraction of 55% in a patient with severe mitral regurgitation
may actually represent substantial reduction in myocardial systolic
function.
CMR can be helpful in evaluating mitral regurgitation in a subset of
patients when echocardiographic assessment is inadequate. CMR can
directly quantify regurgitant volume of the mitral regurgitant jet or
indirectly quantify regurgitant volume by measuring the difference of
left ventricular stroke volume and aortic forward flow.
Assessment of Mitral Stenosis Rheumatic mitral disease remains
the most common cause of mitral stenosis, although mitral stenosis can
also result from severe calcification of the mitral leaflets. Rheumatic
mitral stenosis has a distinct appearance characterized by tethering at
the leaflet tips and relative pliability of the leaflets themselves, resulting
in a hockey stick–type deformation particularly of the anterior leaflet
(Fig. 241-24). Narrowing of the mitral orifice impedes flow from the
left atrium to the left ventricle, resulting in increased pressures in the
left atrium, which are then transmitted backward into the pulmonary
vasculature and the right side of the heart. When mitral stenosis is
suspected, echocardiography can be useful for determining etiology
(specifically whether it is rheumatic or not), estimating the valve areas
and gradients across the valve, assessing the left atrium, and assessing
right ventricular size and function. Assessment of left atrial size and
right ventricular size and function is particularly useful in helping
determine the severity of the mitral stenosis.
■ MYOCARDIAL INFARCTION AND HEART FAILURE
Role of Imaging after Myocardial Infarction Imaging can
be useful in the immediate and long-term follow-up of patients
with myocardial infarction. As discussed earlier in the chapter, LGE
Noninvasive Cardiac Imaging: Echocardiography, Nuclear Cardiology, and Magnetic Resonance/Computed Tomography Imaging
1849CHAPTER 241
FIGURE 241-22 Normal mitral valve in two-dimensional views (left) and with three-dimensional imaging (right).
A B C
FIGURE 241-23 A. Mitral valve prolapse with posterior leaflet visualized prolapsing behind the plane of the anterior leaflet (arrow). B. Color flow Doppler showing mitral
regurgitation in a patient with mitral valve prolapse. C. Severe functional mitral regurgitation in a patient with a dilated left ventricle.
A B
FIGURE 241-24 A. Rheumatic mitral stenosis showing pliable leaflets tethered at the tips (arrow). Note the characteristically enlarged left atrium. B. Mitral stenosis
visualized from a three-dimensional echocardiogram.
1850 PART 6 Disorders of the Cardiovascular System
FIGURE 241-25 Example of a patient who presented with inferior ST-segment
elevation myocardial infarction (MI) after several days of intermittent chest pain.
The MRI confirmed an inferior MI by the location of late gadolinium enhancement
(LGE; red arrows). In addition, there is a central area of microvascular obstruction
(dark region surrounded by the bright LGE, white arrow). LV, left ventricle; RV, right
ventricle.
FIGURE 241-26 Acute left anterior descending artery distribution myocardial
infarction at end systole showing akinetic region (arrows).
imaging by CMR is the best technique for imaging for presence or the
extent of infarcted myocardium. In a recent multicenter study, LGE
imaging identified infarct location accurately and detected acute and
chronic infarcts at a sensitivity of 99 and 94%, respectively. In addition,
regions of microvascular obstruction (no-reflow) can be seen as dense
hypoenhanced areas within the core of a bright region of infarction
(Fig. 241-25). Both the presence of LGE and microvascular obstruction are markers of increased clinical risk.
While echocardiography is often used to assess myocardial function immediately after myocardial infarction, myocardial stunning is
common in the early post–myocardial infarction period, especially
in patients who undergo reperfusion therapy. In these patients, either
partial or complete recovery of ventricular function is common within
several days, so that early estimation of ejection fraction may be misleading. In patients with uncomplicated myocardial infarction, imaging can generally be deferred for several days so that a more accurate
assessment of cardiac function, including regional wall motion, can be
assessed (Fig. 241-26).
Echocardiography is the best method for assessment of patients with
suspected mechanical complications after myocardial infarction. These
include mitral regurgitation secondary to either papillary muscle dysfunction or rupture of papillary muscle head, ventricular septal defect,
or even cardiac rupture. A new severe systolic murmur should raise
suspicions for either severe mitral regurgitation or ventricular septal
defect. While cardiac rupture is often catastrophic, contained ruptures,
also known as pseudoaneurysms, can occur, and early diagnosis and
surgical treatment are the best way to maximize survival. The presence
of thrombus within the pericardial space following myocardial infarction should immediately raise suspicion of myocardial rupture and
represents a surgical emergency.
Some patients demonstrate progressive left ventricular dilatation
and dysfunction, known as cardiac remodeling, after myocardial infarction. Assessment of cardiac function and regional wall motion is useful
in the follow-up period, generally between 1 and 6 months following
infarction. The persistence of left ventricular systolic dysfunction following infarction is used to determine the type of therapy (e.g., angiotensin-converting enzyme inhibitors or angiotensin receptor blockers
are typically used in patients with systolic dysfunction following myocardial infarction).
In patients with acute or subacute myocardial infarction, investigation of residual ischemia and/or viability is occasionally an important
clinical question, especially among those with recurrent symptoms after
myocardial infarction (Fig. 241-27). All cardiac imaging techniques
can provide information regarding myocardial viability and ischemia.
The available data suggest that radionuclide imaging, especially PET, is
highly sensitive, with higher negative predictive value than dobutamine
echocardiography. In contrast, dobutamine echocardiography tends to
be associated with higher specificity and positive predictive accuracy
than the radionuclide imaging methods. The experience with CMR
suggests that it offers similar predictive accuracies as those seen with
dobutamine echocardiography.
Role of Imaging in New-Onset Heart Failure Echocardiography
is usually a first-line test in patients presenting with new-onset heart
failure. As discussed above, this test provides a direct assessment of
ventricular function and can help distinguish patients with reduced
from those with preserved ejection fraction. In addition, it provides
additional structural information including an assessment of valves,
myocardium, and pericardium.
Although coronary angiography is commonly performed in patients
with reduced ejection fraction, the determination of heart failure
etiology in an individual patient may be difficult even if angiographically obstructive CAD is present. Indeed, patients with heart failure
and no angiographic CAD may have typical angina or regional wall
motion abnormalities on noninvasive imaging, whereas patients with
angiographically obstructive CAD may have no symptoms of angina
or history of myocardial infarction. Thus, the appropriate classification for any given patient is not always clear, and it often requires the
complementary information of coronary angiography and noninvasive
imaging. As discussed above, stress radionuclide imaging and echocardiography can be helpful in delineating the extent and severity of
inducible myocardial ischemia and viability. Multiparametric CMR
can be quite helpful in the differential diagnosis of heart failure etiologies. Apart from quantifying left and right ventricular volumes and
function, CMR can provide information about myocardial ischemia
and scar. The pattern of LGE helps differentiate infarction (typically
starting in the subendocardium and involving a coronary territory)
from other forms of infiltrative or inflammatory cardiomyopathies
(typically involving the mid- or subepicardial layers without following
a coronary distribution) (Fig. 241-28). In addition, it can assess the
presence of myocardial edema using T1 or T2 tissue mapping methods
to provide information about the chronicity of ACSs or noncoronary
inflammatory conditions (e.g., myocarditis). Other methods such as
T2*
mapping of myocardial iron deposition assess the extent of iron
infiltration that can lead to cardiac toxicity. Infiltrative cardiomyopathy
such as amyloidosis typically has a restrictive cardiomyopathy pattern
characterized by biventricular increased wall thickness and bilateral
Noninvasive Cardiac Imaging: Echocardiography, Nuclear Cardiology, and Magnetic Resonance/Computed Tomography Imaging
1851CHAPTER 241
Contrast-enhanced MRI
Positron emission tomography
Perfusion
Perfusion
Metabolism
Metabolism
FIGURE 241-27 Examples of myocardial viability patterns obtained with cardiac magnetic resonance imaging (MRI) and positron emission tomography (PET) in three
different patients with coronary artery disease. The top panel demonstrates extensive late gadolinium enhancement (bright white areas) involving the anterior, anteroseptal,
and apical left ventricular walls (arrows), consistent with myocardial scar and nonviable myocardium. The lower left panel demonstrates rubidium-82 myocardial perfusion
and 18F-fluorodeoxyglucose (FDG) images showing a large and severe perfusion defect in the anterior, anterolateral, and apical walls, indicating preserved glucose
metabolism (so-called perfusion-metabolic mismatch) consistent with viable myocardium. The right lower panel shows similar PET images demonstrating concordant
reduction in perfusion and metabolism (so-called perfusion-metabolic match) in the lateral wall, consistent with nonviable myocardium.
atrial enlargement, as assessed by both echocardiography and CMR.
CMR of patients with cardiac amyloidosis often also demonstrates a
characteristic pattern of diffuse endocardial infiltration of the left ventricle and the atria (Fig. 241-28). On strain echocardiography, patients
with cardiac amyloidosis show a reduction in systolic function, which
typically spares the apical left ventricular segments. Bone scintigraphy
complements the use of echocardiography and CMR in cardiac amyloidosis by allowing accurate noninvasive distinction of transthyretin
(ATTR) from light chain (AL) cardiac amyloidosis: ATTR typically
shows intense 99mTc tracer uptake compared to patients with AL amyloidosis (Fig. 241-29). Hypertrophic cardiomyopathy has variable
degree of increased ventricular thickness and often is seen to have
outflow obstruction and intense LGE in regions with marked hypertrophy (Fig. 241-30). CMR also can quantify myocardial iron content in
patients at risk of iron-overload cardiomyopathy (Video 241-7).
PET metabolic imaging has a complementary role in the evaluation
of inflammatory cardiomyopathies, especially sarcoidosis where the
presence of focal and/or diffuse glucose uptake can help identify areas
of active inflammation. In addition, for patients undergoing immunosuppressive therapy, PET is frequently used to monitor therapeutic
response (Fig. 241-31). In patients with ischemic cardiomyopathy,
radionuclide imaging in general and PET in particular are frequently
used to quantify the presence and extent of myocardial ischemia and
viability to assist with clinical decision making related to myocardial
revascularization (Fig. 241-26).
■ ASSESSING CARDIAC FUNCTION IN PATIENTS
UNDERGOING CANCER TREATMENT
Therapies used to treat cancer can adversely affect the cardiovascular
system. As the efficacy of cancer treatment and survival improve, many
patients are presenting with late adverse consequences from chemotherapy and/or radiation therapy on cardiovascular function. Thus,
the morbidity and mortality from late cardiovascular complications
threaten to offset the early gains in cancer survival, especially among
children and young adults. Early recognition and treatment of cardiomyocyte injury are critical for successful application of preventative
therapies but difficult because the adverse effects on cardiac function
are a relatively late manifestation after exposure to anticancer therapy.
The accepted standard for clinical diagnosis of cardiotoxicity is
defined as a >5% reduction in LVEF to <55% with symptoms of heart
failure, or a >10% drop in LVEF to <55% in patients who are asymptomatic. Thus, noninvasive imaging plays a major role in diagnosing
and monitoring for cardiac toxicity in patients undergoing cancer
treatment. Radionuclide angiography has been the technique of choice
for quite some time. However, echocardiography now plays a major
role in this application.
Recently, more novel imaging approaches have been advocated,
including deformation imaging with echocardiography and fibrosis
imaging with CMR. These techniques have shown promising results in
experimental animal models and in humans. In addition, there are also
proof-of-concept studies in animal models using molecular imaging
approaches targeting the mechanisms of cardiac toxicity (e.g., apoptosis and oxidant stress), which can presumably provide the earliest signs
of the off-target effects of these therapies. However, these techniques
are currently considered experimental.
■ PERICARDIAL DISEASE
The fibroelastic pericardial sac surrounding the heart consists of a
visceral, or epicardial, layer and a parietal layer, with a generally small
amount of pericardial fluid in between layers. The pericardium is
generally quite pliable and moves easily with the heart during contraction and relaxation. Abnormalities of the pericardium can affect
cardiac function primarily by impairing the heart’s ability to fill.
Inflammation of the pericardium can lead to an accumulation of fluid
between the two layers, or pericardial effusion, which can be visualized
by echocardiography, CMR, or CT. Other reasons for accumulation
1852 PART 6 Disorders of the Cardiovascular System
A
E F G
Anterior Lateral
B C D
FIGURE 241-29 Multimodality cardiac imaging in a 71-year-old man with history of atrial fibrillation, heart failure with preserved ejection fraction, numbness in his
fingers, a history of bilateral carpal tunnel surgery, and remote history of back surgery with L3 and S1 fusion. A. Two-dimensional echocardiogram demonstrating moderate
increase in left ventricular thickness with a visually estimated left ventricular ejection fraction of 45–50% and small pericardial effusion. B and C. Mitral inflow and tissue
Doppler demonstrating abnormal diastolic function (E/e′ was >20, consistent with elevated left ventricular filling pressure). D. Bull’s-eye strain map demonstrating abnormal
global longitudinal strain at the basal segments (pink and blue colors) with characteristic apical sparing (red color). E. Cardiac MRI study showing normal left ventricular
cavity size, mildly increased left ventricular mass, and mildly enlarged right and left atria. F. The MRI shows a large amount of diffuse late gadolinium enhancement of all
myocardial left ventricular segments, but it is more prominent in a circumferential subendocardial pattern (arrowheads). G. The 99mTc pyrophosphate images demonstrate
increased myocardial uptake of the radiotracer (uptake in the heart is greater than ribs, grade 3). (Images courtesy of Dr. Sarah Cuddy, Brigham and Women’s Hospital.)
FIGURE 241-28 Differentiation of various cardiomyopathies by cardiac magnetic resonance (CMR). The left upper panel shows the short-axis late gadolinium enhancement
(LGE) imaging of a patient who suffered an acute myocardial infarction. Note LGE of the endocardial myocardium in the inferior wall extending from the septum to the
lateral wall associated with myocardial thinning (arrows). The right upper panel shows the long-axis LGE imaging of a patient who has cardiac amyloidosis. Note the diffuse
LGE throughout left ventricular myocardium, the left atrium, and the interatrial septum (arrows). In addition, the blood pool is characteristically dark in signal indicating
sequestration of gadolinium contrast out of the blood pool after injection due to a high burden of amyloidosis in other organs. The left lower panel shows a cine diastolic
long-axis image of a patient with a nonischemic dilated cardiomyopathy. Note that there is extensive sponge-like noncompacted myocardium of the left ventricle (LV) as well
as dilatation of all four cardiac chambers. This patient has a nonischemic dilated cardiomyopathy secondary to LV noncompaction. The right lower panel shows a 22-yearold female patient with a recent episode of acute chest pain and troponin elevation. Note the multiple mid-wall foci of LGE, which suggests acute myocarditis (arrows). LA,
left atrium; RA, right atrium; RV, right ventricle.
Noninvasive Cardiac Imaging: Echocardiography, Nuclear Cardiology, and Magnetic Resonance/Computed Tomography Imaging
1853CHAPTER 241
LV
RV
FIGURE 241-30 This figure demonstrates three pulse sequence techniques by cardiac magnetic resonance that are often used to assess patients with hypertrophic
cardiomyopathy, all displayed in the mid short-axis scan plane. The center panel demonstrates that the left ventricle (LV) was markedly thickened in its wall thickness
especially in the LV septum (red arrows). This finding was matched by marked regions of late gadolinium enhancement (LGE), which was consistent with fibrosis in these
segments (right panel, white arrows). The left panel was cine myocardial tagging in the same slice plane. Myocardial tagging is used to assess the normal intramyocardial
strain by assessing distortion of the myocardial grids during systole. In this case, despite normal-appearing systolic radial wall thickening, the myocardial strain as assessed
by the distortion of grids was markedly reduced (left panel, white arrows). This finding is consistent with substantial myofibril disarray in the anterior and anteroseptal
segments in this patient. RV, right ventricle.
RV
Perfusion
Perfusion
Metabolism
Metabolism
Ant
Inf
Lat
21 22 23 24 25 26 27 28 29 30 31
24 25 26 27 28 29 30 31 32 33 34 35
34 35 36 37 38 39 40 41 42 43 44 45
38 39 40 41 42 43 44 45 46 47 48 49
Sep
LV
RV
LV
FIGURE 241-31 Representative cardiac magnetic resonance (CMR; top panel) and positron emission tomography (PET; lower panel) images from a 45-year-old male
presenting with complete heart block. The CMR images demonstrate extensive late gadolinium enhancement in the subepicardial left ventricular (LV) anterior and
anteroseptal walls and also in the right ventricular (RV) free wall (arrows). The PET images demonstrate extensive fluorodeoxyglucose uptake in the same areas, most
consistent with active inflammation due to sarcoidosis.
of pericardial fluid include infection, malignancy, and bleeding into
the pericardium. The latter can be the result of catastrophic processes
such as trauma, cardiac rupture, perforation in the setting of a cardiac
procedure, cardiac surgery, or dissection of the aorta with extension in
the pericardium.
Echocardiography remains the initial test of choice for assessing
pericardial disease, especially effusions (Fig. 241-32). Moreover,
echocardiography can be useful in evaluating for pericardial constrictive physiology, in which a thick noncompliant pericardium impairs
cardiac filling. The location, size, and physiologic consequences of
accumulated pericardial effusion can generally easily be determined
by echocardiography. Pericardial tamponade occurs when enough
pericardial fluid accumulates so that the intrapericardial pressure
exceeds filling pressures of the heart, generally the right ventricle. The
balance between intrapericardial pressure and ventricular pressure is
more important than the extent of fluid accumulation. Conditions in
which pericardial effusions accumulate over a long period of time, as
can be the case in the setting of malignant effusions, can lead to large
pericardial fluid accumulations without the classic hemodynamic
findings associated with pericardial tamponade. In contrast, rapid
accumulations of pericardial fluid, such as those that occur due to cardiac rupture or perforation, can lead to tamponade physiology without
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