Decellularized tissues have been used as implantable materials for tissue regeneration because of their high biofunctionality. We have reported that high hydrostatic pressured (HHP) decellularized tissue developed in our laboratory exhibits good in vivo performance, but the details of the mechanism are still not known. Based on previous reports of bioactive factors called matrix bound nanovesicles (MBVs) within decellularized tissues, this study aims to investigate whether MBVs are also present in decellularized tissues prepared by HHP decellularization, which is different from the previously reported methods. In this study, we tried to extract bioactive factors from HHP decellularized brain and placenta, and evaluated their effects on nerves in vitro and in vivo, where its effects have been previously reported. The results confirmed that those factors can be extracted even if the decellularization method and tissue of origin differ, and that they have effects on a series of processes toward nerve regeneration, such as neurite outgrowth and nerve fiber repair.
Keywords: Decellularized tissue; extracted components; high hydrostatic pressure; nerve regeneration.
In this study, we evaluated the neuroregenerative effects of matrix-bounded nanovesicles extracted from decellularized tissue using a high hydrostatic pressure method. The results indicate that bioactive factors, including matrix-bounded nanovesicles, can be extracted regardless of the decellularization method and tissue origin.
© 2024 The Author(s). Published by National Institute for Materials Science in partnership with Taylor & Francis Group.