CASE REPORT CASE REPORT

32         SA JOURNAL OF RADIOLOGY • July 2008

CASE REPORT

Abstract
Endovascular stent graft repair for the treatment of post-traumatic 
aortic rupture is emerging as a safe, minimally invasive and attractive 
alternative to surgery. This report covers the importance of computer 
tomographic (CT) angiography as a non-invasive imaging modality in 
the diagnoses of post-traumatic aortic rupture and the role of CT in pre-
endovascular stent work-up. A detailed discussion on the endovascular 
procedure including the major limitations to stent insertion follows, and 
a comparison of endovascular stent graft versus surgery.

Introduction
Post-traumatic aortic rupture is the cause of 16% of all deaths from 
motor vehicle accidents; of all patients sustaining such injury, 85% will 
die before reaching hospital. Fifty per cent of the remaining survivors 
will die within 24 hours.1 Therefore, prompt diagnosis and treatment 
within this critical stage remains crucial.1

The recent development of aortic stent grafts has brought the 
management of thoracic aortic aneurysms into the realm of interventional 
radiology as an alternative to conventional open surgery.2 Stent graft 

placement is proving to be a safe, minimally invasive and effective 
treatment for thoracic aortic disease in poor surgical candidates, and 
short-term morbidity and mortality rates from endovascular repair 
compare favourably with those from surgery.2

Endovascular stent grafting of traumatic aortic 
arch pseudo-aneurysm

N Mahomed, MB BCh
T Briede, MB BCh, FCRad (SA)

M Modi, MB BCh, FCRad (SA), MMed

Department of Radiology, Chris Hani Baragwanath Hospital, University of the 
Witwatersrand, Johannesburg

Fig. 1. Post-contrast chest CT angiogram (axial view), demonstrating a 
tear in the distal aortic arch associated with a left haemothorax.

Fig. 2. Post-contrast chest CTA (coronal view), demonstrating the 
pseudo-aneurysm in the distal aortic arch.

Fig. 3. Digital subtraction angiogram with the pigtail catheter in the aortic 
arch demonstrating the descending thoracic aortic pseudo-aneurysm 
distal to the origin of the LSA.

Endovascular stent.indd   32 8/1/08   10:05:05 AM



CASE REPORTCASE REPORT

Case report
A 51-year-old taxi driver presented with significant chest pain following 
a high-impact motor vehicle accident. Chest X-ray demonstrated a 
widened mediastinum, and an urgent CT angiogram (CTA) of the 
chest was performed. The CTA revealed a dissection of the descending 
thoracic aorta distal to the origin of the left (L) subclavian artery 

(Stanford B), complicated by a 4 cm long pseudo-aneurysm3 (Figs 1 and 
2). An associated L haemothorax suggested leakage from the aneurysm.

The patient had a bovine-type aortic arch (i.e. the right (R) 
brachiocephalic artery and the L common carotid artery shared a 
common origin). These branches and the L subclavian artery were not 
involved in the dissection.

As the patient also had underlying hypertension and ischaemic heart 
disease, making him a poor surgical candidate, but was haemodynamically 
stable with no contraindication to aortic stenting, the decision was made 
to undertake an endovascular repair of the thoracic pseudo-aneurysm.

Endovascular procedure
The procedure was carried out under conscious sedation and local 
anaesthesia. The R common femoral artery was selected for deployment 
of the thoracic endograft (stent). An arterial cut-down was performed 
to obtain access for the required 20F introducer sheath. The cut-down 
was performed by the vascular surgical team. The previous CTA had 
revealed that the common femoral arteries were suitable in calibre as 
well as not being tortuous, so as to accommodate the introducer sheath 
and provide an arterial access site for the interventional procedure.

The L common femoral artery was also punctured percutaneously 
via a standard single-puncture needle with insertion of a 5F introducer 
sheath. This access site was used to perform thoracic arterial runs pre- 
and post-vascular stent deployment.

Pre-stent deployment thoracic aortography confirmed a large 
contained thoracic aorta pseudo-aneurysm originating just below the 
origin of the left subclavian artery (LSA) (Fig. 3). It was calculated 
that there was approximately 2 cm of normal aorta between the LSA 
and the start of the pseudo-aneursym. At the outset, this seemed to 
indicate sufficient length for a good ‘landing zone’ to avoid any possible 
occlusion of the LSA. A sharply angulated curve between the aortic arch 
and thoracic aorta was noted, however; hence, deployment distal to the 
origin of the LSA would lead to excessive kinking of the stent with likely 
failure of the device and possible occlusion of the aorta. It was decided 
that the stent needed to be placed more proximally, with the risk of 
occluding the LSA (Fig. 4).

The thoracic aortic stent used was a Gore TAG thoracic covered 
endoprosthesis (stent). This required a 20F sheath introducer. The 
selected endoprosthesis diameter was 28 mm, with the stent length 15 
cm. The stent diameter needs to be oversized relative to vessel diameter 
by approximately 10 - 15% to prevent migration of the stent and ensure 
good apposition against the vessel walls.2 The stent contains an external 
Nitinol support structure which enables it to self-expand and provide 
sealing by radial force. In addition, there are sealing cuffs on both ends 
to prevent type 1 endovascular leaks.2

Intravenous heparin (5 000 IU) was administered prior to deployment 
of the stent. The delivery catheter containing the constrained stent was 
deployed via the introducer sheath with the proximal end of the graft 
occluding the LSA at the ‘landing zone’, as placement more distally was 
deemed unsuitable owing to the angulation between the aortic arch and 
the descending aorta. At the time of stent deployment, a 9 ml balloon 
was inflated to ensure adequate and complete stent expansion.

Post-deployment angiography demonstrated complete exclusion 
of the pseudo-aneurysm by the stent, with partial occlusion of the LSA 

33         SA JOURNAL OF RADIOLOGY • July 2008

Fig. 4. Digital subtraction angiogram obtained after endovascular stent 
graft deployment, demonstrating complete exclusion of the pseudo-
aneurysm and occlusion of the origin of the LSA.

Fig. 5. Digital subtraction angiogram demonstrating LSA opacification 
due to retrograde flow from the left vertebral artery (as a subclavian 
artery steal phenomenon).

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CASE REPORT CASE REPORT

34         SA JOURNAL OF RADIOLOGY • July 2008

(Fig. 4). No endovascular leaks were demonstrated. The patient did not 
complain of any posterior fossa or left upper limb ischaemic symptoms 
post-procedure, due to adequate retrograde L vertebral and other 
collateral arterial flow (Fig. 5).

Discussion
There is controversy concerning the appropriate role of CT in the 
screening of chest trauma patients for aortic injuries, as plain radiographic 
findings for post-traumatic aortic rupture are nonspecific.1 Traditional 
chest radiographic findings that suggest aortic injury include mediastinal 
widening >8 cm, loss of clarity of the aortic knob, displacement of the 
nasogastric tube to the right of the T4 spinous process, left apical pleural 
capping, widened paraspinal lines, widened right paratracheal stripe 
>5 mm, and loss of the descending aortic line.1,3 However, the value of 
these as positive predictive signs is poor. Most patients with mediastinal 
widening on chest X-ray (CXR) have normal CT findings with no 
mediastinal haemorrhage.1 On the other hand, the negative predictive 
value of a normal CXR is high, at approximately 98%.1

CT findings of aortic injuries include blood within the mediastinum, 
deformities of the aortic contour, intimal flaps, thrombus or debris 
protruding into the aortic lumen, the presence of a pseudo-aneurysm, 
or an abrupt tapering of the diameter of the descending aorta compared 
with the ascending aorta (‘pseudocoarctation’).1,3 Most of these aortic 
injuries occur at or distal to the level of the ligamentum arteriosus1 in 
the aortic isthmus.

In addition to the evaluation of aortic injuries, CT demonstrates 
associated injuries such as subtle pneumothoraces, pneumomedi-
astinum, lung trauma, thoracic spine fractures and other skeletal 
injuries. CTA of the abdomen allows evaluation of the arteries, includ-
ing the diameter of the common iliac and femoral arteries and tor-
tuosity as potential access sites for endovascular stent deployment.1

It is well established that there is a high mortality rate for major 
aortic surgical repair, such as that for chronic Stanford type-B dissection 
which is 15%, reaching almost 40% for acute dissection.2 Endovascular 
repair of thoracic aneurysms is emerging as an attractive alternative to 
surgical graft replacement in both high- and low-risk surgical patients.2,4 
The benefit in high-risk surgical patients has already been established 
and, although the long-term results in low-risk patients are not known, 
the short-term mortality and morbidity compare favourably with that 
for surgery.2

The major limitations in selecting patients for endovascular repair 
are the lack of a suitable proximal landing zone (i.e. the aneurysm should 
arise at least 5 mm beyond the LSA) with ‘first-generation’ endovascular 
stents and inadequate vascular access.2,4 Generally, 10 - 15% oversizing 
of stent grafts is required to prevent migration and provide good 
apposition to the aortic wall. Ideally, the covered portion of stent grafts 
(excluding the length of the uncovered, bare extremities) should cross 
the lesion and at least 1.5 cm of the normal aorta at either end. Whenever 
possible, greater proximal and distal coverage should be used to prevent 

late stent graft migration and endovascular leak due to aortic disease 
progression. However, a stent used for the treatment of aortic dissection 
may be relatively short as the goal is then simply to close the entry 
point.2 When there is <15 mm of normal aorta between the aneurysm 
and the normal LSA, the covered part of the stent will have to occlude 
the origin of the LSA to ensure adequate length of the proximal landing 
zone. As described in our case report, the LSA origin would also have to 
be occluded when there is sharp angulation between the aortic arch and 
thoracic aorta such that deployment distal to the origin of the LSA would 
lead to excessive kinking of the stent with possible aortic occlusion.2 If 
the LSA origin is to be occluded, a left carotid-subclavian artery bypass 
may be created electively beforehand if contralateral vertebral artery 
perfusion is inadequate or if the patient develops symptoms after 
stenting.2 An alternative to covering the LSA would be the use of newer-
generation notched or fenestrated stents.2,4

Closure of the tear in post-traumatic arch rupture often occurs 
spontaneously after stent graft insertion. The most common complication 
after stent graft implantation is leakage into the aneurysm due to 
incomplete fixation of the stent graft to the aortic wall or due to graft 
defects.5 Other complications of endovascular repair of thoracic aortic 
aneurysms include expansion of the aortic tear and weakening of the 
aortic wall due to excessive balloon dilation of the stent graft, graft 
thrombosis and graft kinking.5 Rare complications, with reported rates of 
4 - 17%, include graft occlusion caused by the inability of the stent graft 
to bend along the acute angle in the aortic arch, and shower embolism 
due to mural thrombus dispersion during repeated introduction of 
guide wires, angiographic catheters and delivery systems; this may cause 
cerebral infarction during the endovascular procedure.5

Conclusion
CT will remain at the forefront in the diagnosis of post-traumatic aortic 
rupture and for pre- and post-endovascular stent management. Good 
CT imaging obviates the need for invasive angiography in a significant 
number of patients.

Stent graft placement is proving to be a safe, minimally invasive and 
effective treatment for the management of post-traumatic aortic pseudo-
aneurysms. The limitations of surgical repair include underlying co-
morbid disease, as described in our patient, whereas the major limitation 
to endovascular graft repair is anatomical suitability. In selected patients, 
short-term morbidity and mortality compare favourably with that 
obtained surgically.

1.    Kuhlman J, Posniak M, Collins J. Radiographic and CT findings of blunt chest trauma: Aortic injuries and 
looking beyond them. Radiographics 1998; 18: 1085-1106.

2.    Therasse E, Soulez G, Giroux MF, et al. Stent graft placement for the treatment of thoracic aortic diseases.
Radiographics 2005; 25: 157-173.

3.    Baron RL, Sagel RG, Stanley RJ. Computed tomography in the evaluation of mediastinal widening. 
Radiology 1981; 138: 107-113.

4.    Kato N, Shimono T, Hirano T, et al. Aortic arch aneurysms, extra-anatomical bypass and endovascular stent 
grafting. Cardiovasc Intervent Radiol 2002; 25: 419-422.

5.    Mita T, Arita T, Matsunaga N. Complications of endovascular repair for thoracic and abdominal aortic 
aneurysm: An imaging spectrum. Radiographics 2000; 20: 1263-1278.

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