Animal Experiments on an Antithrombogenic Small-Caliber Vascular Prostheses and Vascualr Patch: Observation in Canine Models.
- Author:
Soo Cheol KIM
1
;
Won Gon KIM
;
Seh Young YOO
Author Information
1. Department of Thoracic and Cardiovascular Surgery, Sejong General Hospital, Korea.
- Publication Type:Original Article
- Keywords:
Blood vessel prosthesis;
Prosthesis;
Patch
- MeSH:
Anesthesia;
Animal Experimentation*;
Animals*;
Arteries;
Blood Vessel Prosthesis*;
Dogs;
Endothelial Cells;
Femoral Artery;
Glass;
Groin;
Halothane;
Intubation, Intratracheal;
Lower Extremity;
Lung;
Microscopy, Electron, Scanning;
Microvilli;
Oxygen;
Phenobarbital;
Polypropylenes;
Porosity;
Prostheses and Implants;
Sutures;
Transplants;
Ventilators, Mechanical
- From:The Korean Journal of Thoracic and Cardiovascular Surgery
2003;36(2):63-72
- CountryRepublic of Korea
- Language:Korean
-
Abstract:
BACKGROUND: Although a variety of synthetic vascular grafts are available in modern vascular surgery, no ideal prosthesis has yet been developed. Small-caliber vascular grafts with low flow, as used in the lower extremity, continue to become thrombosed at unacceptable rates. We have developed and evaluated the new antithrombogenic blood contacting surfaces in canine model. MATERIAL AND METHOD: Two new antithrombogenic blood contacting surfaces(Polyvinylalcohol-Polyurethane(PVA-PU) blend and natural Graphite-Polyurethane(G-PU) blend) have been developed and evaluated in canine model, using vascular grafts and patches. The luminal surfaces of the test vascular grafts(5 mm ID) were fabricated by dipping a glass rod in PVA-PU blend solution(50 % PVA) using phaseseparation method. Mongrel dogs of either sex weighing 18-22 kg were anesthetized by endotracheal intubation using halothane and their lungs were ventilated with a volume-cycled ventilator. Maintenance anesthesia with 0.5-1.0% halothane and supplemental oxygen was used. Two pairs were used for comparison in the bilateral femoral arteries for both vascular grafts(PVA-PU vs. PU) and vascular patches(G-PU vs. PU). Bilateral groin incisions were made and the arteries were exposed and clamped. After an excision of 1 cm of the artery between clamps, a graft of 2.5 cm in length was implanted end-to-end using 6-0 polypropylene suture. The vascular patch was implanted as a form of on-lay patch. Animals were sacrificed at 1, 2, 4, 6, 8 and 16 weeks for vascular grafts and 1, 2, 4 and 6 weeks for vascular patches. RESULT: The vascular grafts of PVA-PU blends showed patent lumina in the 2 and 16 weeks animals, while those of PU showed a patent lumen in 2 weeks animal. PVA-PU graft of 16 weeks showed a fairly clean luminal surface. A light microscopic finding of this graft demonstrated good tissue infiltration through porosity. The animals with vascular patches showed patent arteries in both groups except 2 weeks animal. Scanning electron microscopy of the luminal surfaces of G-PU patches in 4 and 6 weeks animals showed endothelial cell covering with microvilli. PU patches showed qualitatively less endothelial cell covering. CONCLUSION:In conclusion, PVA-PU and G-PU blends can be a promising blood contacting surfaces for application in a synthetic vascualr graft. However,further animal study is needed to determine the real long-term effects of these methods of surface modifications.
