OBJECTIVE
To describe a totally laparoscopic technique for aortobifemoral bypass to treat aortoiliac atheromatous occlusive disease.
DESIGN
A feasibility study.
SETTING
A university teaching hospital.
SUBJECTS
Six piglets weighing between 70 and 80 kg were submitted to a totally laparoscopic retroperitoneal aortobifemoral bypass, performed through six trocar sites, with abdominal suspension and a gasless technique. No minilaparotomy was performed. After systemic heparinization, the infrarenal aorta was cross-clamped and the aortic bifurcation stapled. An end-to-end aorto-prosthetic anastomosis was performed. Retroperitoneal tunnels were created to allow each limb of the graft to join its corresponding femoral artery by a conventional anastomosis.
INTERVENTION
Totally laparoscopic aortobifemoral bypass.
MAIN OUTCOME MEASURES
Duration of the procedure, intraoperative blood loss and operative complications, bleeding in the immediate postoperative period. Evaluation of the aortic anastomosis at autopsy.
RESULTS
All aortobifemoral bypasses were completed in less than 4 hours. Intraoperative blood loss did not exceed 250 mL. No intraoperative complication was encountered except occasional bleeding at the aortic anastomosis upon releasing the arterial clamp. This was controlled with a collagen sponge (three cases) or extra stitches (two cases). The animals were observed for 15 minutes before sacrifice. Autopsy revealed a normal aortic anastomosis in all cases and a normal progression of the limbs of the graft under the ureters in the retroperitoneal tunnels.
CONCLUSIONS
This animal model demonstrates the feasibility of the aortobifemoral bypass through a laparoscopic approach. The retroperitoneal anatomy of the piglet is similar to that of man. Aortic surgery can be conducted as for the standard technique. We used a similar approach to perform the first human, totally laparoscopic aortobifemoral bypass with an end-to-end anastomosis.
[1]
Y. Dion,et al.
Experimental laparoscopic aortic aneurysm resection and aortobifemoral bypass.
,
1996,
Surgical laparoscopy, endoscopy & percutaneous techniques.
[2]
J. Herde,et al.
Laparoscopic vascular surgery: four case reports.
,
1995,
Journal of vascular surgery.
[3]
N. Katkhouda,et al.
Laparoscopy-assisted aortobifemoral bypass.
,
1993,
Surgical laparoscopy & endoscopy.
[4]
B. Jenssen,et al.
Paradoxical air embolism in pigs with a patent foramen ovale.
,
1992,
Undersea biomedical research.
[5]
T. R. Hennessy,et al.
Venous air embolism in swine: transport of gas bubbles through the pulmonary circulation.
,
1990,
Journal of applied physiology.
[6]
W J Penny,et al.
Effects of thrombin inhibition on the development of acute platelet-thrombus deposition during angioplasty in pigs. Heparin versus recombinant hirudin, a specific thrombin inhibitor.
,
1989,
Circulation.
[7]
V. Fuster,et al.
Deep arterial injury during experimental angioplasty: relation to a positive indium-111-labeled platelet scintigram, quantitative platelet deposition and mural thrombosis.
,
1986,
Journal of the American College of Cardiology.
[8]
T. Odlaug.
Laboratory anatomy of the fetal pig
,
1975
.