Abdominal aortic rupture from an impaling osteophyte following blunt trauma

Abdominal aortic rupture from an impaling osteophyte following blunt trauma Seth A. Vernon, MD,a William R. C. Murphy, MD,a Todd W. Murphy, MD,a,b and James M. Haan, MD,a,b Wichita, Kan Blunt injury of the abdominal aorta is highly fatal. We present an unusual case of an osteophyte impaling the abdominal aorta treated by endovascular repair. A 77-year-old man sustained a thoracolumbar fracture-dislocation with posterior aortic rupture between his celiac and superior mesenteric artery origins. His aortic injury was treated with a stent graft, excluding the celiac origin. He was dismissed on postoperative day 6. At 6 months, he had returned to most preinjury activities, and at 2-year follow-up, he continues to have good functional outcome. Endovascular repair may be successfully employed in select aortic injuries in hemodynamically stable patients. (J Vasc Surg 2014;59:1112-5.)

Aortic injuries after blunt trauma generally involve the thoracic aorta and carry a high mortality. Two recent studies demonstrated reduced operative time, procedural blood loss, and transfusions, as well as lower intraoperative and overall hospital mortality with use of endovascular repair.1,2 In both studies, most endovascular complications were related to graft malposition. Blunt abdominal aortic injuries (BAAIs) are uncommon, with less than 200 cases reported in the world literature.3-5 The incidence of BAAIs ranges from 0.04% to 0.67%, and the small subset with fullthickness rupture rarely reach the hospital alive.3,4,6 Many patients with BAAIs have multisystem trauma and present with severe concomitant injuries typically involving the bowel, liver, spleen, bony pelvis, or spine.6 Their pathogenesis and classification parallels thoracic aortic injuries and includes intimal flaps, pseudoaneurysms, and free rupture.3,7 The abdominal aorta has been appropriately divided into three zones based on the major anatomic branches and open exposure.3 Zone 1 is superior to the superior mesenteric artery (SMA), zone 2 is between the SMA and renal arteries, and zone 3 lies below the renal arteries.3 To the best of our knowledge, BAAI resulting from an osteophytic spur injury has not been reported. Herein, we present the first reported case of a posterior abdominal aortic-contained rupture resulting from an osteophytic spur piercing the aorta after a thoracolumbar fracturedislocation. Additionally, this is the first example of From the Department of Surgery, The University of Kansas School of MedicineeWichita,a and the Department of Trauma Services, Via Christi Hospital, Saint Francis Campus.b Author conflict of interest: none. Presented at the Fortieth Annual Meeting of the Western Trauma Association, Telluride, Colo, February 28-March 7, 2010. Reprint requests: James M. Haan, MD, Department of Trauma Services, Room 2514, Via Christi Hospital, Saint Francis Campus, 929 N. St Francis St, Wichita, KS 67214 (e-mail: [email protected]). The editors and reviewers of this article have no relevant financial relationships to disclose per the JVS policy that requires reviewers to decline review of any manuscript for which they may have a conflict of interest. 0741-5214/$36.00 Copyright Ó 2014 by the Society for Vascular Surgery. http://dx.doi.org/10.1016/j.jvs.2013.04.062

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a zone 1 traumatic abdominal aortic rupture managed without laparotomy and treated entirely with an endovascular approach. CASE PRESENTATION A 77-year-old man was an unrestrained driver who reversed his van into a tree, breaking the driver chair backrest, and resulting in hyperextension of his thoracolumbar spine. He was initially evaluated at an outlying facility where he was hypotensive and complained of back pain. He was transferred to our American College of Surgeonsverified level I trauma center and arrived 3 hours postinjury. He received 3 liters of crystalloid en route and was hemodynamically stable throughout. Upon evaluation at our trauma center, his blood pressure was 124/46 mm Hg, pulse was 106, and respiratory rate was 18. His Glasgow Coma Scale score was 15, and his only complaint was of back pain. Physical examination revealed thoracolumbar tenderness, and he was neurovascularly intact. Pertinent labs included a hemoglobin of 7.6 g/dL, lactate of 4.6 meq/L, international normalized ratio of 1.1, glucose of 223 mg/dL, and a creatinine of 0.91 mg/dL. Past medical history was significant for diabetes mellitus, hypertension, coronary artery disease, congestive heart failure, and osteoarthritis. Past surgical history was positive for right hip replacement. Medications included clopidogrel and aspirin. A Focused Assessment with Sonography for Trauma and plain films of his chest and pelvis were unremarkable for injury. Computed tomography angiography (CTA) of his thorax, abdomen, and pelvis revealed the following: T12-L1 fracture-dislocation with a degenerative osteophyte piercing the aorta (Fig 1, A) and a retroperitoneal hematoma with pseudoaneurysm (Fig 1, B). The SMA, celiac origin, and renal arteries were patent and uninjured. The posterior aortic injury was 3 mm inferior to the origin of the celiac artery and 5 mm superior to the SMA, corresponding to a zone 1 injury. The aortic diameter was 26 mm at the injury site. The pseudoaneurysm neck measured 6 mm wide by 10 mm long. Neurosurgery recommended posterior spinal stabilization following aortic repair. The patient was taken

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Fig 1. Computed tomography angiography (CTA) of the thorax, abdomen, and pelvis demonstrating (A) T12-L1 fracture dislocation with degenerative, spear-like osteophytes (arrows). B, Retroperitoneal hematoma with contrast extravasation (arrow) and zone 1 pseudoaneurysm just below the celiac artery.

emergently to our endovascular-capable operating room and prepped for celiotomy and thoracotomy. Single-lumen general endotracheal anesthesia was induced. We performed percutaneous left femoral and open right femoral access without systemic heparinization. Flush angiogram confirmed contrast extravasation between the celiac and SMA origins. A Zenith TX2 TAA 32-mm  127-mm endovascular stent graft (Cook Medical, Bloomington, Ind) was deployed to cover the rupture site and celiac artery ostium, excluding celiac flow. The graft was oversized 23% to achieve this deployment exclusion. The uncovered fixation wires spanned the SMA and the fabric seated just superior to the SMA (Fig 2). Intraoperative postdeployment angiography revealed collateral flow through the pancreaticoduodenal arcade, gastroduodenal, and common hepatic artery (Fig 2). Since the arteriogram demonstrated collateral perfusion, we elected not to perform open debranching with bypass. Consideration was given to placing a spinal drain; however, due to the patient’s severe arthritic spine disease and fracturedislocation, neurosurgery and anesthesiology recommended not placing a spinal drain. On postoperative day 1, the patient underwent posterior spinal stabilization. He was extubated on postoperative day 3 and was walking with physical therapy on postoperative day 4. The patient was dismissed to rehabilitation on postoperative day 6. His hemodynamics and renal function were maintained throughout the postoperative period without pressors. His creatinine never climbed above 0.90 mg/dL. Total contrast exposure was 285 mL (125 mL initial CTA, 60 mL during endovascular aneurysm repair, and 100 mL follow-up CTA on postoperative day 4). Intraoperative fluoroscopy time was under 7 minutes.

At 6 months postinjury, the patient was living independently on his farm and had returned to most preinjury activities. A 6-month follow-up CTA showed thrombosis of the celiac trunk, no endoleak or stent migration, and continued collateral flow through the proper hepatic artery (Fig 3). Serial CT was performed at 6-month intervals showing continued patency and no evidence of migration or other complication. The patient’s medical comorbidities did progress, necessitating nursing home placement where he remains at the time of this article, 2.5 years postinjury. DISCUSSION Treatment of all aortic pathology has dramatically changed over the past decade as a result of advances in endovascular technology and its availability. From elective repair of aortic aneurysms and occlusive disease to emergent repair of thoracic transections, endovascular therapies play a major role in the treatment of aortic disease. The trauma literature continues to mount with regard to endovascular repair of thoracic aortic transection. In anatomically suitable patients, endovascular repair of thoracic aortic transection is now first-line therapy due to reduced morbidity and mortality as compared with open repair.1,2,8 The natural progression of applying similar techniques to BAAI is clearly underway, as reported in case series from others.5-7,9,10 The rarity of BAAI makes this entity difficult to study. The limited evidence available suggests its use is feasible in certain patients. Some have reported on the use of endovascular stent grafts to repair sequelae of BAAIs or after damage-control laparotomy identified an injury.4-6,9,10 This combined technique may be particularly enticing when one encounters concomitant hollow viscus injury with contamination.

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Fig 2. Final intraoperative angiogram confirming proper stent graft deployment sealing pseudoaneurysm and covering celiac with collateral flow from the superior mesenteric artery (SMA).

This report represents the first case in which endovascular therapy was used as the sole modality to successfully treat a zone 1 pseudoaneurysm. However, we realize this injury pattern is unique in that no other intra-abdominal structure was involved. Our patient was also hemodynamically stable, permitting mobilization of the endovascular team. Many BAAI patients have sustained multisystem injuries and present in extremis with other concomitant intra-abdominal injuries that necessitate laparotomy. When embarking on an endovascular approach, consideration should be given to available resources and concurrent injuries. While we utilized a nonfenestrated endovascular stent graft in our case, other commercially available devices such as aortic cuffs may have also been effective. Fenestrated grafts are available at some institutions, and in our case, may have been effective at sealing the injury without covering the celiac artery. Covering the celiac artery was an option in our case, as there was enough collateralization to prevent ischemia. However, if collateralization had been inadequate, we would have performed open debranching with bypass, as an appropriate fenestrated stent graft was not available at our institution. When considering endovascular stent graft treatment of vascular trauma, adjacent orthopedic injuries and their definitive repair should be considered to avoid future disruption or kinking of grafts. Our patient had no neurological deficit or other indication for spine reduction, which contributed to his suitability as a candidate for an endovascular approach. If he had required manipulation of his unstable spine with potential stent graft disruption or secondary aortic injury, an open approach may have been favored. Regardless, in a hemodynamically stable patient, there should be a multidisciplinary plan formulated prior

Fig 3. Six-month postoperative surveillance computed tomography angiography (CTA) showing stent graft without migration, celiac origin thrombosis (arrow), patent superior mesenteric artery (SMA; with arrow) and back-filling of the celiac artery (CA; with arrow).

to proceeding with endovascular treatment. A theoretical complication in our patient is erosion of bone through the stent graft over time as the aorta pulsates adjacent to the vertebral osteophytes. In our particular patient, osteophyte excision would have been performed if he had required a laparotomy for vascular repair or anterior approach. Fortunately, we were able to minimize his operative time and risk by leaving the osteophyte alone. Longterm durability of stent grafts in the trauma population is unknown, and hesitation is warranted in young patients. However, as illustrated by our case, stent grafts seem well suited for elderly trauma patients with multiple medical comorbidities and a high open operative risk. We present both an unusual mechanism of injury and innovative surgical approach. This case adds to the mounting evidence that endovascular repair of aortic injuries is reasonable in properly selected trauma patients. Our case also supports the feasibility of using endovascular techniques for proximal abdominal aortic injuries with exclusion of the celiac trunk. Furthermore, this is the first documented case of an osteophyte spearing the abdominal aorta and the first example of an entirely endovascular approach to a BAAI at this unique location with a good outcome with 2 years of follow-up. REFERENCES 1. Riesenman PJ, Brooks JD, Farber MA. Acute blunt traumatic injury to the descending thoracic aorta. J Vasc Surg 2012;56:1274-80. 2. Celis RI, Park SC, Shukla AJ, Zenati MS, Chaer RA, Rhee RY, et al. Patterns of femoropopliteal recurrence after routine and selective stenting endoluminal therapy. J Vasc Surg 2013;57:37-43.

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3. Shalhub S, Starnes BW, Tran NT, Hatsukami TS, Lundgren RS, Davis CW, et al. Blunt abdominal aortic injury. J Vasc Surg 2012;55: 1277-85. 4. Michaels AJ, Gerndt SJ, Taheri PA, Wang SC, Wahl WL, Simeone DM, et al. Blunt force injury of the abdominal aorta. J Trauma 1996;41: 105-9. 5. Huang JT, Heckman JT, Gunduz Y, Ohki T. Endovascular management of stenosis of the infrarenal aorta secondary to blunt abdominal aortic trauma in a multiply injured patient. J Trauma 2009;66:E81-5. 6. Brathwaite CE, Rodriguez A. Injuries of the abdominal aorta from blunt trauma. Am Surg 1992;58:350-2. 7. Starnes BW, Lundgren RS, Gunn M, Quade S, Hatsukami TS, Tran NT, et al. A new classification scheme for treating blunt aortic injury. J Vasc Surg 2012;55:47-54.

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8. Xenos ES, Abedi NN, Davenport DL, Minion DJ, Hamdallah O, Sorial EE, et al. Meta-analysis of endovascular vs open repair for traumatic descending thoracic aortic rupture. J Vasc Surg 2008;48: 1343-51. 9. Gunn M, Campbell M, Hoffer EK. Traumatic abdominal aortic injury treated by endovascular stent placement. Emerg Radiol 2007;13: 329-31. 10. Voellinger DC, Saddakni S, Melton SM, Wirthlin DJ, Jordan WD, Whitley D. Endovascular repair of a traumatic infrarenal aortic transection: a case series. Vasc Surg 2001;35:385-9.

Submitted Jan 16, 2013; accepted Apr 29, 2013.