Ascending Aortic Slide Repair for Interrupted Aortic Arch
In interrupted aortic arch with wide interruption gaps between proximal and distal aortic portions, the ascending aortic slide is a safe and reproducible technique. It provides a tension-free native tissue bridge with potential for growth, as well as providing a scaffold for patch augmentation in biventricular hearts or for Norwood stage I in univentricular palliation, which the authors performed in 8 neonates/infants.
In a neonate with type A interruption, right arch, right
descending aorta, and aberrant left subclavian artery, complete biventricular
repair was planned. With a Gore-Tex graft to the innominate artery for arterial
inflow and initial single venous right atrial cannulation, bypass was
commenced, the distal ductus was cannulated then transected proximal to the
cannula, and the patient was cooled to 25°C.
After cross-clamping and cardioplegia administration, the clamp was replaced with
a hemoclip and the cardioplegia needle was removed to free up the field. The
right descending aorta was clamped, the head vessels were snared, and antegrade
cerebral perfusion (ACP) was commenced at 50 cc/kg/minute (and adapted up to 70
cc/kg/min as needed using near-infrared spectroscopy monitoring).
The baby whose repair is shown in this video had a diminutive aortic root and 5
mm aortic valve. Therefore, the aorta was transected at the sinotubular
junction, and the root was opened down into the noncoronary sinus. The aortic
valve was probed to confirm size adequacy for the anticipated biventricular
repair. All remnant ductal tissue was excised from the descending aorta. The
ascending aorta was then fileted open with two parallel incisions all the way
up to the proximal arch.
The resulting bridge flap of native ascending aorta was rotated towards the
right shoulder and anchored to the descending aorta. The posterior distal wall
anastomosis was completed to form a native tissue bridge, which then formed the
neo-greater arch curvature. The diameter of the distal opening connected to the
native bridge tissue was checked.
The proximal anastomosis was made between the fileted ascending aorta and the
aortic root. Finally, the root was enlarged with a patch of homograft in the
opened noncoronary aortic sinus, followed by homograft arch augmentation into
the existing native tissue greater curvature scaffold. After de-airing, the
clamps were removed, and the ACP was converted to full flow bypass. In the
video, one can see the reconstructed right-sided arch, aortic root, and right
descending thoracic aorta.
Transatrial ventricular septal defect patch closure was performed after
conversion to bicaval cannulation and repeat cardioplegia. The patient’s postoperative
course was uneventful.
Recommended Reading:
1. Oosterhof T,
Azakie A, Freedom RM, Williams WG, McCrindle BW. Associated factors and trends
in outcomes of interrupted aortic arch. Ann Thorac Surg. 2004;78(5):1696-1702.
2. McCrindle BW, Tchervenkov CI, Konstantinov IE, et al. Risk factors
associated with mortality and interventions in 472 neonates with interrupted
aortic arch: a Congenital Heart Surgeons Society study. J Thorac
Cardiovasc Surg. 2005;129(2):343-350.
3. Jacobs ML, Rychik J, Murphy JD, Nicolson SC, Steven JM, Norwood WI. Results
of Norwood's operation for lesions other than hypoplastic left heart syndrome. J Thorac Cardiovasc Surg. 1995;110(5):1555-1561.