Xeno-immunogenicity of ice-free cryopreserved porcine leaflets.

BACKGROUND: Undesirable processes of inflammation, calcification, or immune-mediated reactions are limiting factors in long-term survival of heart valves in patients. In this study, we target the modulatory effects of ice-free cryopreservation (IFC) of xenogeneic heart valve leaflet matrices, without decellularization, on the adaptive human immune responses in vitro. METHODS: We tested porcine leaflet matrices from fresh untreated, conventionally cryopreserved (CFC), and IFC pulmonary valves by culturing them with human blood mononuclear cells for 5 d in vitro. No other tissue treatment protocols to modify possible immune responses were used. Matrices alone or in addition with a low-dose second stimulus were analyzed for induction of proliferation and cytokine release by flow cytometry-based techniques. Evaluation of the α-Gal epitope expression was performed by immunohistochemistry with fluorochrome-labeled B4 isolectin. RESULTS: None of the tested leaflet treatment groups directly triggered the proliferation of immune cells. But when tested in combination with a second trigger by anti-CD3, IFC valves showed significantly reduced proliferation of T cells, especially effector memory T cells, in comparison with fresh or CFC tissue. Moreover, the cytokine levels for interferon-γ (IFNγ), tumor necrosis factor α, and interleukin-10 were reduced for the IFC-treated group being significantly different compared with the CFC group. However, no difference between treatment groups in the expression of the α-Gal antigen was observed. CONCLUSIONS: IFC of xenogeneic tissue might be an appropriate treatment method or processing step to prevent responses of the adaptive immune system.

Absence of immune responses with xenogeneic collagen and elastin.

Novel tissue-engineering approaches for cardiovascular matrices based on xenogeneic extracellular matrix protein (ECMp) constituents require a detailed evaluation of their interaction with essential immune cell subsets playing a role in innate or adaptive immunity. Therefore, in this study, the effects of xenogeneic (porcine, bovine) collagen type I and elastin as the two main components of the heart valve ECM were analyzed in comparison to their human equivalents. First, their potential to induce maturation and cytokine secretion of human dendritic cells (DC) was tested by flow cytometry. Second, the influence on proliferation and cytokine release of purified human B and T cells was measured. We could demonstrate that xenogeneic collagen type I and elastin are not able to trigger the maturation of DC as verified by the lack of CD83 induction accompanied by a low tumor necrosis factor-α release. Moreover, both ECMp showed no effect on the proliferation and the interleukin-6 release of either unstimulated or prestimulated B cells. Additionally, anti-CD3-induced purified T cell proliferation and secretion of cytokines was not affected. All in vitro data verify the low immunogenicity of porcine and bovine collagen type I and elastin and favor their suitability for tissue-engineered scaffolds.

Engineering of fibrillar decorin matrices for a tissue-engineered trachea.

Decorin is a structural and functional proteoglycan (PG) residing in the complex network of extracellular matrix (ECM) proteins in many connective tissues. Depending on the protein core and the glycosaminoglycan chain, PGs support cell adhesion, migration, proliferation, differentiation, ECM assembly and growth factor binding. For applications in tissue engineering, it is crucial to develop reliable, ECM-mimicking biomaterials. Electrospinning is a suitable method for creating three-dimensional (3D), fibrillar scaffolds. While there are numerous reports on the electrospinning of proteins including collagen, to date, there are no reports on the electrospinning of PGs. In the following study, we used electrospinning to generate decorin-containing matrices for tracheal tissue engineering applications. The electrospun scaffolds were analyzed using scanning electron microscopy, atomic force microscopy, contact angle measurements and dynamic mechanical analysis. Additionally, we confirmed PG functionality with immunostaining and 1,9-dimethylmethylene blue. To determine cell-matrix-interactions, tracheal cells (hPAECs) were seeded and analyzed using an FOXJ1-antibody. Moreover, interactions of the electrospun scaffolds with immune-mediated mechanisms were analyzed in detail. To conclude, we demonstrated the feasibility of electrospinning of decorin to generate functional 3D scaffolds with low immunogenicity for hPAEC expansion. Our data suggest that these hybrid materials may be suitable as a substrate for tracheal tissue engineering.

Human immune responses to porcine xenogeneic matrices and their extracellular matrix constituents in vitro.

Several tissue engineering approaches for the treatment of cardiovascular diseases are based on a xenogeneic extracellular matrix. However, the application of engineered heart valves has failed in some patients, causing severe signs of inflammation by so far undetermined processes. Therefore we investigated the immune-mediated responses to porcine valve matrices (native, decellularized and glutaraldehyde-fixed) and to purified xenogeneic extracellular matrix proteins (ECMp). The induction of human immune responses in vitro was evaluated by analyzing the co-stimulatory effects of matrices and ECMp collagen and elastin on the proliferation of immune cell sub-populations via CFSE-based proliferation assays. The pattern of cytokine release was also determined. In porcine matrix punches we demonstrated strong immune responses with the native as well as the decellularized type, in contrast to attenuated effects with glutaraldehyde-fixed matrices. Furthermore, our results indicate that collagen type I (porcine and human) and human elastin were able to elicit proliferation in co-stimulation with anti-CD3 antibody, accompanied by a strong release of Th1 cytokines (IFN-gamma, TNF-alpha). In contrast, porcine elastin did not elicit any response at all. This low immunogenic potential of porcine elastin suggests its suitability for the creation of new tissue engineering heart valve scaffolds in the future.