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J Thorac Cardiovasc Surg 1996;112:415-423
© 1996 Mosby, Inc.

SURGERY FOR CONGENITAL HEART DISEASE

UNUSUAL FORMS OF TRACHEOBRONCHIAL COMPRESSION IN INFANTS WITH CONGENITAL HEART DISEASE

From Marie Lannelongue Hospital, Paris, France.

Received for publication August 31, 1995 Revisions requested Oct. 27, 1995; revisions received Dec. 11, 1995 Accepted for publication Jan. 18, 1996. Address for reprints: Claude Planché, MD, Department of Pediatric Cardiac Surgery, Marie Lannelongue Hospital, 133, Avenue de la Résistance, 92350 Le Plessis-Robinson, France.

Abstract

Three groups of unusual forms of tracheobronchial compression caused by vascular anomalies are presented. Three patients had an encircling right aortic arch with a left-sided descending aorta and ligamentum arteriosum (group 1), two patients had airway compression caused by a pincer effect between a malposed and enlarged ascending aorta and the descending aorta (group 2), and three patients had airway compression after an arterial switch operation for transposition of the great arteries (group 3). Symptoms developed in all patients before the age of 4 months, and six of them had multiple failed attempts at extubation before the surgical intervention directed at relieving the airway compression. Fiberoptic endoscopy was used in all patients as a first-line diagnostic tool and was 100% accurate in establishing the diagnosis. The operations performed were aortic uncrossing in group 1, dissection and aortopexy of the right or left main bronchus in group 2, and dissection of the left main bronchus and lysis of adhesions in group 3. In group 1 there was one early death, resulting from aspiration, and one late death 4 years later, resulting from an unrelated cause. In this group, bronchomalacia was noted after the operation and resolved gradually in the year after the intervention. In group 2, one patient died of an aortobronchial fistula after placement of a bronchial stent. Group 3 patients had good postoperative results. Two of them are completely symptom-free and one has residual bronchomalacia and may need placement of a bronchial stent. (J THORACCARDIOVASCSURG1996;112:415-23)

Tracheobronchial compression in infants with congenital heart disease has been reported in many contexts, including that of vascular rings and slings—with or without associated intracardiac disease—large left-to-right shunts, anomalous origin of a coronary artery from the pulmonary artery, or the iatrogenic variety following repair of an aortic arch interruption, aortic coarctation, or construction of systemic–pulmonary artery shunts. ^1-4 Our experience consists of more than 500 infants and children undergoing operations for symptomatic tracheobronchial compression belonging to all of these groups. For the purpose of this report, we have selected eight patients who had unusual compressive mechanisms, as well as other features that set them apart. They all had symptoms before 4 months of age. Six patients required preoperative tracheal intubation and had repeated, unsuccessful attempts to be weaned from mechanical ventilation.

Patients and methods

The clinical records of eight patients were retrospectively reviewed and the following data were recorded for each patient: sex, age and weight at the onset of symptoms, need for preoperative intubation, type of disease, age at the first and subsequent operations and the nature of these operations, postoperative complications, duration of postoperative ventilatory support, hospital stay, and length of follow-up.

Three groups of patients were identified (Table I): group 1, consisting of three patients with right-sided aortic arch with left-sided descending aorta and ligamentum arteriosum (also described as circumflex aorta); group 2, comprising two patients in whom the trachea was compressed between an enlarged aortic root, displaced toward the right of the mediastinum and the descending aorta; and group 3, comprising three patients who had tracheobronchial compression as a consequence of an arterial switch operation for transposition of the great arteries.

View larger version (26K): [in this window] [in a new window]   Fig. 1. The vascular anatomy present in circumflex aortas: the right-sided aortic arch passes over the right main bronchus, then takes a retroesophageal course and joins the left-sided descending aorta.

View larger version (25K): [in this window] [in a new window]   Fig. 2. Schema of the aortic uncrossing procedure. The right subclavian artery is divided. The aortic arch is transected proximal to the origin of the right subclavian artery, mobilized, and reanastomosed to the left side of the ascending aorta and left carotid artery, in front of the trachea.

Extubation was possible 4 and 15 days later in the first two patients but was delayed by 11 weeks in the last patient, who had severe bronchomalacia.

Patient 1 died 1 month after the operation after an episode of aspiration, possibly related to recurrent laryngeal nerve injury during the last intervention. The postmortem examination showed that the aortic repair was of normal caliber. No residual bronchial compression was present, but bronchomalacia of the left main bronchus was noted. A perimembranous ventricular septal defect, 2 by 4 mm, considered too small to require closure during the last operative intervention, was noted.

Patients 2 and 3 still had occasional stridor in the year that followed their operations. They both had a second bronchoscopic examination, which confirmed the disappearance of the vascular compression. Digital subtraction angiography of the aortic arch confirmed the accuracy of the vascular repair. Patient 2 was lost to follow-up after his adoption 2 years after his operation, at which time he was free of symptoms referable to airway compression. Patient 3 died 4 years later of an unrelated cause.

Group 2
Patient 4 was born at 29 weeks' gestation, with a birth weight of 1000 gm, and required immediate intubation for respiratory distress. On the third day, a heart murmur was heard and an echocardiogram diagnosed tetralogy of Fallot, with a right-sided aortic arch and descending aorta. Repeated attempts at weaning from mechanical ventilation failed, because each was followed by an episode of bronchospasm. When the infant was 10 weeks old, cardiac catheterization and angiocardiography confirmed the echocardiographic findings and outlined a dilated, dextroposed ascending aorta, separated from the right-sided descending aorta by a narrow space, particularly at the level of the right main bronchus. A bronchoscopic examination showed that the right main bronchus was reduced to a slitlike opening. At the age of 3 months, when he weighed 2500 gm, he underwent a right thoracotomy. Dissection of the right main bronchus confirmed that the bronchus was "squashed" between the ascendingand descending aorta. Inasmuch as the ascending aorta could not be mobilized enough through this approach, an extensive mobilization of the descending aorta was undertaken, which enabled it to be suspended to the posterior parietal pleura, relieving the compression. A small patent ductus arteriosus, which did not contribute to airway compression, was left intact to enhance pulmonary blood flow in the context of tetralogy of Fallot. A systemic–pulmonary artery shunt was not performed, because the oxygen saturation was adequate and there was concern that a shunt might aggravate the compressive symptoms. Postoperative bronchoscopic examination showed relief of the compression and mild bronchomalacia. Prolonged ventilation was needed because of severe bronchopulmonary dysplasia. A tracheostomy was performed and then allowed to close 10 months later, when all respiratory problems had subsided. A one-stage repair of the tetralogy of Fallot was not considered in view of the patient's weight and hypoplastic pulmonary valve ring. The child remained well for the following 2 years, when he underwent an elective correction of the tetralogy of Fallot. He was extubated the following day and had an uncomplicated postoperative course. He remains well 9 years after the initial operation.

Patient 5 was born at 40 weeks' gestation and required tracheal intubation at 3 days of age for respiratory distress. Cardiac catheterization and angiocardiography performed 5 days later showed a perimembranous as well as a muscular ventricular septal defect, with isosystemic pressures in the pulmonary artery, as well as absence of the right pulmonary artery (Fig. 3). The right lung was hypoplastic and the ascending aorta was enlarged and shifted to the right side of the mediastinum. Bronchoscopic examination showed the left main bronchus to be compressed by a pulsatile element in an anteroposterior plane. The right bronchus was patent. Repeated episodes of hypercapnia necessitated use of high ventilatory pressures, which in turn caused a large bronchopleural fistula to develop in the hypoplastic right lung. Repeated attempts at extubation failed, and at the age of 4 weeks she had a left thoracotomy to free the compressed left main bronchus. A small patent ductus arteriosus was divided to gain access to the bronchus, which was extensively mobilized. It was evident that the compression was caused by the large aortic root, but anterior aortopexy was not performed, because the management plan involved closure of the ventricular septal defects in the immediate future. A postoperative bronchoscopic examination showed that the bronchial compression was relieved but that the left bronchus had extensive bronchomalacia. Unfortunately, the intracardiac repair had to be delayed because the right bronchopleural fistula became infected and ultimately necessitated a right pneumonectomy at the age of 10 weeks for control of sepsis. The right lung was completely necrotic and purulent. A second bronchoscopic study 2 months after the original operation showed recurrent left bronchial compression. Because repeated operative interventions seemed unlikely to be successful, a selective left bronchial intubation with a size 4 uncuffed endotracheal tube was performed. Intubation provided immediate improvement in ventilatory mechanics. Unfortunately, 2 weeks later a massive hemoptysis resulted in airway obstruction and death. The postmortem examination showed an aortobronchial fistula caused by compression of the bronchial wall between the bronchial stent from within and the ascending aorta from without.

View larger version (147K): [in this window] [in a new window]   Fig. 3. Left ventricular angiogram in patient 5 (anteroposterior and lateral views), outlining a dilated ascending aorta, displaced posteriorly and to the right. The left main bronchus (LMB) is compressed between the ascending and descending aorta.

All patients had a simple transposition and in each of them the aorta was situated anterior and to the right of the pulmonary artery. The arterial switch operation was performed at the ages of 11, 5, and 9 days by means of our standard technique, which we have used in more than 800 patients to date. The patent ductus arteriosus was ligated with 3-0 Ti-Cron sutures (Davis & Geck Div., American Home Products, Danbury, Conn.) and the divided ends were oversewn with 7-0 polypropylene. The Lecompte maneuver was used in all, to bring the neopulmonary artery in front of the neoaorta. The postoperative course was uneventful in all and the initial progress after discharge was satisfactory.

At the ages of 5, 20, and 4 weeks, respectively, they all had sudden, severe respiratory distress, ranging from severe stridor and wheezing in patient 8 to respiratory arrest mandating emergency endotracheal intubation in patients 6 and 7. The initial diagnosis was bronchiolitis, but this was not supported by the bacterial and viral cultures or by the subsequent clinical course. Extubation was not possible in patient 6 and the clinical condition of patients 7 and 8 remained precarious.

All patients had cardiac catheterization and angiocardiography to elucidate the diagnosis. The coronary anastomoses were free of technical problems, as were the great vessels, with the aorta describing a curve concave anteriorly, as a result of the Lecompte maneuver (Fig. 4). Patient 8 was found to have a large collateral vessel originating from the left subclavian artery and passing to the left hilum anterior to the left bronchus. He also had a computed tomographic scan of the thorax, which showed marked compression of the left main bronchus between the ascending and descending aorta (Fig. 5).

View larger version (117K): [in this window] [in a new window]   Fig. 4. Arch aortogram in patient 7, demonstrating the posterior displacement of the ascending aorta after the Lecompte maneuver. However, the space is not sufficiently narrow to alone explain the airway symptoms.

View larger version (85K): [in this window] [in a new window]   Fig. 5. Thoracic computed tomographic scan with contrast in patient 8, showing near obliteration of the left main bronchus after an arterial switch operation. PA, Pulmonary artery; AA, ascending aorta; DA, descending aorta.

At the ages of 8 weeks, 13 months, and 14 weeks, respectively, the patients underwent a left thoracotomy to relieve the bronchial compression. The operative findings were similar in all three cases. The compression appeared to be due to three individual elements situated in three different planes. The aortopulmonary window was occupied by a mass of small, matted lymph nodes, probably a reaction to recurrent bronchial infection. A second plane of dense fibrosis occupied the site of the divided ductus arteriosus; on further mobilization, it became apparent that the posteriorly displaced ascending aorta contributed to the compression on a deeper plane. The collateral vessel crossing the bronchus was divided in patient 8. Inasmuch as he was the only one of the three whose bronchus remained flattened after the wide dissection, suggesting significant bronchomalacia, anterior and posterior aortopexies were also performed.

Patient 6 had an uncomplicated postoperative course, remains symptom-free, and has normal bronchoscopic findings 6 years later.

Patient 7 was extubated on return to the intensive care unit and had no postoperative problems. A bronchoscopic study 3 months later showed relief of the compression and mild residual bronchomalacia, and he remains free of symptoms 9 months after the intervention.

Patient 8 had a bronchoscopic study in the immediate postoperative period, which showed no residual compression but significant bronchomalacia of the proximal left bronchus. Inasmuch as he was successfully extubated 3 days later, however, a bronchial stent was not considered, because in our experience the bronchomalacia always improved over the following months. His clinical condition did indeed improve, but he still has noticeable wheezing on effort, and a second bronchoscopic examination 5 months later showed the bronchomalacia to be unchanged. If improvement does not continue, the placement of a bronchial stent will be considered.

Discussion

Vascular anomalies causing tracheobronchial compression were observed as early as 1737, when Hommel ⁹ described a case of double aortic arch. Surgical treatment of a double aortic arch was first performed by Gross ¹⁰ in 1945. In the same report he described the anatomic features that we observed in our first group of patients: a right-sided aortic arch, retroesophageal in location, with a left-sided ligamentum arteriosum and descending aorta. In 1948 Edwards ¹¹ described the embryologic development of the aortic arches in relation to these anomalies.

Since then, many reports have documented successful resolution of compressive symptoms after division of vascular rings. In 1991 we ⁷ reported our own experience with 468 cases.

This report focuses on unusual cases, which did not fall into the expected clinical patterns. We have also described a new form of compression associated with repair of transposition of the great vessels, previously described only as a single case report in the literature. ¹²

Patients in groups 1 and 2 required treatment before the age of 6 weeks. They all required preoperative intubation of the trachea for respiratory distress manifested as stridor and wheezing. Repeated attempts at extubation were unsuccessful in all.

Bronchoscopic examination was performed as a first-line diagnostic tool. As pointed out by Binet and Langlois ¹³ from our institution, the bronchoscope accurately visualizes the compression and confirms its extrinsic and vascular nature. In these patients, it was 100% accurate in making the diagnosis.

We acknowledge that bronchoscopic study may be hazardous in inexperienced hands, but we have not had any problems with it and advocate its routine use. ¹⁴ We believe bronchoscopy is safer than tracheography, which Corno and associates ¹⁵ found to be the most useful investigation in their patients with congenital heart disease and coexistent airway obstruction. It also has the advantage that it can be performed at the bedside, avoiding hazardous transfers to remote radiology departments.

We have not used magnetic resonance imaging for diagnostic purposes, but we acknowledge the excellent quality of the imaging afforded by the three-dimensional reconstructions possible with this technique. ¹⁶

The vascular ring described in group 1 (which for brevity we call circumflex aorta, a term introduced by D'Cruz and associates ¹⁷ in 1966) may cause respiratory problems early in life. In the vast majority of cases, division of a vascular ring at the level of the ductus arteriosus suffices for the relief of symptoms. ¹⁸ However, in our three patients, division of the vascular ring combined with mobilization of the divided ends of the ductus was ineffective. Aortopexy is sometimes advocated as an adjunctive operative measure, ¹⁹ but we used it without success in patient 2.

We have not encountered any reports of patients with this abnormality having severe residual compression after division of the ductus arteriosus, but without a careful bronchoscopic examination it can be difficult to differentiate residual compression from secondary bronchomalacia. For example, in the series reported by Lam and coworkers, ²⁰ one of the patients with a double aortic arch with a small anterior component could not be extubated after the operation and died later as a consequence of severe respiratory distress. We could speculate that residual compression was the causative mechanism.

The cause of respiratory difficulties in the postoperative period is generally thought to be secondary bronchomalacia, but we believe that this should be a diagnosis of exclusion, because the symptoms of residual compression may be similar. In our three patients, bronchoscopic examination after division of the vascular ring showed the vascular compression to be unrelieved and a new solution had to be found.

A previous report by Domalain and coworkers ²¹ described how the symptoms of esophageal compression in an infant with a circumflex aorta were relieved by dissecting the esophagus and uncrossing it behind the vascular ring, which was left undisturbed.

Hellebrand and associates ²² reported a case in which the retroesophageal aortic segment was long and tortuous. As in our three patients, there was an associated ventricular septal defect, for which banding of the pulmonary artery was performed. At a second operation, a polytetrafluoroethylene graft was interposed between the left common carotid artery and the descending aorta. A direct anastomosis was not performed because of concern this would complicate the future intervention of pulmonary artery debanding and closure of the ventricular septal defect, which was successfully performed 5 years later. The authors contended that future conduit changes would be needed to accommodate for growth.

Although Knight and Edwards ⁸ found associated intracardiac lesions to be rare with this type of vascular ring, all our three patients, as well as the patient reported on by Hellebrand's group, had an associated ventricular septal defect. As D'Cruz, ¹⁷ Ergin, ¹⁴ and their colleagues commented in their respective series, in this type of vascular ring intracardiac defects may in fact be quite common.

Although Hodorf and coworkers ⁴ documented the rapid regression of the signs of obstructive airway disease after closure of large left-to-right shunts, we have not found any improvement in patient 2. Patient 1 did not have closure of the ventricular septal defect, because it was considered too small to warrant surgical attention. Inasmuch as the airway obstruction was demonstrated both bronchoscopically and angiocardiographically to be caused by the aortic arch itself, reduction in size of the pulmonary artery and left atrium would have had little impact on the primary anomaly.

Damage to the left recurrent laryngeal nerve probably contributed to the aspiration episode causing the death of our first patient, because the dissection of the mediastinum was difficult owing to the obliteration of the tissue planes caused by the first operation.

Our current technique evolved in parallel with our increasing understanding of the anomaly. We now believe that if the vascular compression is still evident on bronchoscopic examination after division of the ligamentum arteriosum and wide mobilization, aortic uncrossing should be performed early, thus minimizing the risk of damage to structures such as the recurrent laryngeal or phrenic nerves or the thoracic duct.

The group 2 patients had compressive symptoms mandating endotracheal intubation within 3 days of birth. Patient 4 had an enlarged, dextroposed ascending aorta, a right-sided aortic arch, and a right-sided descending aorta. The space normally occupied by the right main bronchus was narrow, accounting for the appearance of his symptoms in the neonatal period. In his case, posterior aortopexy allowed just enough space to relieve the bronchial compression. Postoperative ventilatory support was prolonged as a consequence of bronchopulmonary dysplasia related to prematurity. His airway, however, recovered completely, and at the time of his cardiac operation he had normal bronchoscopic findings. In recent years, we have successfully used tracheal stents in patients who had severe secondary tracheomalacia. This has allowed earlier extubation after the surgical intervention directed at relieving the compressive symptoms.

Patient 5 had compression of the left bronchus caused by a posterior and rightward displacement of the ascending aorta, in the context of agenesis of the right pulmonary artery and ventricular septal defects. She underwent division of a patent ductus arteriosus and freeing of the left bronchus. Bronchoscopic examination in the immediate postoperative period confirmed the relief of the vascular compression, with residual severe bronchomalacia. The subsequent right pneumonectomy accentuated the posterior and rightward displacement of the ascending aorta, for a second bronchoscopic study 2 months after pneumonectomy showed recurrent vascular compression. Compression of the distal trachea and left main bronchus in children with a shift of the mediastinum to the right owing to right lung hypoplasia or after right pneumonectomy has been described in reports by Dohlemann, ²³ Horvath, ²⁴ Szarnicky, ²⁵ and their associaates. Rerouting of the aorta with a synthetic graft, as used by Horvath's group, ²³ was not considered to be a satisfactory solution in this patient with bronchomalacia and infection.

Selective left bronchial intubation, although initially successful in relieving the obstruction, was ultimately deleterious, because it caused the development of an aortobronchial fistula. A bronchoplastic procedure could perhaps have been considered. However, the risk of failure would have been high in a patient after a right pneumonectomy, with a long segment of bronchomalacia. ²⁶

Although patient 5 had two ventricular septal defects, which could incriminate a left-to-right shunt as a causative mechanism for her airway compression, she in fact began having symptoms immediately after birth, while having an elevated pulmonary vascular resistance and minimal left-to-right shunting. Thus we believe that the two group 2 patients, at first sight so different in their anomalies and pulmonary blood flow characteristics, share the cause of their bronchial compression: a mechanical obstruction by an enlarged, displaced ascending aorta. Aortopexy, not performed for the described reasons in patient 5, should accompany the liberation of the bronchus.

The three group 3 patients present an interesting late complication after the arterial switch operation. Worsey and coworkers ¹² described this complication in a patient who had stridor 3 months after an arterial switch operation. Our patients' symptoms developed in a similar time frame, between 1 and 4 months after the operation.

We agree with Worsey's group ¹² that the posterior displacement of the ascending aorta after the Lecompte maneuver must play an important role in causing bronchial compression, but other mechanisms must contribute as well, because the condition appears to be uncommon and becomes manifest later, once fibrous tissue forms around the area of division of the patent ductus arteriosus. Airway obstruction then sets the scene for repeated infective episodes, which cause regional lymph node enlargement.

In all our patients, three distinct layers contributed to bronchial compression: the layer of lymph nodes, the scar tissue around the stump of the patent ductus arteriosus, and on a deeper plane the aortic "pincer."

Considering the large number of arterial switch operations performed worldwide, this complication seems rare. In our own series, we recognized it only three times in more than 800 cases. However, inasmuch as respiratory symptoms are common in this age group, their connection to the heart operation may not be realized. We could not find any particular pattern to identify the patients at risk for this condition and therefore cannot make any recommendations to try to avoid it.

On the basis of our experience, we chose to perform an extensive freeing of the bronchus to relieve the already symptomatic obstruction. Aortopexy was used as an adjunctive measure in patient 8, the only one to have residual problems.

Summary

Three rare patterns of bronchovascular compression occurring in a young group of patients are described. Bronchoscopy was found to be the most useful diagnostic tool. The special pathologic problems posed by some of these patients led us to develop new surgical solutions. Bronchoplastic procedures were not used in this series, although at least five patients had significant secondary bronchomalacia. Because bronchomalacia affected relatively long bronchial segments in these small infants, we did not believe that the success of these procedures could be assured. An expectant policy of postoperative ventilation was used, and we successfully extubated all but one, who died of a complication related to a bronchial stent. When respiratory obstruction persists or recurs after the operation in this context, we think that vascular compression has to be carefully excluded.

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