Xenogeneic extracellular matrix grafts elicit a TH2-restricted immune response.

BACKGROUND: Porcine small intestinal submucosa (SIS) is an acellular, naturally derived extracellular matrix (ECM) that has been used for tissue remodeling and repair in numerous xenotransplantations. Although a vigorous immune response to xenogeneic extracellular matrix biomaterials is expected, to date there has been evidence for only normal tissue regeneration without any accompanying rejection. The purpose of this study was to determine the reason for a lack of rejection. METHODS: Mice were implanted s.c. with xenogeneic tissue, syngeneic tissue, or SIS, and the graft site analyzed histologically for rejection or acceptance. Additionally, graft site cytokine levels were determined by reverse transcriptase polymerase chain reaction and SIS-specific serum antibody isotype levels were determined by ELISA. RESULTS: Xenogeneically implanted mice showed an acute inflammatory response followed by chronic inflammation and ultimately graft necrosis, consistent with rejection. Syngeneically or SIS implanted mice, however, showed an acute inflammatory response that diminished such that the graft ultimately became indistinguishable from native tissue, observations that are consistent with graft acceptance. Graft site cytokine analysis showed an increase in interleukin-4 and an absence of interferon-gamma. In addition, mice implanted with SIS produced a SIS-specific antibody response that was restricted to the IgG1 isotype. Reimplantation of SIS into mice led to a secondary anti-SIS antibody response that was still restricted to IgG1. Similar results were observed with porcine submucosa derived from urinary bladder. To determine if the observed immune responses were T cell dependent, T cell KO mice were implanted with SIS. These mice expressed neither interleukin-4 at the implant site nor anti-SIS-specific serum antibodies but they did accept the SIS graft. CONCLUSIONS: Porcine extracellular matrix elicits an immune response that is predominately Th2-like, consistent with a remodeling reaction rather than rejection.

Galalpha(1,3)Gal epitope in porcine small intestinal submucosa.

Small intestinal submucosa (SIS) is a naturally occurring, acellular biomaterial derived from porcine jejunum, which promotes constructive tissue remodeling when applied as a xenogeneic graft material. Galactosyl-alpha(1,3)galactose (Gal) is a cell-associated epitope responsible for hyperacute rejection of porcine whole-organ xenografts in primates. Because SIS is harvested from porcine tissue, it may contain the Gal epitope. The goals of this study were to determine if Gal is present in SIS and, if it is present, to determine if human serum complement can be activated in vitro following exposure to porcine-derived SIS. SIS was probed for Gal by immunohistochemical methods and by lectin-peroxidase staining. SIS stained strongly positive with human serum, which contains naturally occurring antibodies to Gal, followed by anti-immunoglobulin G (IgG) or anti-IgM peroxidase conjugate. Blocking with the lectin I-B(4), which is specific for the Gal epitope, decreased the intensity of staining. Exposure of SIS to alpha-galactosidase reduced staining to negligible amounts. The Gal epitope is distributed transmurally throughout the SIS material. Subtyping of the immunoglobulins that bind to SIS showed that IgG(2) is the major immunoglobulin of human plasma that binds to SIS. SIS did not activate complement in vitro as measured by radioimmunoassay for C3a.

Grafting of PEO to glass, nitinol, and pyrolytic carbon surfaces by gamma irradiation.

Glass, nitinol, and pyrolytic carbon surfaces were grafted with poly (ethylene oxide) (PEO) and PEO-containing Pluronic surfactants by gamma irradiation. These substrates were coated with a primer layer of trichlorovinylsilane (TCVS), which allows grafting of organic polymers. The TCVS-coated substrates were adsorbed with PEO or Pluronics and exposed to 0.3 Mrad of gamma radiation to graft the polymer to the surface. PEO-grafted substrates were characterized by contact angle measurement, X-ray photoelectron spectroscopy, fibrinogen adsorption, and platelet adhesion and activation. Surface modification with PEO reduced fibrinogen adsorption by as much as 99%. Platelet adhesion was significnatly reduced or prevented on the modified surfaces. Protein- and platelet-resistance effects were independent of hydrophilicity of the PEO-grafted surfaces. Polymer grafting by gamma radiation to TCVS-coated substrates provides a facile process to improve thromboresistance of inorganic biomaterials.