Decellularized extracellular matrix (dECM) has been widely used as a scaffold for regenerative medicine due to its high biomimetic and excellent biocompatibility. As a functional polymer material with high water content and controlled fluidity, hydrogel is very promising for some minimally invasive surgery in clinical practice. In recent years, with the rapid development of hydrogel theory and technology, dECM hydrogel has gradually become a research hotspot in the field of regenerative medicine. In this paper, the related researches in recent years are reviewed regarding the preparation of dECM hydrogel and its preclinical application. The future clinical use is also prospected.
Peripheral nerve injury (PNI) is a common neurological dysfunction. In clinical practice, autologous nerve transplantation is used to solve problems related to PNI, such as limited donor resources, neuroma formation and high donor incidence rate. Therefore, searching for new nerve regeneration materials has become a hot research topic. The decellularized extracellular matrix (dECM) hydrogel provides a scaffold for nerve regeneration by removing the cellular components in biological tissues, preserving the extracellular matrix, and is a potential therapeutic material for nerve regeneration. This article reviews the research progress of dECM hydrogel for PNI and looks forward to the clinical prospects of this research direction.
ObjectiveTo review the application of cell derived decellularized extracellular matrix (CDM) in tissue engineering. Methods The literature related to the application of CDM in tissue engineering was extensively reviewed and analyzed. Results CDM is a mixture of cells and their secretory products obtained by culturing cells in vitro for a period of time, and then the mixture is treated by decellularization. Compared with tissue derived decellularized extracellular matrix (TDM), CDM can screen and utilize pathogen-free autologous cells, effectively avoiding the possible shortcomings of TDM, such as immune response and limited sources. In addition, by selecting the cell source, controlling the culture conditions, and selecting the template scaffold, the composition, structure, and mechanical properties of the scaffold can be controlled to obtain the desired scaffold. CDM retains the components and microstructure of extracellular matrix and has excellent biological functions, so it has become the focus of tissue engineering scaffolds. ConclusionCDM is superior in the field of tissue engineering because of its outstanding adjustability, safety, and high bioactivity. With the continuous progress of technology, CDM stents suitable for clinical use are expected to continue to emerge.