The murmur of VSD depends on a pressure gradient between the right and left ventricles. Pulmonary artery pressure at systemic levels in utero declines over the first few weeks of life, with thinning of the muscular wall of the smaller pulmonary arterioles. When right ventricular pressures drop below left-sided pressures, left-to-right shunting occurs across the septal defect, creating the characteristic holosystolic murmur. The appearance of a VSD murmur depends on the rapidity of this vascular maturation process.

During the perinatal period, the size of the communication, coexisting right ventricular outflow obstruction, or persistence of fetal-type cardiopulmonary circulation may mute audibility of the VSD. The clinical course of most VSDs, particularly those located in the muscular segment of the interventricular septum, is often benign. As the duration and intensity of the systolic murmur decrease on serial follow-up, uncomplicated spontaneous closure of the VSD usually follows.

Infrequently, spontaneous closure of a VSD may lead to undesirable changes in intracardiac anatomy or pulmonary physiology. Closure of VSDs, particularly those in the subaortic membranous septum, normally is accomplished with fibrous thickening of the defect’s border or adjacent septal tricuspid valve leaflet and formation of a windsock-like aneurysm on the right septal surface. Undesirable herniation of an aortic cusp into the septal defect, however, may initiate closure. In this sequence, the aortic cusp seals the communication, but secondary distortion of the valve results in aortic regurgitation.

Another variation in the natural history of the relatively small membranous VSD is the spontaneous development of anomalous muscle bundles in the right ventricle. As the VSD spontaneously decreases in size, muscle bundles within the body of the right ventricle hypertrophy, partitioning the chamber into higher and lower pressure segments. The softer systolic murmur of the closing VSD becomes obscured by a harsh ejection murmur. This murmur results from the intraventricular pressure gradient that the anomalous muscle
bundles generate. While the left-to-right shunt is not a hemodynamic burden, surgical intervention in the toddler or younger child may be necessary to resect the obstructing anomalous muscle bundles.

Undesirable changes in pulmonary vascular physiology may simulate spontaneous closure of a VSD. While timely surgical intervention during infancy has reduced the frequency of this clinical problem, certain patients experience accelerated maladaptive changes in the pulmonary arterioles in response to increased pulmonary blood flow due to moderate or large VSDs. The media of the arterioles thicken, increasing pulmonary artery pressure and pulmonary vascular resistance. In addition, this thickening reduces left-to-right shunting across the VSD. The pansystolic VSD murmur recedes as right and left ventricular pressures equilibrate, and the left-to-right intracardiac shunt is minimized. Subsequent physical examination reveals no systolic or diastolic murmur. The second heart sound (S₂) increases in intensity, and a palpable right ventricular impulse is apparent.

In neonates with trisomy 21, a complete common atrioventricular (AV) canal defect (unrestrictive atrial septal defect [ASD], VSD, mitral and tricuspid valve anomalies) may be clinically silent during their physical examination. The pansystolic murmur, which results from left-to-right shunting, is blunted until pulmonary vascular maturation reduces pulmonary vascular resistance and right ventricular pressure. Therefore, newborns with Down syndrome require more than just a careful physical examination. Screening for an AV canal, also known as an endocardial cushion defect, begins with the standard 12-lead electrocardiogram (ECG). In most cases, the neonatal ECG is too nonspecific to identify cardiovascular anomalies; however, the superior QRS axis and counterclockwise depolarization loop associated with an AV canal is characteristic for this anomaly. As with other cardiovascular anomalies whose clinical expression depends on maturation of pulmonary circulation, exclusion of an AV canal anomaly or more complex interventricular septal communications warrants cardiac ultrasound examination.

Although listening for a murmur is a common focus of the practitioner’s assessment when screening for newborn cardiovascular anomalies, TOF illustrates how variable such findings may be. The anomalies in TOF consist of a large malalignment-type VSD; an aortic valve overriding the interventricular septum; obstruction of the pulmonary circulation below, at, or above the pulmonary valve; and right ventricular hypertrophy. Although a large VSD is part of the complex, it does not typically contribute to the auscultatory findings in an affected neonate. The systolic ejection murmur at the left upper sternal border associated with TOF is secondary to the obstruction and attendant pressure gradient across the right ventricular outflow tract.

Variations in the auscultatory findings in TOF reflect the dynamic and static nature of the right ventricular outflow tract obstruction. Patients vary in the degree of fixed obstruction across the hypertrophied, right ventricular outflow, stenotic pulmonary valve, and bifurcation of the branch pulmonary arteries. Obstruction at or below the valve is manifested by a systolic ejection murmur at the left upper sternal border. Distal branch pulmonary artery stenosis radiates this ejection murmur to the axillae and posterior lung fields. An individual patient’s physical examination may vary over time as progressive hypertrophy of the right ventricular outflow increases subvalvar obstruction. Auscultatory findings also may suddenly change with superimposition of reactive dynamic obstruction and virtual occlusion of the right ventricular outflow.

The VSD associated with TOF is a lesion that is seen rather than heard. The typically large defect equalizes both right and left ventricular systolic pressure, and accordingly, no shunt murmur is audible. The defect decompresses the obstructed right ventricle by shunting desaturated blood into the left ventricle and the systemic circulation.

There is considerable anatomic variation with TOF. While many affected patients present with a systolic ejection murmur and cyanosis, some are clinically acyanotic. In such cases, a fortuitous physiologic balance exists between the large VSD and the degree of right ventricular outflow obstruction. The potential for excessive pulmonary blood flow with left-to-right shunting across a large VSD is moderated by right ventricular outflow tract obstruction. These infants may have an uneventful course until elective surgical intervention is performed to close the VSD and relieve the outflow obstruction. Until surgical correction is performed, however, these children remain at risk for hypercyanotic episodes due to acute increase in dynamic obstruction of the right ventricular outflow.

One of the most clinically challenging variations of TOF is the neonate who also has atresia of the pulmonary valve. This infant may be minimally cyanotic at birth as a result of persistent shunting across the patent ductus arteriosus (PDA) or the presence of systemic-to-pulmonary artery collaterals that preserve pulmonary blood flow.

When pulmonary blood flow is totally ductal dependent, the infant may become rapidly and profoundly cyanotic with spontaneous closure of the ductus arteriosus. These infants require emergency intervention with initiation of prostaglandin E-1 therapy and surgical placement of a systemic-to-pulmonary artery shunt.

Those infants with TOF and pulmonary atresia whose pulmonary blood flow depends on multiple systemic-to-pulmonary artery collaterals may not present clinically for several weeks following discharge home. These infants often have complex pulmonary artery anatomy, with marked hypoplasia or even absent branch segments.

In utero, the ductus arteriosus effectively bypasses anomalies of the great vessels (Fig. 37-1), AV and semilunar valves, and hypoplasia of the ventricles. Congenital cardiovascular anomalies of the left heart that are well palliated in the fetus and newborn by the PDA and placental circulation may present acutely and precipitously in the newborn period following spontaneous closure of the ductus arteriosus. Following birth, patency of the ductus arteriosus can transiently preserve systemic or pulmonary circulation. In neonates with critical aortic stenosis or coarctation of the aorta, closure of the ductus in the first 48 to 96 hours of life is followed by progressive metabolic acidosis and myocardial dysfunction. The challenge is to identify affected infants before clinical deterioration alters the opportunity for successful surgical management.

Meeting the challenge of early diagnosis of ductal-dependent cardiovascular anomalies requires more than a clinician’s high index of suspicion. The neonate with clinically occult coarctation of the juxtaductal aorta is an example of how a large PDA can obscure clinical acumen (Fig. 37-2). Right-to-left shunting across a neonate’s unrestrictive PDA provides effective systemic
blood flow distal to the severest of aortic arch anomalies. Femoral pulses are preserved, and the discrepancy in saturation between the upper and lower extremities may not be clinically apparent. Subtle respiratory changes due to progressive left ventricular failure may not be appreciated until spontaneous closure of the PDA compromises peripheral perfusion. Metabolic acidosis then results. A similar clinical pattern occurs with hypoplasia of the left heart where right-to-left shunting across the ductus arteriosus is necessary to palliate aortic or mitral atresia (see Fig. 37-2).

Identification of congenital cardiovascular anomalies when patency of the PDA preserves systemic or pulmonary (Fig. 37-3) blood flow is a challenge for the pediatric clinician. It is critical to identify ductal-dependent lesions so that prostaglandin E-1 therapy can be initiated to keep the ductus arteriosus patent and preserve pulmonary or systemic blood flow.

The infant’s subsequent presentation following spontaneous closure of the PDA is heralded by either significant cyanosis or, in the case of left-sided obstruction, profound metabolic acidosis and shock. Fetal echocardiography allows antenatal diagnosis of most ductal-dependent anomalies. However, cost and availability limit its application as a universal screening procedure.

The physical examination of the normal infant, toddler, and young child is often punctuated by the discovery of “functional” murmurs. They are ejection type and have a vibratory or musical quality.

These murmurs are always systolic; diastolic murmurs are never innocent. In the majority of toddlers and young children, the left upper/midsternal border “innocent” or vibratory systolic ejection murmur is evidence of accelerated blood flow across the right ventricular outflow tract or central systemic veins. The truncated shape of the right ventricle due to continuity of its capacious tricuspid valve annulus and body with a conical shaped tapering outflow accelerates blood flow. The change in velocity of blood flow through the normal right ventricle is similar to that of water in a stream whose channel narrows. The sound of water accelerating as the stream’s banks converge parallels the functional murmur, audible at the left upper sternal border of the heart, as blood accelerates across the normal right ventricular outflow tract.

If the volume of blood returning to the right heart is increased, either by febrile illness, anemia, or posture, the intensity of the murmur increases much as the sound of the stream does with runoff following a rainfall. This explains the frequent discovery of a “new” or “never heard before” murmur during the evaluation of a routine febrile illness.

While murmurs secondary to structural cardiovascular anomalies can be influenced by changes in systemic venous return to the heart, simple postural changes usually have a minimal effect on the intensity of organic murmurs.

Postural changes in intensity help identify most murmurs of “functional origin.” Interpretation of the response to such maneuvers, however, may be confusing. While upright posture decreases venous return from the inferior vena cava, it accelerates superior vena cava as well as innominate, subclavian, and internal jugular venous blood flow. This acceleration in blood flow often results in a continuous, infraclavicular venous hum that may simulate a PDA in the toddler or young child. Discriminating the continuous murmur of the venous hum from that of a PDA is straightforward. The venous hum continuous murmur is exquisitely sensitive to maneuvers reducing superior venous blood flow velocity. The transition from upright to supine posture, contralateral rotation of the head, or gentle supraclavicular compression eliminates the venous hum murmur but does not influence the continuous murmur of the PDA.

Being able to identify variability or physiologic splitting of S2 is often a challenge, especially in younger children. Concentrating on that particular phase of the cardiac cycle requires patience. In older cooperative children, asking for deep breathing in and out and holding the breath may make variable splitting more apparent.

Hearing variability in the splitting of S2 commonly differentiates between the ejection-type flow murmur of an innocent murmur, an ASD, and those murmurs caused by right sided outflow tract obstruction. All of these murmurs sound the same in that they are typical ejection type murmurs; S2 splitting differentiates between the three. Innocent murmurs have variable splitting.

The murmur of an ASD is caused by relative pulmonic stenosis. This is due to increased blood volume across a normal pulmonic valve due to inter-atrial left-to-right shunting, and it sounds like a typical pulmonic ejection-type murmur (the sound of the murmur is not caused by flow across the ASD). Because of the increased flow, closure of the pulmonic valve lags behind aortic valve closure, resulting in a fixed and widely (nonvariable) split S2. With the murmur of pulmonic stenosis, it is typically difficult to identify any normal splitting of S2.

Antecedent viral illness is commonplace during the winter and spring months. Temporal relationship to symptoms help pinpoint the prodrome, which precedes pericardial or pleural disease. Marfan syndrome in first- or second-degree relatives of a phenotypically suggestive, tall adolescent presenting with a spontaneous pneumothorax should direct the clinician’s attention to connective tissue disease, especially when scoliosis, pectus excavatum, or abdominal wall hernias have been treated or noted in the past. Such patients may present with acute chest pain radiating to the neck or back secondary to spontaneous injury of an aortic aneurysm (Groenink et al., 1999). Past medical history of Kawasaki syndrome or an atypical febrile illness associated with a perineal rash, edema of the hands and feet, or mucoconjunctivitis warrants investigation of coronary artery anatomy. A history of intractable colic and poor weight gain in the young infant may be the only manifestation of abnormal coronary artery (anomalous origin of the left coronary artery from the pulmonary circulation). The child or adolescent reporting a tapping sensation in the chest or vague chest discomfort with irregular heartbeats may be experiencing tachyarrhythmias related to atrial or ventricular ectopy.

Discrimination between benign functional and organic chest pain can often be accomplished with review of the symptoms’ duration, location and quality of the discomfort, and circumstances provoking the complaint.

Patients with benign, fleeting chest discomfort of musculoskeletal or transient gastrointestinal etiology find it difficult to be precise about the onset of symptoms that are fleeting in quality and rarely interrupt their activity. In contrast, those with organic chest pain can often pinpoint the onset of symptoms and are emphatic about its chronicity.

The timelines of chest pain in the pediatric population vary according to etiology. Pain due to self-limiting musculoskeletal or gastrointestinal etiologies is fleeting, lasting only seconds. A spontaneous pneumothorax results in acute penetrating pain that wanes. Myocardial ischemia results in minutes of provocable anginal discomfort. Pleuropericardial inflammation and costochondritis result in an incessant ache.