The use of absorbable sutures in laser-assisted microvascular anastomoses.

The efficacy of the laser in performing microvascular anastomoses has been well established in the laboratory using a number of wavelengths. These studies have concluded that laser-assisted microvascular anastomoses are at least comparable to, if not superior to, ordinary suture techniques. The advantages have been the diminished foreign body reaction that occurs as a consequence of using only a few stay sutures to hold the vessels in approximation while the laser bonding is performed, as well as the rapidity of the surgery. We have already shown that absorbable sutures (polyglactin 910) are as efficacious as standard nonabsorbable sutures (nylon) in both arterial and venous microanastomoses. The current study was undertaken to see if the foreign body reaction could be diminished even further by the use of absorbable 10.0 sutures and compare these findings to laser-assisted microvascular anastomoses performed with nonabsorbable sutures. The carbon dioxide milliwatt laser was used to perform laser-assisted microvascular anastomoses in rat femoral arteries and veins. Patency rates and histological response were compared at intervals of 3 days and 1, 2, 4, 8, and 12 weeks postoperatively. Both arterial and venous patency rates were comparable (overall absorbable, 91.2%-52/57; overall nonabsorbable, 87.7%-50/57), as was the degree of inflammation and fibrosis. We conclude that absorbable sutures can be used for laser-assisted microvascular anastomoses and have the potential of allowing healing to occur without any foreign material within the surgical site.

The efficacy of absorbable suture for microvascular anastomoses.

Although microvascular anastomoses are routinely performed with nonabsorbable sutures, a foreign body reaction can be stimulated that acts as a nidus for inflammation, infection, and possible thrombosis. Absorbable sutures should be able to diminish this reaction. There are sparse data describing the use of absorbable sutures for both arterial and venous anastomoses. This investigation compares standard microvascular anastomotic technique using nonabsorbable 10-0 sutures (nylon) with absorbable 10-0 sutures (polyglactin 910), using a previously reported tubed superficial epigastric flap model in rats. Patency rates and histologic responses are compared at intervals of 3 days and 1, 2, 8 and 12 weeks postoperatively. Arterial and venous patency rates were similar for both materials (overall nonabsorbable, 85.9%; overall absorbable, 84.4%). A somewhat increased inflammatory response was noted in the arterial absorbable group at 1 week and in both the venous and arterial nonabsorbable groups at 8 and 12 weeks postoperatively. The later finding most probably represents the continued presence of the nylon sutures. The incidence of intraluminal thrombosis was greater for nonabsorbable suture, occurring in two arterial and four venous anastomoses, compared with only one absorbable suture venous anastomosis. We conclude that nonabsorbable suture is as efficacious as standard absorbable material in both arterial and venous microanastomoses with the potential benefit of diminished foreign body reaction.