Objective To harvest pancreatic tissues from rats , prepare decellularized bio-derived pancreatic scaffolds ( DBPS) , and to examine the integrity and biocompatibility of the scaffolds .Methods Normal pancreases were harvested from healthy adult SD rats .DBPS was prepared by perfusing SDS and Triton X-100 through bile duct and the portal vein, respectively.After decellularization, normal pancreatic tissue and DBPS were compared via HE staining , and transmission electron microscopy ( TEM ) . Abdominal wall and subcutaneous implantations were used to compare biocompatibility , and the remain quantity of residual protein and growth factors were determined via enzyme linked immunosorbent assay(ELISA).MTT assay was used to test the scaffolds’ cytotoxicity.The scaffolds were co-cultured with endotheliocyte .Results HE staining and TEM study indicated no residual cells in the DBPS as well as preservation of the complete extracellular matrix .The remain quantity of residual protein and growth factors in ECM was high .The abdominal wall and subcutaneous implantation revealed that DBPS triggered a lower immune response as compared to the control group.MTT assay showed little cytotoxicity .Endotheliocyte assembled and growed with the scaffolds together .Conclusion DBPS are completely decellularized , and exhibit a higher level of biocompatibility in vivo.Using the way of vessels can make the integrity of extracellular matrix to be fully preserves and contain more growth factors .So using vessels way is better than bile duct .

With potent biological activities, cellular growth factors are polypeptide factors that primarily stimulate cell growth and proliferation. They participate in the regulation of not only normal physiological functions such as human embryonic development and cell growth, but also neurorehabilitation and neuroplasticity in pathological processes such as nerve injury and recovery. Specifically, cellular growth factors have been shown to promote neuron survival, facilitate nerve regeneration and regulate synaptic plasticity, promote cell differentiation/vascular regeneration and modulate the microenvironment, promote nerve fiber myelination and improve nerve conduction. This review summarized current knowledge on the roles and various growth factors in neurorehabilitation and neuroplasticity, providing an update on potential clinical application of cellular growth factors in the field of neural rehabilitation.