Endovascular treatment for pseudoaneurysm after carotid blowout syndrome

Article information

J Neurocrit Care. 2020;13(2):115-118
Publication date (electronic) : 2020 December 24
doi : https://doi.org/10.18700/jnc.200026
1Division of Rheumatology, Department of Internal Medicine, Wonkwang University College of Medicine, Iksan, Republic of Korea
2Department of Surgery, Keimyung University School of Medicine, Daegu, Republic of Korea
3Department of Neurology, Keimyung University School of Medicine, Daegu, Republic of Korea
Corresponding Author: Hyungjong Park, MD Department of Neurology, Keimyung University School of Medicine, 1035 Dalgubeol-daero, Dalseo-gu, Daegu 42601, Korea Tel: +82-53-258-7747, Fax: +82-53-258-4380 E-mail: hjpark209042@gmail.com
Received 2020 September 24; Revised 2020 November 9; Accepted 2020 November 26.

Abstract

Background

Pseudoaneurysms of the carotid artery are rare and can be both a cause and consequence of carotid blowout syndrome (CBS) in patients with head and neck cancer. Surgical or endovascular treatment approaches may be useful for managing this condition.

Case Report

A 55-year-old man presented with a pulsatile mass surrounding the carotid bifurcation in the neck. He reported a history of CBS that occurred as a surgical complication while removing a benign neck cyst. Additionally, he reported a history of laryngeal cancer that underwent complete remission after surgery and radiotherapy. The mass was diagnosed as a pseudoaneurysm. Surgical treatment proved challenging owing to the patient’s history of neck surgery and radiotherapy; therefore, stent-graft deployment was performed and the absence of pulsations was checked through the neck mass.

Conclusion

Endovascular treatment may be a useful therapeutic strategy in cases of post-CBS pseudoaneurysm in patients undergoing surgery and/or radiotherapy for head and neck cancer.

INTRODUCTION

Carotid artery (CA) aneurysms are rare and account for approximately 0.4%–4% of all peripheral artery aneurysms [1]. Pseudoaneurysms are the most common type of CA aneurysms [2]. Trauma is the most common cause of CA pseudoaneurysm, followed by surgery and/or radiotherapy for head and neck cancer [3]. Pseudoaneurysms are not covered by healthy, well-vascularized tissue and can therefore rupture easily [4]. Carotid blowout syndrome (CBS) is the rupture of the CA and its branches, which can cause life-threatening complications due to massive blood loss, as well as neurological complications such as cerebral infarction [5]. A pseudoaneurysm of the CA, while being one of the main known causes of CBS, can also occur as a surgical complication for CBS [1,6].

Pseudoaneurysms are treated using open surgery or with endovascular treatments, such as parent vessel sacrifice, using detachable balloons or coil embolization and stent-graft placement [7,8]. Currently, endovascular treatment is regarded as a better alternative to open surgery in selected patients [7]. We report a case of post-CBS pseudoaneurysm that was treated successfully using endovascular therapy in a patient with a history of surgery and radiotherapy for laryngeal cancer.

CASE REPORT

A 55-year-old man was diagnosed with laryngeal cancer 23 years prior to presentation; complete tumor resolution was observed after partial laryngectomy and radiotherapy. Approximately 1 year before his visit, a palpable mass surrounding the left carotid bifurcation was observed. Ultrasonography revealed a subcutaneous, solid, and well-demarcated ovoid mass that distorted the left internal jugular vein thus necessitating excision. The left internal CA (ICA) was injured intraoperatively during neck dissection which resulted in active bleeding that was managed by an emergency primary suture at the site of injury. The following day, the patient was observed to be drowsy, with an altered mental status, and with severe dysarthria. Diffusion-weighted magnetic resonance imaging revealed border-zone and cortical infarctions in the left cerebral hemisphere (Fig. 1A and B). Computed tomography angiography (CTA) showed multifocal long-segment stenosis of the left common CA (CCA) (Fig. 1C). Volume replacement was performed in addition to blood pressure control to maintain cerebral perfusion pressure. The patient showed complete recovery a month later and was discharged with aspirin (100 mg), clopidogrel (75 mg), and atorvastatin (80 mg) for multifocal stenosis extending along the CCA to the ICA. Histopathologic findings of the neck mass revealed benign soft tissue without any evidence of inflammation or tumor cells. No bleeding or abnormal vessel formation was observed at the site of CBS; the patient was therefore instructed to follow up with the outpatient department.

Fig. 1.

(A, B) Cortical and border-zone infarctions in the left cerebral hemisphere. (C) Multifocal long-segment stenosis of the left common carotid artery extending to the proximal internal carotid artery on computed tomography angiography. (D) A pulsating mass in the vicinity of the previous injury site of the carotid artery (red arrow). (E) Pseudoaneurysm immediately beneath the skin (white arrow). (F) Pseudoaneurysm (black arrow) with long-segment stenosis of the left common carotid artery on digital subtraction angiogram. (G) Non-visualization of pseudoaneurysm after deployment of a self-expandable stent graft. (H) The disappearance of the pseudoaneurysm with good stent patency on computed tomography angiogram 7 days after endovascular treatment. (I) The disappearance of the pulsatile mass in the vicinity of the previous injury site of the carotid artery (red arrowhead) after 3 months.

During follow-up, a pulsating mass was detected in the vicinity of the previous site of injury (Fig. 1D). This mass gradually increased in size and was clearly identified a year after the development of the CBS. CTA revealed a new pseudoaneurysm immediately beneath the skin in addition to multifocal long-segment stenosis of the left CCA (Fig. 1E). Because of the patient’s history of partial laryngectomy and radiotherapy, we expected that performing surgical ligation would be technically challenging; therefore, a self-expandable stent graft was used to treat the post-CBS pseudoaneurysm. We inserted a 10-F sheath through the right femoral artery and an 8-F guiding catheter (Shuttle; Cook, Bloomington, IN, USA) was into the proximal portion of the left CCA. Left CCA angiography revealed a pseudoaneurysm at the carotid bulb with multifocal long-segment stenosis of the left CCA (Fig. 1F). A microcatheter (Headway 17; Microvention, Tokyo, Japan) was placed at the orifice of the external CA (ECA) and coil embolization (Tornado, Cook) of the left ECA was performed to prevent a type II endoleak after stent placement. A 0.035-inch guidewire was placed at the petrous portion of the left ICA after confirming that coil embolization had completely blocked blood flow through the ECA. A 9×60-mm self-expandable stent graft (Covera Plus; Bard Medical, Covington, GA, USA) was selected based on the dimensions of the affected CA (the graft size was at least 1 mm greater than the diameter of the CCA). The self-expandable stent graft was then advanced over the 0.035-inch guidewire and deployed to extend between the distal segment of the left CCA and the proximal ICA, ensuring that the pseudoaneurysm was completely covered. Left CCA angiography was performed after stent graft deployment and showed the absence of a pseudoaneurysm. We subsequently placed a carotid stent into the stenotic segment of the left CCA, which, if left untreated, could have served as a potential source of emboli thereby predisposing the patient to ischemic stroke. A 9×50 mm carotid stent (Carotid Wallstent; Boston Scientific, Santa Clara, CA, USA) was advanced over a 0.014-inch microwire (Transend; Stryker, Kalamazoo, MI, USA) and deployed from immediately beneath the orifice of the left proximal ICA, partially overlapping the previously deployed self-expandable stent graft. Left CCA angiography revealed no pseudoaneurysms, in-stent stenosis, or in-stent thrombosis (Fig. 1G). Carotid duplex ultrasonography was performed the following day and revealed no stenotic flow, in-stent stenosis, or thrombosis. Moreover, the patient did not show any postoperative neurological symptoms. A CTA was performed 7 days postoperatively which confirmed the disappearance of the pseudoaneurysm with good stent patency (Fig. 1H). After 3 months, the pulsatile mass disappeared completely (Fig. 1I).

DISCUSSION

A pseudoaneurysm is defined as a loss of integrity of the three layers of the arterial wall that can result in a contained rupture of blood vessels; this differs from a true aneurysm in which the three vascular walls are intact but dilated [9]. Pseudoaneurysms of the ICA are known to present as a growing pulsatile mass in the lateral aspects of the neck [10].

Radiotherapy following head and neck cancer surgery is known as an important cause of CA pseudoaneurysm that can lead to CBS [11]. The CA receives 80% of its blood supply from the vasa vasorum in its adventitia (the outermost layer of the CA) [4]; radiotherapy results in injury to the adventitia of the CA and/or its major branches, resulting in the weakening of the arterial wall [5,12]. Thus, radiotherapy itself can be the main cause of pseudoaneurysm formation in CA. In addition, weakening of the arterial wall due to radiotherapy after head and neck cancer surgery can increase the risk of pseudoaneurysm formation after surgical repair for CBS.

Treatment modalities for pseudoaneurysms can be categorized into surgical repair and endovascular treatment [7,8]. Surgical repair involves surgical ligation of the affected ICA followed by vascular bypass or anastomosis; this procedure sacrifices the ICA. Furthermore, surgical ligation can predispose patients to cerebral ischemia, and bypass or anastomosis cannot be performed when the aneurysms are located near the skull base. Additionally, the open access approach is challenging in patients who previously underwent surgery or radiotherapy for head and neck cancer [8].

Endovascular treatment involves deconstructive methods, such as occlusion of the affected ICA using a balloon or coil, and reconstructive methods, such as stent-graft placement [5,7]. Because stent-graft placement is less invasive and has lower complication rates [13], it may be a useful strategy for managing post-CBS aneurysms especially in patients with a history of surgery and/or radiotherapy for head and neck cancer. Nevertheless, the following factors should be considered prior to stent-graft placement for CBS: (1) it is necessary to assess the patient’s anatomical suitability for the procedure, as this method is only feasible in patients without excessive vascular tortuosity, to ensure easy access for the stent delivery system, and in those with patent femoral or iliac arteries to ensure placement of a large-caliber (10–11F) vascular sheath [14]; (2) stent-grafts are more thrombogenic than bare stents and warrant long-term aggressive antiplatelet therapy which involves a high risk for bleeding complications [15]; and (3) endoleak is a common complication of stent-graft placement. Specifically, reconstitution of the proximal branches of the ECA for lesions in the vicinity of the carotid bifurcation is associated with a risk for developing a type II endoleak from collateral vessels [16]; however, embolization of the main trunk of the ipsilateral ECA can reduce this risk [14].

In our case, the patient was relatively young and had a favorable vascular anatomy and was therefore considered to be a suitable candidate for endovascular treatment. In addition, severe adhesions were detected intraoperatively between the CA and the surrounding connective tissue, which occurred at the time of CBS development. Based on these findings, we performed endovascular treatment for a post-CBS pseudoaneurysm. Furthermore, we performed ECA embolization to prevent a type II endoleak.

In conclusion, the anatomical constraints associated with surgical treatment of post-CBS pseudoaneurysm make endovascular treatment an appealing alternative. This case illustrates the usefulness of stent-graft placement in treating post-CBS pseudoaneurysms.

Notes

Ethics statement

This study was reviewed and approved by the Institutional Review Board of Keimyung University Dongsan Hospital (IRB No. 2020-09-068). The requirement to obtain informed consent was waived by the Board.

Conflict of interest

Dr. JH Hong is an editorial board member of the journal but was not involved in the peer reviewer selection, evaluation, or decision process of this article. There are no other potential conflicts of interest relevant to this article to declare.

Funding

This work was supported by a National Research Foundation of Korea (NRF) grant funded by the Korean government (MSIT) (No. 2020R1G1A007100).

Author contributions

Conceptualization: HP, Data curation: CHC, YNR, SHL, YSJ, JHH, SIS, Writing–original draft: CHC, HP, Writing–review & editing: HP.

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Article information Continued

Fig. 1.

(A, B) Cortical and border-zone infarctions in the left cerebral hemisphere. (C) Multifocal long-segment stenosis of the left common carotid artery extending to the proximal internal carotid artery on computed tomography angiography. (D) A pulsating mass in the vicinity of the previous injury site of the carotid artery (red arrow). (E) Pseudoaneurysm immediately beneath the skin (white arrow). (F) Pseudoaneurysm (black arrow) with long-segment stenosis of the left common carotid artery on digital subtraction angiogram. (G) Non-visualization of pseudoaneurysm after deployment of a self-expandable stent graft. (H) The disappearance of the pseudoaneurysm with good stent patency on computed tomography angiogram 7 days after endovascular treatment. (I) The disappearance of the pulsatile mass in the vicinity of the previous injury site of the carotid artery (red arrowhead) after 3 months.