Effects of hypercholesterolemia on healing of vascular grafts.

Small-diameter vascular grafts woven from bioresorbable lactide/glycolide copolymers have been successfully interposed into aortas of normal NZW rabbits. The current study examines the histologic and functional reactions to these bioresorbable grafts in severely hypercholesterolemic rabbits, a standard animal model of atherosclerosis. Sixty rabbits were placed on a 2% cholesterol, 6% peanut oil atherogenic diet. Baseline serum cholesterols and triglycerides were measured and repeated at operation 3 months later. Woven polyglactin 910 (PG910) grafts were interposed into infrarenal aortas. Fifty-two rabbits died on the diet or within 3 days of surgery and eight survived operation (normal NZW rabbit operative mortality is less than 10%). Cholesterol levels rose from 63 to 1989, p less than .001. Of the eight survivors, five died after 3 weeks, and one died after 2 1/2 months. Two were sacrificed at 2 and 4 months. Four aortic disruptions with retroperitoneal hematomas, one pseudoaneurysm, and one diffuse aneurysm were observed, greater than in normal rabbits, p less than .001. Inspection revealed severe atherosclerosis. Histologically, 3-week explants showed only small areas of neointima with myofibroblasts and endothelial cells; the outer capsules were infiltrated by lipid-laden macrophages. Graft material in 2- to 4-month explants was replaced by tissue with histologic atherosclerosis. More severe atherosclerosis was observed in native aortas at the perianastomotic areas than the more distant aortic segments. Abundant intracellular lipid was seen also in splenic histiocytes and hepatic cells with evidence of micronodular cirrhosis. Macrophages phagocytizing bioresorbable prostheses may release growth factors mediating the formation of a cellular tissue conduit. Severe hypercholesterolemia may alter monokine release from macrophages resulting in a weakened prosthesis/tissue complex.

[1]  H. Greisler,et al.  The effects of an atherogenic diet on macrophage/biomaterial interactions. , 1991, Journal of vascular surgery.

[2]  H. Greisler The role of the macrophage in intimal hyperplasia , 1989 .

[3]  B. Gewertz Derivation of neointima in vascular grafts: Greisler HP, Dennis JW, Endean, ED, Ellinger J, Buttle KF, Kim DU, Circulation 1988;78:16-12 , 1989 .

[4]  H. Greisler,et al.  Macrophage/biomaterial interactions: the stimulation of endothelialization. , 1989, Journal of vascular surgery.

[5]  K. Buttle,et al.  Polyglactin 910/polydioxanone bicomponent totally resorbable vascular prostheses. , 1988, Journal of vascular surgery.

[6]  H P Greisler,et al.  Arterial regeneration over polydioxanone prostheses in the rabbit. , 1987, Archives of surgery.

[7]  B. van der Lei,et al.  Long-term biologic fate of neoarteries regenerated in microporous, compliant, biodegradable, small-caliber vascular grafts in rats. , 1987, Surgery.

[8]  R. Kempczinski Arterial wall regeneration in small-caliber vascular grafts in rats , 1986 .

[9]  K. Schrör,et al.  Arterial wall regeneration in small-caliber vascular grafts in rats. Neoendothelial healing and prostacyclin production. , 1985, The Journal of thoracic and cardiovascular surgery.

[10]  J. B. Price,et al.  Arterial regenerative activity after prosthetic implantation. , 1985, Archives of surgery.

[11]  H P Greisler,et al.  Arterial regeneration over absorbable prostheses. , 1982, Archives of surgery.

[12]  S. Bowald,et al.  Arterial regeneration following polyglactin 910 suture mesh grafting. , 1979, Surgery.

[13]  P. Richardson,et al.  Coated bioresorbable mesh as vascular graft material. , 1985, Transactions - American Society for Artificial Internal Organs.

[14]  S. Bowald,et al.  Polyglactin mesh grafting of the pig aorta. The two-year follow-up in an experimental animal. , 1980, Acta chirurgica Scandinavica.

[15]  S. Bowald,et al.  Absorbable material in vascular prostheses: a new device. , 1980, Acta chirurgica Scandinavica.