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Information × Registration Number 0226U001992, (0124U004360) , R & D reports Title Hybrid three-dimensional membranes with MXene for tissue engineering popup.stage_title Іn vitro дослідження біосумісності нових нановолокнистих 3D мембран на основі MXene Head Pogrebnjak Alexander D., д.ф.-м.н. Registration Date 04-02-2026 Organization Sumy State University popup.description1 The main goal of the project is to investigate the properties of new electrically conductive and biocompatible three-dimensional hybrid polymer nanofibrous membranes modified by MXenes, which mimic the natural electrical properties of living tissues, and to establish the possibility of their use for nerve tissue regeneration popup.description2 The project “Hybrid Three-Dimensional MXene-Based Scaffolds for Tissue Engineering” aims to address critical challenges in regenerative medicine through the development of innovative materials for nerve tissue regeneration. The relevance of this research is driven by the high incidence of peripheral nerve injuries, which significantly affect patients’ quality of life and require substantial medical resources for treatment. The core concept of the project is the development of biocompatible and electrically conductive three-dimensional polymer membranes modified with MXenes, combining unique properties that promote cellular growth and tissue regeneration. The primary objective of the project is to develop novel biomaterials that mimic the electrical properties of living tissues, with a particular focus on applications in nerve tissue regeneration. The main tasks include the synthesis of MXenes, the development of three-dimensional matrices with optimized structural and mechanical properties, plasma-based surface modification of membranes to enhance their antibacterial performance, and a comprehensive evaluation of the biocompatibility of the developed materials. The project hypothesis is based on the assumption that the integration of MXenes into the scsffold structure will significantly improve their electrical conductivity and biological performance, thereby enabling more efficient nerve tissue regeneration. The proposed project represents a substantial contribution to modern regenerative medicine by combining scientific innovation with strong practical relevance Product Description popup.authors Maksym V. Pogorielov Alexander D. Pogrebnjak Oksana S. Pogorelova Katerina V. Smyrnova Viktoriia S. Kazban Viktor S. Kulibaba popup.nrat_date 2026-02-04 Close