2026 PART 6 Disorders of the Cardiovascular System
pain, syncope, congestive heart failure (CHF), murmurs,
arrhythmias, conduction disturbances, pericardial effusion,
and pericardial tamponade. Additionally, embolic phenomena and constitutional symptoms may occur.
Myxoma Myxomas are the most common type of primary cardiac tumor in adults, accounting for one-third
to one-half of all cases at postmortem examination, and
approximately three-quarters of the tumors treated surgically. They occur at all ages, most commonly in the third
through sixth decades, with a female predilection. Approximately 90% of myxomas are sporadic; the remainder
are familial with autosomal dominant transmission. The
familial variety often occurs as part of a syndrome complex
(Carney complex) that includes (1) myxomas (cardiac,
skin, and/or breast), (2) lentigines and/or pigmented nevi,
and (3) endocrine overactivity (primary nodular adrenal
cortical disease with or without Cushing’s syndrome, testicular tumors, and/or pituitary adenomas with gigantism or
acromegaly). Certain constellations of findings have been
referred to as the NAME syndrome (nevi, atrial myxoma,
myxoid neurofibroma, and ephelides) or the LAMB syndrome (lentigines, atrial myxoma, and blue nevi), although
these syndromes probably represent subsets of the Carney
complex. The genetic basis of this complex has not been elucidated
completely; however, inactivating mutations in the tumor-suppressor
gene PRKAR1A, which encodes the protein kinase A type I-α regulatory
subunit, have been identified in ~70% of patients with Carney complex.
Pathologically, myxomas are gelatinous structures that consist of
myxoma cells embedded in a stroma rich in glycosaminoglycans.
Most sporadic tumors are solitary, arise from the interatrial septum
in the vicinity of the fossa ovalis (particularly in the left atrium), and
are often pedunculated on a fibrovascular stalk. In contrast, familial
or syndromic tumors tend to occur in younger individuals, are often
multiple, may be ventricular in location, and are more likely to recur
after initial resection.
Myxomas commonly present with obstructive signs and symptoms.
The most common clinical presentation mimics that of mitral valve
disease: either stenosis owing to tumor prolapse into the mitral orifice
or regurgitation resulting from tumor-induced valvular trauma or
distortion. Ventricular myxomas may cause outflow tract obstruction
similar to that caused by subaortic or subpulmonic stenosis. The
symptoms and signs of myxoma may be sudden in onset or positional
in nature, owing to the effects of gravity on tumor position. A characteristic low-pitched sound, a “tumor plop,” may be appreciated on
auscultation during early or mid-diastole and is thought to result from
the impact of the tumor against the mitral valve or ventricular wall.
Myxomas also may present with peripheral or pulmonary embolic
phenomenon (resulting from embolization of tumor fragments or
tumor-associated thrombus) or with constitutional signs and symptoms, including fever, weight loss, cachexia, malaise, arthralgias, rash,
digital clubbing, and Raynaud’s phenomenon. These constitutional
symptoms are likely the result of cytokines (e.g., interleukin 6) secreted
by the myxoma. Laboratory abnormalities, such as hypergammaglobulinemia, anemia, polycythemia, leukocytosis, thrombocytopenia or
thrombocytosis, elevated erythrocyte sedimentation rate, and elevated
C-reactive protein level are often present. These features account for
the frequent misdiagnosis of patients with myxomas as having endocarditis, collagen vascular disease, or a paraneoplastic syndrome.
Two-dimensional and three-dimensional transthoracic and/or
transesophageal echocardiography are useful in the diagnosis of
cardiac myxoma and allow for assessment of tumor size and determination of the site of tumor attachment, both of which are important
considerations in the planning of surgical excision (Fig. 271-1). Computed tomography (CT) and magnetic resonance imaging (MRI) may
provide important additional information regarding size, shape, composition, and surface characteristics of the tumor (Fig. 271-2) and may
identify extracardiac intrathoracic involvement in patients in whom
metastatic disease is suspected.
A B
FIGURE 271-1 Transthoracic echocardiogram demonstrating a large atrial myxoma. The myxoma
(Myx) fills the entire left atrium in systole (A) and prolapses across the mitral valve and into the
left ventricle (LV) during diastole (B). RA, right atrium; RV, right ventricle. (Courtesy of Dr. Michael
Tsang; with permission.)
FIGURE 271-2 Cardiac magnetic resonance imaging demonstrating a rounded
mass (M) within the left atrium (LA). Pathologic evaluation at the time of surgery
revealed it to be an atrial myxoma. LV, left ventricle; RA, right atrium; RV, right
ventricle.
Although cardiac catheterization and angiography were previously
performed routinely before tumor resection, they no longer are considered mandatory when adequate noninvasive information is available and other cardiac disorders (e.g., coronary artery disease) are not
considered likely. Additionally, catheterization of the chamber from
which the tumor arises carries the risk of tumor embolization. Because
myxomas may be familial, echocardiographic screening of first-degree
relatives is appropriate, particularly if the patient is young and has
multiple tumors or features of a myxoma syndrome.
TREATMENT
Myxoma
Surgical excision using cardiopulmonary bypass is indicated
regardless of tumor size and is generally curative. Myxomas recur in
12–22% of familial cases but in only 1–2% of sporadic cases. Tumor
Atrial Myxoma and Other Cardiac Tumors
2027CHAPTER 271
recurrence most likely results from multifocal lesions in the former
setting and incomplete tumor resection in the latter.
Other Benign Tumors Cardiac lipomas, although relatively common, are usually incidental findings at postmortem examination; however, they may grow as large as 15 cm, may present as an abnormality of
the cardiac silhouette on chest x-ray, and should be resected if they produce symptoms owing to mechanical interference with cardiac function, arrhythmias, or conduction disturbances. Papillary fibroelastomas
are friable tumors with frond-like projections that are usually solitary
and are the most common tumors of the cardiac valves. Remnants
of cytomegalovirus have been recovered from these tumors, raising
the possibility that they arise as a result of chronic viral endocarditis.
Although usually clinically silent, they can cause valve dysfunction and
may embolize distally, resulting in transient ischemic attacks, stroke,
or myocardial infarction. In general, these tumors should be resected
even when asymptomatic, although a more conservative approach may
be considered for small, right-sided lesions. Rhabdomyomas and fibromas are the most common cardiac tumors in infants and children and
usually occur in the ventricles, where they may produce mechanical
obstruction to blood flow, thereby mimicking valvular stenosis, CHF,
restrictive or hypertrophic cardiomyopathy, or pericardial constriction.
Rhabdomyomas are probably hamartomatous growths, are multiple in
90% of cases, occur in ~50% of children with tuberous sclerosis, and
are associated with mutations in the tumor-suppressor genes TSC1 and
TSC2 (Fig. 271-3). These tumors have a tendency to regress completely
or partially; only tumors that cause obstruction require surgical resection. Fibromas are usually single, universally ventricular in location,
often calcified, and may be associated with mutations in the tumorsuppressor gene PTCH1. Fibromas tend to grow and cause arrhythmias and obstructive symptoms and should be completely resected
when possible. Paragangliomas are rare chromaffin cell tumors that
represent extra-adrenal pheochromocytomas. Most are located in the
roof of the left atrium and can be identified on cardiac CT or MRI or
with nuclear scanning using 131-I-metaiodobenzylguanidine. They
are highly vascular and may be hormonally active, resulting in uncontrolled hypertension. Extensive surgical resection is usually required.
Hemangiomas and mesotheliomas are generally small tumors, most
often intramyocardial in location, and may cause atrioventricular (AV)
conduction disturbances and even sudden death as a result of their propensity to develop in the region of the AV node. Other benign tumors
arising from the heart include teratoma, chemodectoma, neurilemoma,
granular cell myoblastoma, and paraganglioma.
Malignant Tumors Almost all malignant primary cardiac tumors
are sarcomas, which may be of several histologic types; angiosarcomas
are the most common type in adults, whereas rhabdomyosarcomas
are the most common type in children. In general, sarcomas are characterized by rapid progression that culminates in the patient’s death
within weeks to months from the time of presentation as a result of
hemodynamic compromise, local invasion, or distant metastases.
Almost one-third are metastatic at the time of initial diagnosis, usually
involving the lungs. Sarcomas commonly involve the right side of the
heart, are rapidly growing, frequently invade the pericardial space, and
may obstruct the cardiac chambers or venae cavae. Sarcomas also may
occur on the left side of the heart and may be mistaken for myxomas.
Isolated cardiac lymphomas have been rarely described, but more
commonly occur in the context of systemic disease. They are more
common in men and in the elderly; usually involve the right heart; may
represent with arrhythmias, syncope, CHF, or constitutional symptoms; and are usually of the large B-cell type.
TREATMENT
Malignant Tumors
The optimal therapy for cardiac sarcoma is complete resection,
often with neoadjuvant and postoperative chemotherapy; however,
at the time of presentation, many of these tumors have spread too
extensively to allow for surgical excision. Although there are scattered reports of palliation with radiotherapy and/or chemotherapy,
the response of cardiac sarcomas to these therapies is generally
poor. The one exception appears to be cardiac lymphosarcomas,
which may respond to a combination of chemo- and radiotherapy.
Primary cardiac lymphoma is the most chemotherapy-sensitive
primary cardiac malignancy, with long-term survival achieved in
~40% of treated individuals.
■ TUMORS METASTATIC TO THE HEART
Metastatic cardiac tumors are much more common than primary
cardiac tumors, and their incidence is likely to increase as the life
expectancy of patients with various forms of malignant neoplasms is
extended by more effective therapy and improved imaging modalities
allow earlier identification of metastatic disease. Although cardiac
metastases may occur with any tumor type, the relative incidence is
especially high in malignant melanoma and, to a somewhat lesser
extent, leukemia and lymphoma (Fig. 271-4). In absolute terms, the
most common primary sites from which cardiac metastases originate
are carcinoma of the breast and lung, reflecting the high incidence of
these malignancies. Cardiac metastases almost always occur in the setting of widespread primary disease; most often, there is either primary
or metastatic disease elsewhere in the thoracic cavity.
RA
RV
LV
T
T
T T
FIGURE 271-3 Transthoracic echocardiogram revealing multiple tumors (T)
consistent with rhabdomyomas in a 1-day-old infant. The largest tumor (arrows)
was located in the left antrioventricular groove and measured 2 cm × 2 cm. LV, left
ventricle; RA, right atrium; RV, right ventricle.
RV
LV
LA
Met
FIGURE 271-4 Large metastatic lesion (Met) in the left ventricle (LV) of a patient
with diffusely metastatic bladder cancer. The mass arose from the interventricular
septum and prolapsed into the aortic outflow tract during systole.
2028 PART 6 Disorders of the Cardiovascular System
■ CARDIAC TRAUMA
Traumatic cardiac injury may be caused by either penetrating or nonpenetrating trauma; the latter is often referred to as blunt cardiac injury
(BCI). Penetrating injuries most often result from gunshot or knife
wounds, and the site of entry is usually obvious. Blunt cardiac injuries
most often occur during motor vehicle accidents, either from rapid
deceleration or from impact of the chest against the steering wheel, but
can also result from falls from heights, crush injuries, blast injuries, and
violent assault. Importantly, rapid deceleration following motor vehicle
accidents may be associated with significant cardiac injury even in the
absence of external signs of thoracic trauma.
■ BLUNT CARDIAC INJURY
Myocardial contusion is a nonspecific term that has been used to
describe a broad spectrum of nonpenetrating cardiac injuries that
result in abnormalities on electrocardiogram (ECG), elevation in
cardiac biomarkers, and acute structural cardiac abnormalities
(Table 272-1). Importantly, the cardiac injury may initially be overlooked in trauma patients as the clinical focus is directed toward other,
more obvious injuries. Unfortunately, there is no one sign or symptom that confirms the diagnosis of BCI, and clinical, laboratory, and
radiographic findings may be nonspecific in the setting of significant
trauma. The physical examination may be challenging in the setting of
chest wall injury; however, patients should be carefully examined to
detect pericardial rubs, cardiac murmurs, and evidence of pericardial
tamponade (Chap. 270). The mechanism of injury and the presence of
other chest trauma should be considered when determining the index
of suspicion for BCI; however, there is no proven association between
sternal or rib fractures and the presence of BCI, and significant cardiac
injury may be present in the absence of chest wall abnormalities.
Chest pain is common following thoracic trauma, and while it
could indicate cardiac ischemia or pericardial injury, it often reflects
musculoskeletal trauma. Nonetheless, myocardial necrosis may occur
as a direct result of the blunt injury or as a result of traumatic coronary laceration, dissection, or thrombosis. The injured myocardium is
pathologically similar to infarcted myocardium and may be associated
with atrial or ventricular arrhythmias, conduction disturbances including bundle branch block, or abnormalities on ECG resembling those of
infarction or pericarditis. Thus, it is important to obtain an ECG in all
patients presenting with chest trauma and consider BCI as a cause of
otherwise unexplained ECG abnormalities.
272 Cardiac Trauma
Eric H. Awtry
TABLE 272-1 Spectrum of Cardiac Abnormalities Following Blunt
Cardiac Injury
ABNORMALITY COMMENTS
ECG abnormalities Sinus tachycardia, RBBB, ST-T wave abnormalities,
atrial and ventricular arrhythmias
Elevated cardiac
biomarkers
Troponin I and T are most specific
Focal wall motion
abnormality or
hematoma
Most commonly involving RV free wall, LV apex, and
interventricular septum
Valvular insufficiency Most commonly involving mitral and tricuspid valves
and occasionally the aortic valve
Myocardial rupture Ventricular septal defect or free wall rupture
Coronary artery injury Most commonly involving the LAD, usually presents
as STEMI
Pericardial effusion and
tamponade
Resulting from free wall rupture or coronary artery
laceration
Abbreviations: ECG, electrocardiogram; LAD, left anterior descending coronary
artery; LV, left ventricle; RBBB, right bundle branch block; RV, right ventricle; STEMI,
ST-segment elevation myocardial infarction.
Cardiac metastases may occur via hematogenous or lymphangitic
spread or by direct tumor invasion. While they generally manifest as
small, firm nodules, diffuse infiltration also may occur, especially with
sarcomas or hematologic neoplasms. The pericardium is most often
involved, followed by myocardial involvement of any chamber and,
rarely, by involvement of the endocardium or cardiac valves.
Cardiac metastases are clinically apparent only ~10% of the time,
are usually not the cause of the patient’s presentation, and rarely are the
cause of death. The vast majority occur in the setting of a previously
recognized malignant neoplasm. As with primary cardiac tumors, the
clinical presentation reflects more the location and size of the tumor
than its histologic type. When symptomatic, cardiac metastases may
result in a variety of clinical features, including dyspnea, acute pericarditis, cardiac tamponade, ectopic tachyarrhythmias, heart block, and
CHF. Importantly, many of these signs and symptoms may also result
from myocarditis, pericarditis, or cardiomyopathy induced by radiotherapy or chemotherapy, and a high index of suspicion for cardiac
involvement should be maintained for patients with malignant disease
who develop these symptoms.
Electrocardiographic (ECG) findings are nonspecific but may reveal
features consistent with pericarditis or may demonstrate low QRS voltage and electrical alternans in the setting of a large pericardial effusion.
On chest x-ray, the cardiac silhouette is most often normal but may be
enlarged or exhibit a bizarre contour. Echocardiography is useful for
identifying and assessing the significance of pericardial effusions and
visualizing larger metastases, although CT and radionuclide imaging
may define the tumor burden more clearly. Cardiac MRI offers superb
image quality and plays a central role in the diagnostic evaluation of
cardiac metastases and cardiac tumors in general. Pericardiocentesis
may allow for a specific cytologic diagnosis in patients with malignant
pericardial effusions with a reported sensitivity of 67–92%. Angiography is rarely necessary but may help to delineate discrete myocardial
lesions.
TREATMENT
Tumors Metastatic to the Heart
Most patients with cardiac metastases have advanced malignant
disease; thus, therapy is generally palliative and consists of controlling symptoms and treatment of the primary tumor. Symptomatic
malignant pericardial effusions should be drained by pericardiocentesis. Prolonged drainage (3–5 days) and concomitant instillation of a sclerosing agent (e.g., tetracycline or bleomycin) may
delay or prevent reaccumulation of the effusion, and creation of a
pericardial window allows drainage of the effusion to the adjacent
pleural or peritoneal space. Given the overall poor prognosis of
these patients, discussions regarding goals of care and involvement
of palliative care services are often appropriate.
■ FURTHER READING
Bussani R et al: Cardiac metastases. J Clin Pathol 60:27, 2007.
Mousavi N et al: Assessment of cardiac masses by cardiac magnetic
resonance imaging: Histological correlation and clinical outcomes. J
Am Heart Assoc 8:e007829, 2019.
Shapira O et al: Tumors of the heart, in Sabiston and Spenser Surgery
of the Chest, 9th ed, FW Sellke et al (eds). Philadelphia, Elsevier, 2016,
pp 1849–1857.
Tamin SS et al: Prognostic and bioepidemiologic implications of papillary fibroelastomas. J Am Coll Cardiol 65:2420, 2015.
Young PM et al: Computed tomography imaging of cardiac masses.
Radiol Clin N Am 57:75, 2019.
Cardiac Trauma
2029CHAPTER 272
Serum creatine kinase, myocardial band (CK-MB) isoenzyme levels
are increased in ~20% of patients who experience blunt chest trauma
but may be falsely elevated in the presence of massive skeletal muscle
injury and should not be relied upon to confirm the diagnosis of BCI
in the setting of trauma. Cardiac troponin levels are more specific for
identifying cardiac damage; patients with normal serial troponin levels after chest trauma are very unlikely to have cardiac injury. When
combined with a normal ECG, a normal troponin level at 6–8 h after
chest trauma essentially excludes BCI. Echocardiography is the most
useful modality for the detection of structural and functional sequelae
of BCI, including regional wall motion abnormalities (most commonly
involving the right ventricle, interventricular septum, or left ventricular apex), pericardial effusion, valvular dysfunction, and ventricular
rupture. A transthoracic echocardiogram (TTE) should be performed
in all patients with suspected BCI, especially in those with an abnormal
ECG, elevated troponin, or hemodynamic instability; transesophageal
echocardiography should be considered for patients in whom adequate
TTE images cannot be obtained.
Traumatic rupture of the cardiac valves or their supporting structures, most commonly of the tricuspid or mitral valve, leads to acute
valvular incompetence. This complication is usually heralded by
the development of a loud murmur, may be associated with rapidly
progressive heart failure, and can be diagnosed by either TTE or
transesophageal echocardiography.
The most serious consequence of nonpenetrating cardiac injury is
myocardial rupture, which may result in hemopericardium and tamponade (free wall rupture) or intracardiac shunting (ventricular septal
rupture). Although generally fatal, up to 40% of patients with cardiac
rupture have been reported to survive long enough to reach a specialized trauma center. Hemopericardium also may result from traumatic
rupture of a pericardial vessel or a coronary artery. Additionally, pericarditis and/or pericardial effusion may develop weeks or even months
after blunt chest trauma as a manifestation of the post–cardiac injury
syndrome, an inflammatory condition that resembles the postpericardiotomy syndrome (Chap. 270).
Blunt, nonpenetrating, often innocent-appearing injuries to the
chest may trigger ventricular fibrillation even in the absence of structural myocardial damage. This syndrome, referred to as commotio
cordis, occurs most often in adolescents during sporting events (e.g.,
baseball, hockey, football, and lacrosse) and is an electrical phenomenon that probably results from an impact to the chest wall overlying
the heart during the susceptible phase of repolarization (just before
the peak of the T wave). Survival depends on prompt defibrillation.
Sudden emotional or physical trauma, even in the absence of direct
cardiac trauma, may precipitate a transient catecholamine-mediated
cardiomyopathy referred to as takotsubo syndrome or apical ballooning
syndrome (Chap. 259).
Rupture or transection of the aorta, usually just above the aortic
valve or at the site of the ligamentum arteriosum, is a common consequence of nonpenetrating chest trauma and is the most common
vascular deceleration injury. The clinical presentation may be similar
to that of aortic dissection (Chap. 280); the arterial pressure and pulse
amplitude may be increased in the upper extremities and decreased
in the lower extremities, and chest x-ray may reveal mediastinal widening. Aortic rupture into the left thoracic space is almost universally
fatal; however, the rupture may occasionally be contained by the aortic
adventitia, resulting in a false, or pseudo-, aneurysm that may be discovered months or years after the initial injury.
TREATMENT
Blunt Cardiac Injury
The treatment of BCI depends on the specific injury sustained.
Hemodynamically stable patients with a normal ECG and normal
serial troponin levels are at low risk for BCI and usually do not
require hospital admission for cardiac issues. Patients with an
abnormal ECG and/or elevated troponin but normal echocardiogram usually warrant 24–48 h of telemetry monitoring; however,
other specific cardiac treatment is not usually required in the
absence of the development of arrhythmias. Patients with mechanical complications (acute valvular insufficiency, myocardial rupture)
require urgent operative correction.
■ PENETRATING CARDIAC INJURY
Penetrating injuries of the heart produced by knife or bullet wounds
usually result in rapid clinical deterioration and frequently in death
as a result of hemopericardium/pericardial tamponade or massive
hemorrhage. Nonetheless, up to half of such patients may survive long
enough to reach a specialized trauma center if immediate resuscitation
is performed. Prognosis in these patients relates to the mechanism
of injury, the specific cardiac chamber(s) involved, and their clinical
condition at presentation. In general, gunshot wounds are associated
with a higher mortality than are knife wounds; up to 65% of stabbing
victims survive versus <20% of shooting victims. This is likely in part
because ballistic wounds are more frequently associated with multichamber cardiac injury. As a result of its anterior position in the chest,
the right ventricle (RV) is the most frequently injured cardiac chamber,
followed by the left ventricle (LV); isolated atrial injury is uncommon.
Some studies suggest that RV injuries may be associated with a better
prognosis than LV injuries, and most reports indicate that multichamber involvement carries a worse prognosis than single-chamber injury.
Patients who are in hemodynamic collapse at presentation to the emergency department have a particularly poor prognosis with a mortality
rate approaching 90%, whereas ~75% of patients who are stable enough
to be brought to the operating room will survive.
Cardiac perforation of the right atrium, the RV free wall, or the
interventricular septum may occur as a complication of cardiac procedures including during placement of central venous/intracardiac
catheters, insertion of pacemaker/defibrillator leads, or performance
of RV endomyocardial biopsies, and coronary arterial perforation can
occur during deployment of intracoronary stents. These iatrogenic
injuries are associated with a better prognosis than are other forms of
penetrating cardiac trauma, likely related to a more limited degree of
cardiac injury and the rapid availability of corrective therapies.
Traumatic rupture of a great vessel from penetrating injury is usually
associated with hemothorax and, less often, hemopericardium, both
of which are associated with significant mortality. Local hematoma
formation may compress adjacent vessels and produce ischemic symptoms, and arteriovenous fistulas may develop, occasionally resulting in
high-output heart failure.
Some patients with penetrating chest injuries are hemodynamically
stable at presentation and without symptoms to suggest cardiac injury;
however, as many as 20% of these patients will have occult penetrating
cardiac trauma. As a result, there should always be a high index of suspicion for cardiac injury in any patient with penetrating chest trauma,
irrespective of clinical stability. TTE should be performed in all of these
patients to assess for the presence of pericardial effusion or hematoma.
Occasionally, patients who survive penetrating cardiac injuries may
subsequently present days or weeks later with a new cardiac murmur
or heart failure as a result of mitral or tricuspid regurgitation or an
intracardiac shunt (i.e., ventricular or atrial septal defect, aortopulmonary fistula, or coronary arteriovenous fistula) that was undetected at
the time of the initial injury or developed subsequently (Fig. 272-1).
Therefore, trauma patients should be examined carefully several weeks
after the injury. If a mechanical complication is suspected, it can be
confirmed by echocardiography or cardiac catheterization.
TREATMENT
Penetrating Cardiac Injury
Penetrating cardiac injury associated with hemodynamic instability is a surgical emergency and requires immediate resuscitative measures including endotracheal intubation, establishment of
large-bore intravenous access to facilitate massive volume resuscitation, and immediate thoracotomy to allow for pericardial drainage
and repair of cardiac injuries. Occasionally, cross-clamping of the
2030 PART 6 Disorders of the Cardiovascular System
A B
RV
LV
FIGURE 272-1 Transthoracic echocardiogram demonstrating a traumatic ventricular septal defect. The patient underwent emergent repair of the right ventricle following
a self-inflicted stab wound to the chest. Subsequent two-dimensional imaging (A) revealed a laceration of the interventricular septum (arrow) with color flow Doppler (B)
demonstrating prominent left-to-right shunting across the defect. LV, left ventricle; RV, right ventricle.
descending aorta is required to preferentially perfuse the heart and
brain until hemodynamic stability can be achieved. Hemodynamically stable patients in whom echocardiography reveals even a small
pericardial effusion require urgent surgical exploration to evaluate
for occult cardiac perforation. Pericardiocentesis may be lifesaving
in patients with tamponade but is usually only a temporizing measure while awaiting definitive surgical therapy. In some survivors of
penetrating cardiac injury, the pericardial hemorrhage predisposes
to the development of constriction (Chap. 270), which may require
surgical decortication.
■ FURTHER READING
Crawford T et al: Thoracic trauma, in Sabiston and Spenser Surgery of
the Chest, 9th ed, FW Sellke et al (eds). Philadelphia, Elsevier, 2016,
pp 100–130.
Morse BC et al: Penetrating cardiac injuries: A 36-year perspective at
and urban level 1 trauma center. J Trauma Acute Care Surg 81:623,
2016.
Yousef R, Carr JA: Blunt cardiac trauma: A review of the current
knowledge and management. Ann Thorac Surg 98:1134, 2014.
Wu Y et al: Imaging of cardiac trauma. Radiol Clin N Am 57:795, 2019.
Section 5 Coronary and Peripheral
Vascular Disease
273 Ischemic Heart Disease
Elliott M. Antman, Joseph Loscalzo
Ischemic heart disease (IHD) is a condition in which there is an inadequate supply of blood and oxygen to a portion of the myocardium;
it typically occurs when there is an imbalance between myocardial
oxygen supply and demand. The most common cause of myocardial
ischemia is atherosclerotic disease of an epicardial coronary artery
(or arteries) sufficient to cause a regional reduction in myocardial
blood flow and inadequate perfusion of the myocardium supplied
by the involved coronary artery. This chapter focuses on the chronic
manifestations and treatment of IHD, while the subsequent chapters
address the acute phases of IHD.
■ EPIDEMIOLOGY AND GLOBAL TRENDS
IHD causes more deaths and disability and incurs greater economic
costs than any other illness in the developed world. IHD is the most
common, serious, chronic, life-threatening illness in the United States,
where 20.1 million persons have IHD. Although there is regional
variation, ~3–4% of the population has sustained a myocardial infarction. Genetic factors, a high-fat and energy-rich diet, smoking, and
a sedentary lifestyle are associated with the emergence of IHD. In
the United States and Western Europe, IHD is growing among lowincome groups, but primary prevention has delayed the disease to later
in life across socioeconomic groups. Despite these sobering statistics,
it is worth noting that epidemiologic data show a decline in the rate of
deaths due to IHD, about half of which is attributable to treatments and
half to prevention by risk factor modification.
Obesity, insulin resistance, and type 2 diabetes mellitus are increasing and are powerful risk factors for IHD. These trends are occurring in
the general context of population growth and as a result of the increase
in the average age of the world’s population. With urbanization in
countries with emerging economies and a growing middle class, elements of the energy-rich Western diet are being adopted. As a result,
the prevalence of risk factors for IHD and the prevalence of IHD itself
are both increasing rapidly, so that in analyses of the global burden
of disease, there is a shift from communicable to noncommunicable
diseases, and it is estimated that globally 197.2 million people live with
IHD. Population subgroups that appear to be particularly affected are
men in South Asian countries, especially India and the Middle East.
IHD is a major contributor to the number of disability-adjusted lifeyears (DALYs) experienced globally.
■ PATHOPHYSIOLOGY
Central to an understanding of the pathophysiology of myocardial
ischemia is the concept of myocardial supply and demand. In normal
conditions, for any given level of a demand for oxygen, the myocardium
will control the supply of oxygen-rich blood to prevent underperfusion
of myocytes and the subsequent development of ischemia and infarction. The major determinants of myocardial oxygen demand (MVO2
)
are heart rate, myocardial contractility, and myocardial wall tension
(stress). An adequate supply of oxygen to the myocardium requires a
satisfactory level of oxygen-carrying capacity of the blood (determined
by the inspired level of oxygen, pulmonary function, and hemoglobin
concentration and function) and an adequate level of coronary blood
Ischemic Heart Disease
2031CHAPTER 273
flow. Blood flows through the coronary arteries in a phasic fashion,
with the majority occurring during diastole. About 75% of the total
coronary resistance to flow occurs across three sets of arteries: (1)
large epicardial arteries (Resistance 1 = R1
), (2) prearteriolar vessels
(R2
), and (3) arteriolar and intramyocardial capillary vessels (R3
). In
the absence of significant flow-limiting atherosclerotic obstructions,
R1
is trivial; the major determinant of coronary resistance is found in
R2
and R3 (Fig. 273-1). The normal coronary circulation is dominated
and controlled by the heart’s requirements for oxygen. This need is met
by the ability of the coronary vascular bed to vary its resistance (and,
therefore, blood flow) considerably while the myocardium extracts a
high and relatively fixed percentage of oxygen. Normally, intramyocardial resistance vessels demonstrate a great capacity for dilation (R2
and
R3
decrease). For example, the changing oxygen needs of the heart with
exercise and emotional stress affect coronary vascular resistance and,
in this manner, regulate the supply of oxygen and substrate to the myocardium (metabolic regulation). The coronary resistance vessels also
adapt to physiologic alterations in blood pressure to maintain coronary
blood flow at levels appropriate to myocardial needs (autoregulation).
By reducing the lumen of the coronary arteries, atherosclerosis
limits appropriate increases in perfusion when the demand for more
coronary flow occurs. When the luminal reduction is severe, myocardial perfusion in the basal state is reduced. Coronary blood flow also
can be limited by spasm (see Prinzmetal’s angina in Chap. 274), arterial
thrombi, and, rarely, coronary emboli as well as by ostial narrowing
due to aortitis. Congenital abnormalities such as the origin of the left
anterior descending coronary artery from the pulmonary artery may
cause myocardial ischemia and infarction in infancy, but this cause is
very rare in adults.
Myocardial ischemia also can occur if myocardial oxygen demands
are markedly increased and particularly when coronary blood flow
may be limited, as occurs in severe left ventricular hypertrophy (LVH)
due to aortic stenosis. The latter can present with angina that is indistinguishable from that caused by coronary atherosclerosis largely
owing to subendocardial ischemia (Chap. 261). A reduction in the
oxygen-carrying capacity of the blood, as in extremely severe anemia
or in the presence of carboxyhemoglobin, rarely causes myocardial
ischemia by itself but may lower the threshold for ischemia in patients
with moderate coronary obstruction.
Not infrequently, two or more causes of ischemia coexist in a
patient, such as an increase in oxygen demand due to LVH secondary
Segment
and size
Macrocirculation Microcirculation
Main stimulus
for vasomotion Flow Pressure Metabolites
Transport Regulation Exchange Main
function
Percentage of
total resistance
to flow
Epicardial arteries >400 µm Small arteries <400 µm Arterioles <100 µm Capillaries <10 µm
FIGURE 273-1 Macrocirculation and microcirculation across segments and sizes of the arteries. The location and size of the arteries supplying blood to the heart is shown
at the top. Vasomotion of the arterial segments occurs in response to the stimuli shown. The main function of each of the arterial segments is shown next, followed by a
depiction of the relative resistance to antegrade flow. (Reproduced with permission from B De Bruyne et al: Microvascular (dys)function and clinical outcome in stable
coronary disease. J Amer Coll Cardiol 67:1170, 2016.)
to hypertension and a reduction in oxygen supply secondary to coronary atherosclerosis and anemia. Abnormal constriction or failure
of normal dilation of the coronary resistance vessels also can cause
ischemia. When it causes angina, this condition is referred to as
microvascular angina.
CORONARY ATHEROSCLEROSIS
Epicardial coronary arteries are the major site of atherosclerotic disease. The major risk factors for atherosclerosis (high levels of plasma
low-density lipoprotein [LDL], cigarette smoking, hypertension, and
diabetes mellitus) vary in their relative impact on disturbing the normal functions of the vascular endothelium. These functions include
local control of vascular tone, maintenance of an antithrombotic
surface, and control of inflammatory cell adhesion and diapedesis.
The loss of these defenses leads to inappropriate constriction, luminal
thrombus formation, and abnormal interactions between blood cells,
especially monocytes and platelets, and the activated vascular endothelium. Functional changes in the vascular milieu ultimately result in
the subintimal collections of fat, smooth muscle cells, fibroblasts, and
intercellular matrix that define the atherosclerotic plaque. Rather than
viewing atherosclerosis strictly as a vascular problem, it is useful to
consider it in the context of alterations in the nature of the circulating
blood (hyperglycemia; increased concentrations of LDL cholesterol,
tissue factor, fibrinogen, von Willebrand factor, coagulation factor VII,
and platelet microparticles). The combination of a “vulnerable vessel”
in a patient with “vulnerable blood” promotes a state of hypercoagulability and hypofibrinolysis. This is especially true in patients with
diabetes mellitus.
Atherosclerosis develops at irregular rates in different segments of
the epicardial coronary tree and leads eventually to segmental reductions in cross-sectional area, i.e., plaque formation. There is also a
predilection for atherosclerotic plaques to develop at sites of increased
turbulence in coronary flow, such as at branch points in the epicardial
arteries. When a stenosis reduces the diameter of an epicardial artery
by 50%, there is a limitation of the ability to increase flow to meet
increased myocardial demand. When the diameter is reduced by ~80%,
blood flow at rest may be reduced, and further minor decreases in the
stenotic orifice area can reduce coronary flow dramatically to cause
myocardial ischemia at rest or with minimal stress.
Segmental atherosclerotic narrowing of epicardial coronary arteries is caused most commonly by the formation of a plaque, which is
2032 PART 6 Disorders of the Cardiovascular System
subject to rupture or erosion of the cap separating the plaque from
the bloodstream. Upon exposure of the plaque contents to blood, two
important and interrelated processes are set in motion: (1) platelets
are activated and aggregate, and (2) the coagulation cascade is activated, leading to deposition of fibrin strands. A thrombus composed
of platelet aggregates and fibrin strands traps red blood cells and can
reduce coronary blood flow, leading to the clinical manifestations of
myocardial ischemia.
The location of the obstruction influences the quantity of myocardium rendered ischemic and determines the severity of the clinical
manifestations. Thus, critical obstructions in vessels, such as the
left main coronary artery and the proximal left anterior descending
coronary artery, are particularly hazardous. Chronic severe coronary
narrowing and myocardial ischemia frequently are accompanied by the
development of collateral vessels, especially when the narrowing develops gradually. When well developed, such vessels can by themselves
provide sufficient blood flow to sustain the viability of the myocardium
at rest but not during conditions of increased demand.
With progressive worsening of a stenosis in a proximal epicardial
artery, the distal resistance vessels (when they function normally)
dilate to reduce vascular resistance and maintain coronary blood
flow. A pressure gradient develops across the proximal stenosis, and
poststenotic pressure falls. When the resistance vessels are maximally
dilated, myocardial blood flow becomes dependent on the pressure in
the coronary artery distal to the obstruction. In these circumstances,
ischemia, manifest clinically by angina or electrocardiographically by
ST-segment deviation, can be precipitated by increases in myocardial
oxygen demand caused by physical activity, emotional stress, and/or
tachycardia. Changes in the caliber of the stenosed coronary artery
resulting from physiologic vasomotion, loss of endothelial control of
dilation (as occurs in atherosclerosis), pathologic spasm (Prinzmetal’s
angina), or small platelet-rich plugs also can upset the critical balance
between oxygen supply and demand and thereby precipitate myocardial ischemia.
■ EFFECTS OF ISCHEMIA
During episodes of inadequate perfusion caused by coronary atherosclerosis, myocardial tissue oxygen tension falls and may cause
transient disturbances of the mechanical, biochemical, and electrical
functions of the myocardium (Fig. 273-2). Coronary atherosclerosis is
a focal process that usually causes nonuniform ischemia. During ischemia, regional disturbances of ventricular contractility cause segmental
hypokinesia, akinesia, or, in severe cases, bulging (dyskinesia), which
can reduce myocardial pump function.
The abrupt development of severe ischemia, as occurs with total or
subtotal coronary occlusion, is associated with near instantaneous failure of normal muscle relaxation and then diminished contraction. The
relatively poor perfusion of the subendocardium causes more intense
ischemia of this portion of the wall (compared with the subepicardial
region). Ischemia of large portions of the ventricle causes transient
left ventricular (LV) failure, and if the papillary muscle apparatus is
involved, mitral regurgitation can occur. When ischemia is transient,
it may be associated with angina pectoris; when it is prolonged, it can
lead to myocardial necrosis and scarring with or without the clinical
picture of acute myocardial infarction (Chap. 275).
A wide range of abnormalities in cell metabolism, function, and
structure underlie these mechanical disturbances during ischemia.
The normal myocardium metabolizes fatty acids and glucose to carbon
dioxide and water. With severe oxygen deprivation, fatty acids cannot
be oxidized, and glucose is converted to lactate; intracellular pH is
reduced, as are the myocardial stores of high-energy phosphates, i.e.,
ATP and creatine phosphate. Impaired cell membrane function leads
to the leakage of potassium and the uptake of sodium by myocytes as
well as an increase in cytosolic calcium. The severity and duration of
the imbalance between myocardial oxygen supply and demand determine whether the damage is reversible (≤20 min for total occlusion in
the absence of collaterals) or permanent, with subsequent myocardial
necrosis (>20 min).
Ischemia also causes characteristic changes in the electrocardiogram
(ECG) such as repolarization abnormalities, as evidenced by inversion
of T waves and, when more severe, displacement of ST segments (Chap.
240). Transient T-wave inversion probably reflects nontransmural,
intramyocardial ischemia; transient ST-segment depression often
reflects patchy subendocardial ischemia; and ST-segment elevation is
thought to be caused by more severe transmural ischemia. Another
important consequence of myocardial ischemia is electrical instability,
which may lead to isolated ventricular premature beats or even ventricular tachycardia or ventricular fibrillation (Chaps. 254 and 255). Most
patients who die suddenly from IHD do so as a result of ischemiainduced ventricular tachyarrhythmias (Chap. 306).
■ ASYMPTOMATIC VERSUS SYMPTOMATIC IHD
Although the prevalence is decreasing, postmortem studies of accident victims and military casualties in Western countries show that
Systolic dysfunction
Regional wall motion
Decreased segmental perfusion
Diastolic dysfunction
Micro-infarction/myocardial fibrosis
Altered metabolism/abnormal ST segment
Decreased subendocardial perfusion
Endothelial and microvascular dysfunction
Exposure time of mismatch in myocardial oxygen supply/demand
Near term
Repetitive/progressive manifestations of ischemia
Prolonged
FIGURE 273-2 Cascade of mechanisms and manifestations of ischemia. (Reproduced with permission from LJ Shaw et al: Women and ischemic heart disease: Evolving
knowledge. J Am Coll Cardiol 54:1561, 2009.)
Ischemic Heart Disease
2033CHAPTER 273
coronary atherosclerosis can begin before age 20 and is present among
adults who were asymptomatic during life. Exercise stress tests in
asymptomatic persons may show evidence of silent myocardial ischemia, i.e., exercise-induced ECG changes not accompanied by angina
pectoris; coronary angiographic studies of such persons may reveal
coronary artery plaques and previously unrecognized obstructions
(Chap. 242). Coronary artery calcifications (CACs) may be seen on CT
images of the heart, can be quantified in a CAC score, and may be used
as adjunctive information to support a diagnosis of IHD. However,
they should not be used as the primary screening modality or as the
isolated basis on which to formulate therapeutic decisions. (See further
discussion below.) Postmortem examination of patients with such
obstructions without a history of clinical manifestations of myocardial
ischemia often shows macroscopic scars secondary to myocardial
infarction in regions supplied by diseased coronary arteries, with or
without collateral circulation. According to population studies, ~25%
of patients who survive acute myocardial infarction may not come to
medical attention, and these patients have the same adverse prognosis
as do those who present with the classic clinical picture of acute myocardial infarction (Chap. 275). Sudden death may be unheralded and is
a common presenting manifestation of IHD (Chap. 306).
Patients with IHD also can present with cardiomegaly and heart
failure secondary to ischemic damage of the LV myocardium that may
have caused no symptoms before the development of heart failure; this
condition is referred to as ischemic cardiomyopathy. In contrast to the
asymptomatic phase of IHD, the symptomatic phase is characterized
by chest discomfort due to either angina pectoris or acute myocardial
infarction (Chap. 275). Having entered the symptomatic phase, the
patient may exhibit a stable or progressive course, revert to the asymptomatic stage, or die suddenly.
STABLE ANGINA PECTORIS
This episodic clinical syndrome is a result of transient myocardial
ischemia. Various diseases that cause myocardial ischemia and the
numerous forms of discomfort with which it may be confused are discussed in Chap. 14. Males constitute ~70% of all patients with angina
pectoris and an even greater proportion of those aged <50 years. It
is, however, important to note that angina pectoris in women may be
atypical in presentation (see below).
■ HISTORY
The typical patient with angina is a man >50 years or a woman
>60 years of age who complains of episodes of chest discomfort, usually
described as heaviness, pressure, squeezing, smothering, or choking
and only rarely as frank pain. When the patient is asked to localize the
sensation, he or she typically places a hand over the sternum, sometimes with a clenched fist, to indicate a squeezing, central, substernal
discomfort (Levine’s sign). Angina is usually crescendo-decrescendo
in nature (typically with the severity of the discomfort not at its most
intense level at the outset of symptoms), typically lasts 2–5 min, and
can radiate to either shoulder and to both arms (especially the ulnar
aspects of the forearm and hand). It also can arise in or radiate to the
back, interscapular region, root of the neck, jaw, teeth, and epigastrium.
Angina is rarely localized below the umbilicus or above the mandible.
A useful finding in assessing a patient with chest discomfort is the fact
that myocardial ischemic discomfort does not radiate to the trapezius
muscles; that radiation pattern is more typical of pericarditis.
Although episodes of angina typically are caused by exertion (e.g.,
exercise, hurrying, or sexual activity) or emotion (e.g., stress, anger,
fright, or frustration) and are relieved by rest, they also may occur at
rest (Chap. 274) and while the patient is recumbent (angina decubitus).
The patient may be awakened at night by typical chest discomfort
and dyspnea. Nocturnal angina may be due to episodic tachycardia,
diminished oxygenation as the respiratory pattern changes during
sleep, or expansion of the intrathoracic blood volume that occurs with
recumbency; the latter causes an increase in cardiac size (end-diastolic
volume), wall tension, and myocardial oxygen demand that can lead to
ischemia and transient LV failure.
The threshold for the development of angina pectoris may vary by
time of day and emotional state. Many patients report a fixed threshold
for angina, occurring predictably at a certain level of activity, such as
climbing two flights of stairs at a normal pace. In these patients, coronary stenosis and myocardial oxygen supply are fixed, and ischemia
is precipitated by an increase in myocardial oxygen demand; they are
said to have stable exertional angina. In other patients, the threshold
for angina may vary considerably within any particular day and from
day to day. In such patients, variations in myocardial oxygen supply,
most likely due to changes in coronary vasomotor tone, may play an
important role in defining the pattern of angina. A patient may report
symptoms upon minor exertion in the morning yet by midday be
capable of much greater effort without symptoms. Angina may also be
precipitated by unfamiliar circumstances, a heavy meal, exposure to
cold, or a combination of these factors.
Exertional angina typically is relieved in 1–5 min by slowing or ceasing activities and even more rapidly by rest and sublingual nitroglycerin (see below). Indeed, the diagnosis of angina should be suspect if it
does not respond to the combination of these measures. The severity of
angina can be conveniently summarized by the Canadian Cardiac Society functional classification (Table 273-1). Its impact on the patient’s
functional capacity can be described by using the New York Heart
Association functional classification (Table 273-1).
Sharp, fleeting chest pain or a prolonged, dull ache localized to the
left submammary area is rarely due to myocardial ischemia. However,
especially in women and diabetic patients, angina pectoris may be
atypical in location and not strictly related to provoking factors. In
addition, this symptom may exacerbate and remit over days, weeks, or
months. Its occurrence can be seasonal, occurring more frequently in
the winter in temperate climates. Anginal “equivalents” are symptoms
of myocardial ischemia other than angina. They include dyspnea,
TABLE 273-1 Cardiovascular Disease Classification Chart
CLASS
NEW YORK HEART
ASSOCIATION FUNCTIONAL
CLASSIFICATION
CANADIAN CARDIOVASCULAR
SOCIETY FUNCTIONAL
CLASSIFICATION
I Patients have cardiac disease
but without the resulting
limitations of physical activity.
Ordinary physical activity
does not cause undue fatigue,
palpitation, dyspnea, or anginal
pain.
Ordinary physical activity, such
as walking and climbing stairs,
does not cause angina. Angina
present with strenuous or rapid
or prolonged exertion at work or
recreation.
II Patients have cardiac disease
resulting in slight limitation
of physical activity. They are
comfortable at rest. Ordinary
physical activity results in
fatigue, palpitation, dyspnea, or
anginal pain.
Slight limitation of ordinary
activity. Walking or climbing stairs
rapidly, walking uphill, walking
or stair climbing after meals, in
cold, or when under emotional
stress or only during the few
hours after awakening. Walking
more than two blocks on the level
and climbing more than one flight
of stairs at a normal pace and in
normal conditions.
III Patients have cardiac disease
resulting in marked limitation
of physical activity. They are
comfortable at rest. Less than
ordinary physical activity
causes fatigue, palpitation,
dyspnea, or anginal pain.
Marked limitation of ordinary
physical activity. Walking one
to two blocks on the level and
climbing one flight of stairs at
normal pace.
IV Patients have cardiac disease
resulting in inability to carry on
any physical activity without
discomfort. Symptoms of
cardiac insufficiency or of
the anginal syndrome may be
present even at rest. If any
physical activity is undertaken,
discomfort is increased.
Inability to carry on any physical
activity without discomfort—
anginal syndrome may be present
at rest.
Source: Reproduced with permission from L Goldman et al: Comparative
reproducibility and validity of systems for assessing cardiovascular functional
class: Advantages of a new specific activity scale. Circulation 64:1227, 1981.
2034 PART 6 Disorders of the Cardiovascular System
nausea, fatigue, and faintness and are more common in the elderly and
in diabetic patients.
Systematic questioning of a patient with suspected IHD is important to uncover the features of an unstable syndrome associated with
increased risk, such as angina occurring with less exertion than in the
past, occurring at rest, or awakening the patient from sleep. Since coronary atherosclerosis often is accompanied by similar lesions in other
arteries, a patient with angina should be questioned and examined for
peripheral arterial disease (intermittent claudication [Chap. 281]),
stroke, or transient ischemic attacks (Chap. 426). It is also important
to uncover a family history of premature IHD (<55 years in first-degree
male relatives and <65 in female relatives) and the presence of diabetes
mellitus, hyperlipidemia, hypertension, cigarette smoking, and other
risk factors for coronary atherosclerosis.
The history of typical angina pectoris establishes the diagnosis of
IHD until proven otherwise. Given the importance of the history,
clinicians should move beyond unstructured interviews with the
patient and consider using a validated questionnaire (e.g., Seattle
Angina Questionnaire) to establish the presence and severity of IHD.
The coexistence of advanced age, male sex, the postmenopausal state,
and risk factors for atherosclerosis increases the likelihood of hemodynamically significant coronary disease. A particularly challenging
problem is the evaluation and management of patients with persistent
ischemic-type chest discomfort but no flow-limiting obstructions in
their epicardial coronary arteries. This situation arises more often in
women than in men. Potential etiologies include microvascular coronary disease (detectable on coronary reactivity testing in response
to vasoactive agents such as intracoronary adenosine, acetylcholine,
and nitroglycerin) and abnormal cardiac nociception. Treatment of
microvascular coronary disease should focus on efforts to improve
endothelial function, including nitrates, beta blockers, calcium antagonists, statins, and angiotensin-converting enzyme (ACE) inhibitors.
Abnormal cardiac nociception is more difficult to manage and may be
ameliorated in some cases by imipramine.
■ PHYSICAL EXAMINATION
The physical examination is often normal in patients with stable
angina when they are asymptomatic. However, because of the increased
likelihood of IHD in patients with diabetes and/or peripheral arterial
disease, clinicians should search for evidence of atherosclerotic disease
at other sites, such as an abdominal aortic aneurysm, carotid arterial
bruits, and diminished arterial pulses in the lower extremities. The
physical examination also should include a search for evidence of risk
factors for atherosclerosis such as xanthelasmas and xanthomas. Evidence for peripheral arterial disease should be sought by evaluating the
pulse contour at multiple locations and comparing the blood pressure
between the arms and between the arms and the legs (ankle-brachial
index). Examination of the fundi may reveal an increased light reflex
and arteriovenous nicking as evidence of hypertension. There also may
be signs of anemia, thyroid disease, and nicotine stains on the fingertips from cigarette smoking.
Palpation may reveal cardiac enlargement and abnormal contraction of the cardiac impulse (LV dyskinesia). Auscultation can uncover
arterial bruits, a third and/or fourth heart sound, and, if acute ischemia or previous infarction has impaired papillary muscle function, an
apical systolic murmur due to mitral regurgitation. These auscultatory
signs are best appreciated with the patient in the left lateral decubitus
position. Aortic stenosis, aortic regurgitation (Chap. 261), pulmonary
hypertension (Chap. 283), and hypertrophic cardiomyopathy (Chap.
259) must be excluded, since these disorders may cause angina in the
absence of coronary atherosclerosis. Examination during an anginal
attack is useful, since ischemia can cause transient LV failure with
the appearance of a third and/or fourth heart sound, a dyskinetic
cardiac apex, mitral regurgitation, and even pulmonary edema. Tenderness of the chest wall, localization of the discomfort with a single
fingertip on the chest, or reproduction of the pain with palpation of the
chest makes it unlikely that the pain is caused by myocardial ischemia.
A protuberant abdomen may indicate that the patient has the metabolic syndrome and is at increased risk for atherosclerosis.
■ LABORATORY EXAMINATION
Although the diagnosis of IHD can be made with a high degree of
confidence from the history and physical examination, a number of
simple laboratory tests can be helpful. The urine should be examined for evidence of diabetes mellitus and renal disease (including
microalbuminuria) since these conditions accelerate atherosclerosis.
Similarly, examination of the blood should include measurements of
lipids (cholesterol—total, LDL, high-density lipoprotein [HDL]—and
triglycerides), glucose (hemoglobin A1C), creatinine, hematocrit, and, if
indicated based on the physical examination, thyroid function. A chest
x-ray may be helpful in demonstrating the consequences of IHD, i.e.,
cardiac enlargement, ventricular aneurysm, or signs of heart failure.
These signs can support the diagnosis of IHD and are important in
assessing the degree of cardiac damage. Evidence exists that an elevated
level of high-sensitivity C-reactive protein (CRP) (specifically, between
1 and 3 mg/L) is an independent risk factor for IHD and may be useful
in therapeutic decision-making about the initiation of hypolipidemic
treatment. The major benefit of high-sensitivity CRP is in reclassifying
the risk of IHD in patients in the “intermediate” risk category on the
basis of traditional risk factors.
■ ELECTROCARDIOGRAM
A 12-lead ECG recorded at rest may be normal in patients with typical angina pectoris, but there may also be signs of an old myocardial
infarction (Chap. 240). Although repolarization abnormalities, i.e.,
ST-segment and T-wave changes, as well as LVH and disturbances of
cardiac rhythm or intraventricular conduction, are suggestive of IHD,
they are nonspecific, since they also can occur in pericardial, myocardial, and valvular heart disease or, in the case of the former, transiently
with anxiety, changes in posture, drugs, or esophageal disease. The
presence of LVH is a significant indication of increased risk of adverse
outcomes from IHD. Of note, even though LVH and cardiac rhythm
disturbances are nonspecific indicators of the development of IHD,
they may be contributing factors to episodes of angina in patients
in whom IHD has developed as a consequence of conventional risk
factors. Dynamic ST-segment and T-wave changes that accompany
episodes of angina pectoris and disappear thereafter are more specific.
■ STRESS TESTING
Electrocardiographic The most widely used test for both the
diagnosis of IHD and the estimation of risk and prognosis involves
recording of the 12-lead ECG before, during, and after exercise, usually
on a treadmill (Fig. 273-3). The test consists of a standardized incremental increase in external workload (Table 273-2) while symptoms,
the ECG, and arm blood pressure are monitored. Exercise duration is
usually symptom-limited, and the test is discontinued upon evidence of
chest discomfort, severe shortness of breath, dizziness, severe fatigue,
ST-segment depression >0.2 mV (2 mm), a fall in systolic blood pressure >10 mmHg, or the development of a ventricular tachyarrhythmia.
This test is used to discover any limitation in exercise performance,
detect typical ECG signs of myocardial ischemia, and establish their
relationship to chest discomfort. The ischemic ST-segment response
generally is defined as flat or downsloping depression of the ST
segment >0.1 mV below baseline (i.e., the PR segment) and lasting
longer than 0.08 s (Fig. 273-2). Upsloping or junctional ST-segment
changes are not considered characteristic of ischemia and do not
constitute a positive test. Although T-wave abnormalities, conduction
disturbances, and ventricular arrhythmias that develop during exercise
should be noted, they are also not diagnostic. Negative exercise tests in
which the target heart rate (85% of maximal predicted heart rate for age
and sex) is not achieved are considered nondiagnostic.
In interpreting ECG stress tests, the probability that coronary
artery disease (CAD) exists in the patient or population under study
(i.e., pretest probability) should be considered. A positive result on
exercise indicates that the likelihood of CAD is 98% in males who are
>50 years with a history of typical angina pectoris and who develop
chest discomfort during the test. The likelihood decreases if the patient
has atypical or no chest pain by history and/or during the test.
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