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Patent ductus arteriosus and aortopulmonary window


Historical Notes

In 1593 Giambattista Carcano, Professor of Anatomy in Pavia, an ancient town in northern Italy, described the ductus arteriosus in his book on the great cardiac vessels of the fetus. However, Leo Bottali came to be associated with the arterial duct—the duktus arteriosus persistens —even though he misapplied the term to the foramen ovale. It was not until Karl von Rokitansky’s handbook of 1844 and his beautifully illustrated monograph of 1852 that patent ductus arteriosus was recognized as a specific congenital malformation.

Patent ductus arteriosus

The first section of this chapter is concerned with persistent patency of the ductus arteriosus. The second section is devoted to aortopulmonary window, often called aortopulmonary or aorticopulmonary septal defect, an anomaly that is embryologically unrelated to patent ductus but is physiologically and clinically similar.

Anatomical considerations

The incidence of isolated persistent patency of the ductus has been estimated at 1:2000 to 1:5000 births, or about 10% to 12% of all varieties of congenital heart disease. The pulmonary orifice of the ductus is located immediately to the left of the bifurcation of the pulmonary trunk near the origin of its left branch ( Figs. 17.1 and 17.2 ; ). The aortic orifice is located immediately distal to the origin of the left subclavian artery ( Figs. 17.1–17.3 ). A patent ductus can be long and narrow or short and wide, with all gradations in between ( Figs. 17.3–17.5 ; ). Closure consistently begins at the pulmonary arterial end, so the ductus assumes the shape of a truncated cone that is larger at its aortic end (see Figs. 17.3 , 17.4 , and 17.6 ). , A widely patent aortic end with a sealed pulmonary end is the substrate for a ductal aneurysm (see Figs. 17.6 and 17.7 ). Patency confined to the pulmonary end is exceptional. Anatomical variations include bilateral patent ductus, , left-sided patent ductus with right aortic arch, right-sided patent ductus with right aortic arch, patent ductus or ligamentum arteriosum as a component of a vascular ring ( Fig. 17.8 ), and dissection of the aorta with extension into a patent ductus.

Fig. 17.1, Illustrations of patent ductus arteriosus (PDA) and aortopulmonary window (APW). (A) The aortic orifice of a PDA inserts immediately distal to the origin of the left subclavian artery. Ao , Aorta. The pulmonary orifice inserts immediately to the left of the bifurcation of the pulmonary trunk (PT). (B) An APW is a communication between adjacent walls of the ascending aorta and the PT proximal to its bifurcation. Lig Art, Ligamentum arteriosum.

Fig. 17.4, (A) Lateral angiogram from a 16-year-old girl. A catheter passed from the pulmonary trunk (PT) through a ductus arteriosus (arrow), which is distinctly larger at its aortic end. AO , Aortic arch; DA, descending aorta. (B) Lateral angiogram from an 8-year-old male with a restrictive tubular ductus arteriosus (arrow) that fills from the aorta (AO) and tapers markedly at its pulmonary end.

Fig. 17.6, (A) Computed tomography (CT) angiogram, sagittal view, of a 51-year-old with a conical (type A) PDA that appears large at the aortic end (Ao) but then narrows as it enters the pulmonary artery (PA). The arrow points to an area of calcification within the proximal dilated portion of the duct; this is often present in older patients with patent ductus arteriosus (PDA). Note the narrowing as the ductus enters a mildly dilated pulmonary artery (PA). (B) Cardiac catheterization revealed that the pulmonary artery mean pressure was ∼60% of systemic and the patient did have a moderate left-to-right shunt (calculated Qp:Qs of 1.7:1). This figure depicts a large-volume mechanical contrast injection via a pig-tail catheter in the proximal descending thoracic aorta (Ao) with evidence of left-to-right flow to the pulmonary artery (PA) via the tubular-appearing PDA (arrow). Note that the narrowing at the pulmonary artery end is not fully appreciated here as it is on the CT (A). The device selection for closure of this PDA was based on CT measurements. This is a realistic example of the additive data provided by cross-sectional imaging when characterizing and planning interventions on congenital malformations.

Fig. 17.8, Angiocardiogram with contrast material injected into the left ventricle (LV) of a 15-year-old male with a vascular ring. The ascending aorta (Ao) bifurcates into a right aortic arch (RAA) that passes anterior to the trachea, and a left aortic arch (LAA) that passes posterior to the esophagus; hence a vascular ring that compressed the trachea and esophagus. The two aortic arches joined to form the descending aorta (DAo). All anatomical components of the vascular ring are visualized except the ligamentum arteriosum, which was surgically divided. LCA , Left carotid artery; LSA , left subclavian artery; RCA , right carotid artery; RSA, right subclavian artery.

Despite its seeming anatomical simplicity, the ductus arteriosus is a complex structure. The fetal ductus is a major anatomical component of a contiguous intrauterine great arterial system consisting of pulmonary trunk/ductus/aortic continuity that delivers 85% of right ventricular output into the descending aorta. Persistent fetal circulation is a designation applied to an intrauterine right-to-left ductal shunt that persists after birth. Persistent patency of the ductus arteriosus is abnormal and therefore undesirable, although certain forms of congenital heart disease depend on neonatal ductal patency for survival. Ductal-dependent circulations include malformations in which a patent ductus is the only source of pulmonary arterial blood flow (pulmonary atresia with intact ventricular septum), the only source of systemic arterial blood flow (aortic atresia or complete interruption of the aortic arch), or the only source of bidirectional blood flow (simple complete transposition of the great arteries) (see relevant chapters).

The ductus arteriosus is derived from the sixth aortic arch. By the fourth month of gestation, ductal tissue has become distinctive, differing histologically from pulmonary arterial and aortic tissue. At 16 weeks’ gestation, the ductus consists of a muscular arterial channel with an endothelium separated by an internal elastic lamina and a thin subendothelial layer. The media differs at the aortic and pulmonary ends, so ductal media can be aortic, pulmonary, or mixed. As gestation continues, the intima thickens, and the subendothelial layer is invaded by cells from the media that disrupt the internal elastic lamina. At term, the mature ductus harbors conspicuous intimal cushions that protrude into the lumen. The ductus is then capable of contraction— functional closure —which is followed by anatomical closure that uniformly begins at the pulmonary arterial end (see Fig. 17.5 and see earlier). Anatomical closure follows a sequence of immunohistochemical and ultrastructural changes, , namely:

  • 1.

    separation of endothelium from internal elastic lamina;

  • 2.

    enfolding and ingrowth of endothelial cells;

  • 3.

    migration of undifferentiated medial smooth muscle cells into the subendothelium;

  • 4.

    fragmentation of the internal elastic lamina;

  • 5.

    sealing of the lumen by endothelial cell apposition;

  • 6.

    accumulation of lipid droplets; and

  • 7.

    intimal and subendothelial degenerative changes that spread centrally and peripherally and result in disappearance of endothelial cells at luminal apposition lines.

Fig. 17.5, Three-dimensional volume-rendered computed tomography angiogram of a 55-year-old with systemic hypertension that was incidentally found to have aortic coarctation and a small restrictive patent ductus arteriosus (PDA). (A) Left lateral view. (B) Right posterior oblique view. Note that the PDA tethers the descending thoracic aorta to the pulmonary artery resulting in an S-shaped curve to the distal arch and proximal descending thoracic aorta. In addition to this the patient does have focal narrowing of the proximal descending thoracic aorta.

The normal process of functional closure begins within 10 to 15 hours after birth and is virtually complete (probe patent) by the second week of extrauterine life. The ductus is an anatomically closed ligamentum arteriosum 2 to 3 weeks after birth. , , When a ductus is destined to remain patent , the intrauterine subendothelial internal elastic lamina lies adjacent to the intimal cushions, endothelial cells adhere to the elastic lamina, and subendothelial edema with enfolding of endothelial cells does not occur. , A ductus that remains patent in full-term infants after 3 months of extrauterine life harbors the histological features of persistent patency just described. Spontaneous closure is then unlikely. , ,

In utero ductal tone is determined by an interplay between the constricting effect of oxygen (relatively weak because of low fetal pO2) and the dilating effect of endogenous prostaglandin E2. , Prostaglandin synthetase inhibitors administered to mammalian fetuses or to pregnant ewes constrict the fetal ductus and deprive the fetal right ventricle of its only outlet. As term approaches, the ductus becomes less responsive to prostaglandin E2 and more responsive to oxygen, setting the stage for constriction that begins a few hours after birth in full-term infants. Functional closure is closely coupled to the increase in extrauterine ambient oxygen tension which exerts a direct constricting effect on the ductal wall (see earlier). Oxygen-induced constriction has been related to inhibition of voltage-gated potassium channels. Flow through the closing ductus is transiently bidirectional. Left-to-right flow then decreases rapidly during the next 12 hours and cannot be detected at 48 hours. Anatomical closure is the culmination of morphological changes accrued during intrauterine ductal maturation (see earlier). , , In addition, apoptosis and smooth muscle cell proliferation have been assigned a role in anatomical closure.

In normal preterm infants, delayed closure of the ductus arteriosus is common. Premature neonates with a gestational age of 30 weeks or more usually experience spontaneous ductal closure within a time frame that corresponds to the closure time in full-term infants. , In full-term infants, spontaneous closure is unlikely after 3 months of age , and, in premature infants, is unlikely after 1 year of age ( Fig. 17.9 ). Exceptional examples of spontaneous closure have been documented between 5 and 6 years of age, between 7 and 14 years, after 17 years, and at age 19 years.

Fig. 17.9, X-ray from the 21-day-old premature male with a widely patent ductus arteriosus. The phonocardiogram is shown in Fig. 17.16 . Pulmonary blood flow is increased, the heart is considerably enlarged, and a thymus (arrows) obscures the base. By age 4 months, the ductus had spontaneously closed, the thymus had disappeared, and the x-ray was virtually normal.

Persistent patency of the ductus in premature infants sometimes coincides with respiratory distress, but the distress may not improve with subsequent ductal closure. , , Patent ductus in preterm infants is associated with reduced cerebral blood flow due a steal effect caused by the aortic-to-pulmonary shunt, rather than by a limited capacity of the preterm left ventricle to achieve adequate cardiac output. , Prolonged suboptimal cerebral oxygenation due to a patent ductus may impair brain growth, leading to adverse neurodevelopmental outcomes. Decreased blood flow through the abdominal aorta can also reduce perfusion of the liver, gut, and kidneys, leading to hepatic failure, renal insufficiency, and necrotizing enterocolitis.

First trimester maternal rubella with rash carries an 80% incidence of intrauterine viral infection, deafness, and cataracts ( Fig. 17.10 ), and congenital heart disease in two thirds of offspring. Patent ductus arteriosus accounts for a third of the congenital malformations and is characterized by maturational arrest and an immature ductal wall of the type found at 16 weeks’ gestation (see earlier).

Fig. 17.10, A 5-year-old female whose mother had first trimester rubella. The bandage followed ophthalmic surgery for cataract. The child had a patent ductus arteriosus.

Physiological consequences

The physiological consequences of persistent patency of the ductus arteriosus depend on five variables: (1) the size of the ductus, (2) pulmonary vascular resistance, (3) the adaptive response of the left ventricle to volume overload, (4) prematurity, and (5) respiratory distress. When the ductus is restrictive , pulmonary vascular resistance is normal, right ventricular afterload is normal, and the hemodynamic consequences are negligible. When the ductus is moderately restrictive and pulmonary vascular resistance is normal or nearly so, right ventricular afterload is not significantly affected, and continuous aortic-to-pulmonary flow imposes only a moderate volume load on the left ventricle ( Figs. 17.11 and 17.12 ; and ; see also ). About 95% of isolated patent ductuses are restrictive or moderately restrictive. When the ductus is non-restrictive , systolic pressure in the aorta and pulmonary trunk equalize at systemic level, so the direction of blood flow depends on the relative resistances in the systemic and pulmonary vascular beds ( Figs. 17.13–17.15 ; ; see also and ). If pulmonary resistance is lower than systemic, a left-to-right shunt is established, imposing volume overload on the left ventricle, while right ventricular afterload remains at systemic level (see Fig. 17.2 A). When pulmonary vascular resistance exceeds systemic, the shunt is reversed (see Fig. 17.2 B). Volume overload of the left ventricle is then curtailed, pressure overload of the right ventricle remains at systemic level, and the pulmonary vascular bed exhibits histological changes similar to primary pulmonary hypertension or Eisenmenger syndrome (see Chapter 14 ). ,

Fig. 17.11, Transthoracic echocardiogram of a 24-year-old female with dyspnea on exertion and a continuous murmur heard in the left subclavicular region. (A) Parasternal short-axis view with color Doppler demonstrating high-velocity continuous flow from the descending aorta (DAo) to the main pulmonary artery (MPA). The ascending aorta (AAo) and the right pulmonary artery (RPA) are labeled. (B) Apical four-chamber view demonstrating an enlarged left ventricle (LV) due to left-to-right shunting at the great arterial level resulting in increased LV preload. The right ventricle (RV) is normal in size because the shunt does not result in increased RV preload. (C) Continuous-wave Doppler clearly demonstrates continuous left-to-right flow at a systolic velocity of 4 m/s and end diastolic velocity of 3 m/s. This patient’s noninvasive right upper extremity blood pressure at the time of the echocardiogram was 110/65 mm Hg. The estimated pulmonary artery (PA) systolic pressure is mildly elevated at 46 mm Hg (110 to 64) and the PA diastolic pressure is estimated at 29 mm Hg (65 to 36), which is moderately elevated. These findings indicate a somewhat restrictive patent ductus arteriosus that nevertheless is causing sufficient left-to-right shunting to increase the PA systolic and diastolic pressures and result in LV volume overload.

Fig. 17.12, Conical-type patent ductus arteriosus (PDA) in a 62-year-old presenting with decompensated heart failure and pulmonary edema. (A) Cineangiography, lateral projection of a mechanical contrast injection in the distal aortic arch (Ao) demonstrating a conical-type PDA with left-to-right flow to a moderately dilated main pulmonary artery (MPA). Note the size discrepancy between the enlarged aortic isthmus of the PDA and the restrictive narrowing at the MPA entry point. (B) Transthoracic echo with color Doppler, parasternal short-axis view, demonstrates diastolic flow from the descending aorta via the PDA to the pulmonary artery. The jet is directed at the pulmonary valve (PV) with resultant pulmonary valve regurgitation. (C) Subcostal view demonstrates diastolic high-velocity jet from the PDA to the PA and the PV. (D) Apical four-chamber view in systole demonstrates a dilated left ventricle (LV) with severe functional mitral regurgitation (MR). Herein one can see the long-term consequences of untreated PDA with significant left-to-right shunt and left ventricular volume overload. The patient underwent device closure of the PDA with resultant resolution of symptoms, reduction in mitral regurgitation severity, and decrease in left ventricular size.

Fig. 17.2, Illustrations of two major flow patterns in patent ductus arteriosus (PDA). (A) This illustration depicts a left-to-right shunt through a large tubular patent ductus in which pulmonary vascular resistance is lower than systemic vascular resistance. Shunt flow is from aorta (Ao) into the pulmonary artery (PA). The left atrium (LA) and left ventricle (LV) are enlarged due to the increased pulmonary blood flow and hence pulmonary venous return. The right ventricle (RV) is not enlarged. (B) This figure illustrates the long-term consequence of a large PDA and progressive increase in pulmonary arterial resistance to a suprasystemic level. Shunt flow is from PA into the Ao immediately distal to the left subclavian artery, and hence the lower body is cyanotic. The LA and LV are not enlarged, because the pulmonary venous return is limited by the severity of the pulmonary arterial disease. The RV is enlarged and hypertrophied.

Prolonged exposure to ductal patency in the preterm infant can result in early and significant remodeling of the left heart to be larger and more spherical, with a corresponding increase in volume. This compensatory cardiac physiology represents an adaptive change to the volume overload induced by a patent ductus arteriosus.

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