Impact of iliac artery anatomy on the outcome of fenestrated and branched endovascular aortic repair.

Fenestrated and branched endovascular aneurysm repair (FB-EVAR) is a valid option to treat juxtarenal and pararenal abdominal aortic aneurysms and thoracoabdominal aortic aneurysms. Because successful deployment depends on complex maneuvers, hostile iliac artery anatomy (HIA) can prejudice the FB-EVAR outcome. The aim of the study was to evaluate the impact of HIA on FB-EVAR outcome. Between 2010 and 2015, all patients undergoing FB-EVAR were prospectively categorized according to iliac anatomy (friendly iliac artery anatomy [FIA] or HIA). HIA was defined as the presence of one of the following: severe (>90-degree) iliac angle, extensive (>50%) iliac circumferential calcification, hemodynamic iliac stenosis or obstruction, external iliac artery diameter <7 mm, or previous aortoiliac/femoral graft. Early end points were technical success (absence of type I or type III endoleak, target visceral vessel [TVV] loss, conversion to open repair), intraoperative adjunctive maneuvers (IAMs; iliac percutaneous transluminal angioplasty/stenting, surgical iliac conduit, intra-aortic graft rotations, several attempts of TVV cannulation), intraoperative technical problems (iliac rupture, significant endograft twisting, difficult TVV cannulations, TVV injuries, TVV loss), and 30-day mortality. Follow-up end points were survival, TVV patency, and freedom from reintervention. Ninety-four patients (male, 87%; age, 73 ± 6 years) with 59 (63%) juxtarenal and pararenal abdominal aortic aneurysms and 35 (37%) thoracoabdominal aortic aneurysms underwent FB-EVAR, for a total of 324 TVVs; 60 (64%) patients had HIA and 34 (36%) had FIA. Patients with HIA and FIA had similar preoperative clinical characteristics, except for coronary artery disease, peripheral artery occlusive disease, and American Society of Anesthesiologists class 4 (47% vs 24% [P = .03], 12% vs 0% [P = .04], and 28% vs 9% [P = .03], respectively). Technical success was 96% (HIA, 97%; FIA, 95%; P = .6). In HIA, adjunctive iliac procedures were performed in 32 cases (surgical conduit, 14 [15%]; percutaneous transluminal angioplasty/stenting, 27 [29%]). Endograft twisting and difficult TVV cannulation occurred in 13 (14%) and 33 (35%) cases, respectively (HIA 18% vs FIA 15% [P = .09]; HIA 28% vs FIA 21% [P = .03]). TVV cannulation failed in nine cases and injury occurred in five (TVV patency rate, 97.8%; HIA 94.7% vs FIA 98.3%; P = .3). One (1%) iliac rupture occurred in HIA, needing surgical repair. Overall, 44 (47%; HIA 55% vs FIA 25%; P = .03) IAMs were necessary. Perioperative mortality was 4% (HIA 3% vs FIA 5%; P = .9). At multivariate analysis, predictors of IAMs were external iliac diameter <7 mm (odds ratio [OR], 12.5; 95% confidence interval [CI], 2.2-71.4; P = .004) and extensive iliac calcifications (OR, 8.3; 95% CI, 1.4-50.0; P = .02). The mean follow-up was 24 ± 17 months, with an overall survival of 87% and 71% at 1 year and 3 years, respectively, significantly lower in HIA compared with FIA (at 3 years, HIA 60% vs FIA 92%; P = .02). On multivariate analysis, HIA was a significant predictor of late mortality (OR, 3.6; 95% CI, 1.1-13.2; P = .04). Freedom from reintervention (87%) and 3-year TVV patency (92%) were similar in the two groups. HIA does not significantly affect the early outcome of FB-EVAR. However, in patients with HIA, procedures are technically more demanding and late mortality is increased. Iliac characteristics should be taken into account to correctly stratify the surgical risk in FB-EVAR.

Gallitto E ，Gargiulo M ，Faggioli G ，Pini R ，Mascoli C ，Freyrie A ，Ancetti S ，Stella A ... -  《-》

Fenestrated and Branched Thoraco-abdominal Endografting after Previous Open Abdominal Aortic Repair.

Proximal para-anastomotic aneurysms, or aneurysmal degeneration of the native aorta above a previous open abdominal aortic repair (Pr-AAAs), are challenging scenarios. The aim of this study was to report the early and mid term outcomes of endovascular repair of Pr-AAAs by fenestrated and branched endovascular aneurysm repair (FB-EVAR). From 2006 to 2017, pre-operative, intra-operative, and post-operative data from patients undergoing FB-EVAR for Pr-AAAs at two European vascular surgery units were prospectively collected and retrospectively analysed. Early results were considered in terms of technical success (target visceral vessel cannulation and stenting, absence of type I - III endoleak, iliac limb occlusion and 24 h mortality); spinal cord ischaemia (SCI) and 30 day and in hospital mortality. Survival, target visceral vessel (TVV) patency, and freedom from re-interventions were also considered at the mid term follow up. Five hundred and forty-four patients underwent FB-EVAR to treat juxta/pararenal or thoraco-abdominal aneurysms. Of these patients, 108 (19.8%) cases were Pr-AAAs (94% male; mean ± standard deviation [SD] age 71 ± 4 years; American Society of Anesthesiologists' grade 3-4 in 74% and 26%, respectively). The previous open aortic repair (OR) was performed 10 ± 2 years before FB-EVAR. It was a tubular aorto-aortic repair in 63 (58.3%) cases, a bifurcated aortobi-iliac repair in 37 (34.2%) cases, and an aortobifemoral bypass repair in eight (7.4%) cases. A previous thoracic endovascular aneurysm repair (TEVAR) had been performed in seven patients (6.5%). The aortic lesion at the time of FB-EVAR was, according to the Crawford classification, a type I - III in 69 (63.9%) or a type IV 39 (36.1%) thoraco-abdominal aneurysm. The mean ± SD aneurysm diameter was 64 ± 6 mm. Overall, 390 TVVs (3.6 ± 1 TVV/case) were revascularised by an endograft with fenestrations (n = 63 [58.3%]), with branches (n = 26 [24.1%]), or with both fenestrations and branches (n = 19 [17.6%]). Tubular, trimodular, or aorto-uni-iliac implants were planned in 68 (63.0%), 38 (35.2%), and two (1.8%) patients, respectively. Proximal TEVAR, carotid-subclavian bypass, and iliac branch devices were planned as adjunctive procedures in 41 (38.0%), five (4.6%), and three (2.8%) cases, respectively. Overall technical success was 93%, with technical failures including five TVV losses (coeliac trunk, n = 1; renal arteries, n = 4) and three deaths within 24 h. Post-operative SCI occurred in seven patients (6.5%), four of which (3.7%) were permanent. SCI was more frequent in category I - III TAAAs (p = .042) and in endografts incorporating both fenestrations and branches (p = .023). Cardiac, pulmonary, and renal complications (reduction in glomerular filtration rate of ≥30% compared with baseline) occurred in 9%, 10%, and 20%, respectively. Bowel ischaemia was seen in three (2.8%) patients. Thirty day mortality was 4% and was associated with pre-operative chronic renal failure (p = .034), post-operative cardiac morbidity (p = .041), and bowel ischaemia (p = .003). Overall in hospital mortality was 5.5% (n = 6). Mean ± SD follow up was 38 ± 18 months. Survival was 82%, 64%, and 54% at one, three, and five years, respectively, and target visceral vessel patency was 93%, 91%, and 91%, respectively. Permanent haemodialysis was needed in four patients (3.7%). There was no late aneurysm related mortality. Survival during follow up was statistically significantly affected by pre-operative chronic renal failure (p = .022), post-operative cardiac morbidity (p = .042), SCI (p = .044), and bowel ischaemia (p = .003). Freedom from re-intervention at one, three, and five years was 89%, 77%, and 74%, respectively. Endovascular treatment of aneurysmal aortic degeneration above a previous open abdominal repair with FB-EVAR is safe and effective. If those promising results are confirmed at later follow up, FB-EVAR should be considered a prominent therapeutic option, especially in high risk patients.

Gallitto E ，Sobocinski J ，Mascoli C ，Pini R ，Fenelli C ，Faggioli G ，Haulon S ，Gargiulo M ... -  《-》

Off-the-shelf multibranched endograft for urgent endovascular repair of thoracoabdominal aortic aneurysms.

The aim of this paper was to report early and midterm results of endovascular repair of urgent thoracoabdominal aortic aneurysms (TAAAs) by the off-the-shelf multibranched Zenith t-Branch endograft (Cook Medical, Bloomington, Ind). Between January 2014 and April 2016, all patients with urgent TAAAs (asymptomatic with diameter >8 cm, symptomatic, or ruptured TAAAs) and aortoiliac anatomic feasibility underwent endovascular repair by t-Branch and were prospectively enrolled. Clinical, morphologic, intraoperative, and postoperative data were recorded. Follow-up was performed by duplex ultrasound, contrast-enhanced duplex ultrasound, and computed tomography angiography. Early end points were technical success (absence of type I or type III endoleak, loss of target visceral vessels [TVVs], conversion to open repair, or 24-hour mortality), spinal cord ischemia, and 30-day mortality. Follow-up end points were survival, TVV patency, type I or type III endoleaks, and freedom from reintervention. Seventeen patients (male, 71%; age, 73 ± 6 years; American Society of Anesthesiologists class 3/4, 60%/40%) affected by type II (47%), III (29%), and IV (24%) TAAAs were enrolled. The indications for t-Branch were as follows: contained TAAA rupture, four (24%); symptomatic TAAA (pain or peripheral embolism), four (24%); and TAAA diameter ≥8 cm, nine (52%). The mean TAAA diameter was 80 ± 19 mm, with 63 TVVs. Fifteen patients (87%) needed adjunctive intraoperative procedures: 14 proximal thoracic endografts (thoracic endovascular aortic repair), 1 left carotid-subclavian bypass, 2 endovascular hypogastric branches, and 2 surgical iliac conduits. In four cases (24%), a significant malorientation (≥60 degrees) of the main body occurred during t-Branch deployment. Technical success was achieved in 14 cases (82%), with technical failures consisting of the loss of three renal arteries (TVV patency, 95%). Spinal cord ischemia occurred in one case (6%) with temporary paraparesis. The 30-day mortality was 6% (one patient with ruptured type II TAAA died on postoperative day 7 of respiratory failure). Renal function worsening occurred in four patients (25%), with one case requiring permanent hemodialysis. The mean follow-up was 11 ± 9 months. Survival at 1 month, 6 months, and 12 months was 94%, 82%, 82%, respectively. No TAAA-related mortality and TVV occlusion occurred in the follow-up. One type III endoleak was detected at 3 months and successfully treated. Freedom from reintervention at 1 month, 6 months, and 12 months was 88%, 82%, and 82%, respectively. The off-the-shelf multibranched endograft is a safe and effective therapeutic option for urgent total endovascular TAAA repair for which a custom-made endograft is not obtainable in due time. However, the complex anatomy of these aneurysms needs a number of adjunctive and complex intraoperative procedures to achieve a durable repair.

Gallitto E ，Gargiulo M ，Freyrie A ，Pini R ，Mascoli C ，Ancetti S ，Faggioli G ，Stella A ... -  《-》

Impact of previous open aortic repair on the outcome of thoracoabdominal fenestrated and branched endografts.

Thoracoabdominal aortic aneurysms (TAAAs) after previous aortic open surgical repair (OSR) are challenging clinical scenarios. Redo-OSR is technically demanding, and standard endovascular repair is unavailable due to visceral vessel involvement. Fenestrated and branched endografts (FB-EVAR) are effective options to treat TAAAs in high surgical risk patients but dedicated studies on the FB-EVAR outcomes in patients with TAAAs with previous OSR are not available. The aim of the study was to evaluate the impact of previous OSR on TAAAs FB-EVAR outcomes. Between 2010 and 2016, all TAAAs undergoing FB-EVAR were prospectively evaluated, retrospectively categorized in two groups, and then compared: group A-primary TAAAs and group B-TAAAs after previous OSR (abdominal, thoracic, or thoracoabdominal aneurysm). Early end points were technical success (absence of type I-III endoleak, target visceral vessel loss, conversion to OSR, intraoperative mortality), spinal cord ischemia (SCI), and 30-day mortality. Follow-up end points were survival, target visceral vessel patency, and freedom from reinterventions. Sixty-two patients (male: 74%; age: 72 ± 7 years) with 1 (1%) extent I, 14 (23%) extent II, 24 (39%) extent III, and 23 (37%) extent IV TAAA underwent FB-EVAR. The mean TAAA diameter and total target visceral vessels were 65 ± 13 mm and 226, respectively. Ninety branches and 136 fenestrations were planned. Thirty cases (48%) were clustered in group A and 32 (52%) in group B. Patients in group A and group B had similar preoperative clinical and morphologic characteristics, except for female sex (group A: 40% vs group B: 13%; P = .02). Technical success was 92% (group A: 90% vs group B: 94%; P = .6), SCI 5% (group A: 10% vs group B: 0%; P = .1) and 30-day mortality 5% (group A: 10% vs group B: 0%; P = .1). The mean follow-up was 17 ± 11 months with a total survival of 86%, 80%, and 60% at 6, 12, and 24 months, respectively and no differences in the two groups (group A: 83%, 83%, and 67% vs group B: 88%, 78%, and 55% respectively; P = .96). There was no late TAAA-related mortality. Target visceral vessel patency was 91%, 91%, and 91% at 6, 12, and 24 months, respectively (group A: 87%, 87%, and 87% vs group B: 95%, 95%, and 95%; P = .25). Freedom from reinterventions was 90%, 87%, and 87%, at 6, 12, and 24 months, respectively, and it was significantly lower in group A compared with group B (group A: 83%, 76%, and 76% vs group B: 96%, 96%, and 96% respectively; P = .002). Previous open surgery repair does not significantly affect the early outcomes of FB-EVAR in TAAA, with encouraging results in terms of technical success, SCI, mortality, and lower reinterventions rate at midterm follow-up.

Gallitto E ，Faggioli G ，Mascoli C ，Pini R ，Ancetti S ，Vacirca A ，Stella A ，Gargiulo M ... -  《-》

Renal Artery Orientation Influences the Renal Outcome in Endovascular Thoraco-abdominal Aortic Aneurysm Repair.

To evaluate the impact of renal artery (RA) anatomy on the renal outcome of fenestrated-branched endografts (FB-EVAR) for thoraco-abdominal aortic aneurysms (TAAA). Between 2010 and 2016, all patients undergoing FB-EVAR for TAAA were prospectively collected. Anatomical, procedural, and post-operative data were retrospectively analysed. RA anatomy was assessed on volume rendering, multi planar and centre line reconstructions by dedicated software (3Mensio). RA diameter, length, ostial stenosis/calcification, orientation and aortic angles of the para-visceral aorta were evaluated. RA orientation was classified in four types: A (horizontal), B (upward), C (downward), D (downward + upward). RA revascularisation by fenestrations or branches was considered. Inability to cannulate and stent RA (RA loss), early RA occlusion (within three months), and composite RA events (one among RA loss, intra-operative RA lesion, RA related re-interventions, RA occlusion) were assessed. Seventy-three patients (male 77%; age 73 ± 6 years) with 39 (53%) type I, II, III and 34 (47%) type IV TAAA, underwent FB-EVAR, for a total of 128 RAs. The mean RA diameter and length were 6 ± 1 mm and 43 ± 12 mm, respectively. Type A, B, C, and D orientations were 51 (40%), 18 (14%), 48 (36%), and 11 (10%) RAs, respectively. Angulation of para-visceral aorta >45° was present in 14 cases (19%). Ostial stenosis and calcifications were detected in 20 (16%) and 16 (13%) RAs, respectively. Branches and fenestrations were used in 43 (34%) and 85 (66%) RAs, respectively. There were four (3%) intra-operative RA lesions (2 ruptures, 2 dissections). Ten (8%) RAs were lost intra-operatively because of the inability to cannulating and stenting. On univariable analysis, type B RA orientation (p = .001; OR 13.2; 95% CI 3.2-53.6), para-visceral aortic angle > 45° (p = .02; OR 4.9; 95% CI 1.3-18.5) and branches (p = .003; OR 9.0; 95% CI 1.9-46.9) were risk factors for intra-operative RA loss; type C RA orientation was a protective factor (p = .02; OR 0.1; 95% CI 0.01-0.9). On multivariable analysis, type B RA orientation (p = .03; OR 5.9; 95% CI 1.1-31.1) and branches (p = .03; OR 7.3; 95% CI 1.1-47.9) were independent risk factors for intra-operative RA loss. Fourteen patients suffered post-operative renal function worsening (> 30% of the baseline). The mean follow up was 19 ± 12 months. Four (3%) early RA occlusions occurred in three patients (2 single kidney patients required permanent haemodialysis). Type D RA orientation (p = .00; RR 17.8; 8.6-37.0) and branches (p = .004; RR 3.2; 2.4-4.1) were risk factors for early RA occlusion on univariable analysis. Five patients (7%) required early RA related re-interventions (recanalisation + relining 3; stent graft extension 1; parenchymal embolisation 1). No late RA occlusion or re-interventions were reported during follow up. Composite RA events occurred in 17 (13%) cases. Type B (p = .05; OR 3.9; 95% CI 1.1-15.7) or D (p = .006; OR 10.9; 95% CI 2.3-50.8) RA orientations and branches (p = .006; OR 5.7; 95% CI 1.6-20.3) were independent predictors of composite RA events on multivariable analysis. Renal artery orientation significantly affects the early RA outcome of FB-EVAR for TAAA. Intra-operative RA loss is predicted by type B RA orientation and branches, while early RA occlusion is predicted by type D orientation and branches. The present data suggest that in TAAA, fenestrations should be the first choice for renal revascularisation in type B and D RA orientations.

Gallitto E ，Faggioli G ，Pini R ，Mascoli C ，Ancetti S ，Abualhin M ，Stella A ，Gargiulo M ... -  《-》