Endothelial seeding of Dacron and polytetrafluoroethylene grafts: the cellular events of healing.

To detect cellular differences in the healing of polytetrafluoroethylene (e-PTFE) and Dacron grafts up to 7 months after implantation, we studied 108 aortic graft interpositions in dogs. Each prosthesis was alternately prepared by endothelial seeding or by an unseeded control method. The grafts were perfusion fixed and studied with light, scanning, and transmission electron microscopy at intervals from before to 221 days after implantation. Seeding resulted in the development of an extensive endothelial flow surface in two out of three of the e-PTFE and none out of four of the Dacron grafts by 10 days after implantation (p = 0.053). After 30 days a microfibrillar subendothelial matrix ranging from 5 to 11 mu formed in all but three grafts with endothelial coverage. The inner capsule of mature Dacron grafts was significantly thicker (169 +/- 143 mu) than in e-PTFE grafts (22 +/- 32 mu; p = 0.002). Seeded and unseeded Dacron grafts had predominantly fibroblasts in the outer capsule of the graft by 10 days. Surface endothelium, vasa vasorum, fibroblasts, and myointimal cells appeared in the inner capsule between 10 and 30 days after implantation. In Dacron grafts, fibroblasts and myointimal cells predominated in the inner capsule at 30 days, with smooth muscle cells not being definitely identifiable until after 150 days. Neither fibroblasts nor myointimal cells were common (present but sparse in one of four e-PTFE grafts) at 30 days, and transmural vasa vasorum were never seen. The seeded endothelial cells migrated rapidly from the sites of initial adhesion near the e-PTFE onto the flow surface. Only one of four of the unseeded e-PTFE grafts had surface endothelium after 30 days, and only moderate coverage developed during 180 days. We conclude that endothelial healing is more rapid in seeded e-PTFE grafts than in seeded Dacron grafts and occurs by a different mechanism.

[1]  J. Glover,et al.  The quantitation of cultured cellular surface coverage: applications for transparent and opaque surfaces. , 1984, Journal of biomedical materials research.

[2]  R. Dilley,et al.  The peroxidase antiperoxidase staining of factor VIII-related antigen on cultured endothelial cells. , 1984, Journal of biomedical materials research.

[3]  J. Glover,et al.  Seeding human arterial prostheses with mechanically derived endothelium. The detrimental effect of smoking. , 1984, Journal of vascular surgery.

[4]  S. Schmidt,et al.  Controlled flow studies in 4 mm endothelialized dacron grafts. , 1983, Transactions - American Society for Artificial Internal Organs.

[5]  H. Gritsman,et al.  The biochemical mechanisms of shear-induced platelet aggregation. , 1983, Transactions - American Society for Artificial Internal Organs.

[6]  D. W. Vinter,et al.  Enhanced patency of small-diameter, externally supported Dacron iliofemoral grafts seeded with endothelial cells. , 1982, Surgery.

[7]  N. Rich,et al.  Early normalization of platelet survival by endothelial seeding of Dacron arterial prostheses in dogs. , 1982, Surgery.

[8]  D. W. Vinter,et al.  Expanded polytetrafluoroethylene vascular prostheses seeded with enzymatically derived and cultured canine endothelial cells. , 1982, Surgery.

[9]  D. W. Vinter,et al.  Sequential studies of healing in endothelial seeded vascular prostheses: histologic and ultrastructure characteristics of graft incorporation. , 1981, The Journal of surgical research.

[10]  D. W. Vinter,et al.  Immediate seeding of enzymatically derived endothelium in Dacron vascular grafts. Early experimental studies with autologous canine cells. , 1980, Archives of surgery.

[11]  R. Dilley,et al.  The effects of crimping on the healing of prosthetic arterial grafts. , 1980, The Journal of cardiovascular surgery.

[12]  R. Dilley,et al.  Endothelium lined arterial prostheses: a single-staged preparation. , 1980, The Journal of the Indiana State Medical Association.

[13]  R. Dilley,et al.  Immunofluorescent staining for factor VIII-related antigen: a tool for study of healing in vascular prostheses. , 1979, The Journal of surgical research.

[14]  J. Glover,et al.  Seeding endothelium onto canine arterial prostheses. The effects of graft design. , 1979, Archives of surgery.

[15]  J. Glover,et al.  A single-staged technique for seeding vascular grafts with autogenous endothelium. , 1978, Surgery.

[16]  D. Ausprunk,et al.  Spreading of vascular endothelial cells in culture: spatial reorganization of cytoplasmic fibers and organelles. , 1978, Tissue & cell.

[17]  Karnovsky Mj,et al.  Endothelial regeneration in the rat carotid artery and the significance of endothelial denudation in the pathogenesis of myointimal thickening. , 1975 .

[18]  J. C. Smith,et al.  Interspecies healing of porous arterial prostheses: observations, 1960 to 1974. , 1974, Archives of surgery.

[19]  L. Sauvage,et al.  Healing of Arterial Prostheses in Man: Its Incompleteness , 1972, Annals of surgery.