A 6-years-old boy with abdominal pain was admitted to our hospital. Physical Examination after Admission: Heart rate 140 beats per minute, respiratory rate 20 breaths per minute, blood pressure 116/65 mmHg, weight 20 kg, arterial saturation 98%. The patient is tall and thin. There is bilateral exotropia and pectus carinatum. There are deformities in the joints of the limbs: contracture of the interphalangeal joints of the fingers, bilateral clubfoot, and deformity of the toe joints with flexion.

The boy was previously seen in our hospital in 2019, and echocardiography examination revealed ascending aortic aneurysm (Aortic Root Z-Scores:11.7), congenital aortic insufficiency (severe) and patent ductus arteriosus. Genetic testing revealed a heterozygous mutation in the TGFBR2 gene (C.1411G > T, p.D471Y), leading to the diagnosis of LDS type 2. Emergency aortic valve and ascending aorta replacement surgery (Bentall procedure, Mechanical valve 25, Graft 28 mm), aortic arch resection with artificial graft replacement (D: 24*10 mm, L: 50 cm), ductus arteriosus ligation was performed. After 1-year post-Benatll procedure, the computed tomographic angiography (CTA) showed the maximum aortic diameter of 12 mm. Besides the cardiac surgery in 2019, the patient also underwent craniotomy for the resection of a prepontine arachnoid cyst at our hospital in 2020, and hand surgery for polydactyly in an external hospital in 2023.

CTA was performed during admission. CTA indicates aortic dissection (DeBakey Type III, Stanford Type B), involving the aortic arch to the abdominal aorta (at the mid-level of the left kidney). The intimal tear is located at the T5 level. A significant hematoma surrounds the aorta at the level of the diaphragm(Fig. 1.A). Electrocardiogram is normal. Echocardiography shows left ventricular hypertrophy, mechanical valve function is normal, and the descending aorta exhibits an intimal flap. On the first day of admission, the boy developed dyspnea, with arterial saturation dropping to 93%. Endotracheal intubation was performed for assisted ventilation. The boy was not anticoagulated with warfarin or low molecular heparin at time of dissection. International normalized ratio remained between 2.0 and 2.8. Following multidisciplinary discussions, thoracoabdominal aortic replacement surgery was performed.

A) a large intimal fissure (red arrow). B) Preoperative 3-dimensional computed tomographic image showing the aortic dissection near the diaphragm (blue arrow) forming a huge hematoma around it. C) Marked dilatation of the thoracoabdominal aorta and formation of a huge aneurysm

The patient was placed in the right lateral position, exposing the left inguinal region. The chest cavity was opened at the left fifth intercostal space. The aorta revealed an aneurysmal dilatation. The maximum diameter of the dissecting aortic aneurysm was approximately 5.5 cm. At the level of the diaphragm, the aneurysm formed a large surrounding hematoma. Cannulation was performed through the inferior vena cava and the abdominal aorta to establish extracorporeal circulation. Proximal cross-clamping was applied to the left subclavian artery, and cross-clamping of the aorta was performed at the level above the celiac trunk. The aneurysm was incised, and the thrombus was extracted. Trimming of the aorta was performed, with proximal aorta and artificial blood vessel (MAQUET, polyester, D:10 mm) subjected to an end-to-end anastomosis. The abdominal aorta, mesenteric artery, and bilateral renal arteries were cut at an angle, and an end-to-side anastomosis was performed with the artificial graft. The T10-T11 intercostal artery was anastomosed to the side of the artificial blood vessel with an island flap, and the remaining intercostal arteries were sutured closed. The overall extracorporeal circulation time was 276 min. The patient was discharged on the 11th day postoperatively. A team consisting of pediatric and cardiac surgeons conducted follow-up on the patient. The girl had mild chest pain postoperatively, with no neurological complications observed. CTA scans were planned at the first and third months postoperatively.

The postoperative CTA of the patient at one (Fig. 2.D) and three months (Fig. 2.E) revealed that the artificial blood vessel was unobstructed and there was no stenosis at the anastomosis sites. However, compared to the CT scans taken one month postoperatively, the false lumen of the descending aortic arch in the third month postoperative CTA appeared enlarged, forming a localized bulge (Fig. 2.F). The Adamkiewicz artery is visualized. We plan to perform aortic arch replacement on the boy. However, for the boy’s better recovery and overall health improvement, we aim to maximize the interval between the second and third interventions.

D) Postoperative CTA three-dimensional reconstruction in the first month. E) Postoperative CTA three-dimensional reconstruction in the third month. F) CT scan in the third month after surgery showed an enlargement of the false lumen in the descending thoracic aorta