Natural biomaterials are crucial in ocular tissue engineering because they allow cells to proliferate, differentiate, and stratify while maintaining the typical epithelial phenotype. In this study, membranes as dressings were formed from silk fibroin and collagen (Co) extracted from fish skin and then modified with carbodiimide chemical cross linker in different concentrations. The samples were evaluated by different analyses such as structural, physical (optical, swelling, denaturation temperature, degradation), mechanical, and biological (viability, cell adhesion, immunocytochemistry) assays. The results showed that all membranes have excellent transparency, especially with higher silk fibroin content. Increasing the cross linker concentration and the ratio of silk fibroin to Co increased the denaturation temperature and mechanical strength and, conversely, reduced the degradation rate and cell adhesion. The samples did not show a significant difference in toxicity with increasing cross linker and silk fibroin ratio. In general, samples with a low silk fibroin ratio combined with cross linker can provide desirable properties as a membrane for corneal wound healing.carbodiimide cross linker, cornea wound healing, fish collagen, properties studies, silk fibroin
Key Messages• natural biomaterials such as collagen extracted from fish skin and silk fibroin can well be used as dressings to heal wounds
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Currently, mesenchymal stem/stromal cells (MSCs) have attracted growing attention in the context of cell-based therapy in regenerative medicine. Following the first successful procurement of human MSCs from bone marrow (BM), these cells isolation has been conducted from various origins, in particular, the umbilical cord (UC). Umbilical cord-derived mesenchymal stem/stromal cells (UC-MSCs) can be acquired by a non-invasive plan and simply cultured, and thereby signifies their superiority over MSCs derived from other sources for medical purposes. Due to their unique attributes, including self-renewal, multipotency, and accessibility concomitant with their immunosuppressive competence and lower ethical concerns, UC-MSCs therapy is described as encouraging therapeutic options in cell-based therapies. Regardless of their unique aptitude to adjust inflammatory response during tissue recovery and delivering solid milieu for tissue restoration, UC-MSCs can be differentiated into a diverse spectrum of adult cells (e.g., osteoblast, chondrocyte, type II alveolar, hepatocyte, and cardiomyocyte). Interestingly, they demonstrate a prolonged survival and longer telomeres compared with MSCs derived from other sources, suggesting that UC-MSCs are desired source to use in regenerative medicine. In the present review, we deliver a brief review of UC-MSCs isolation, expansion concomitantly with immunosuppressive activities, and try to collect and discuss recent pre-clinical and clinical researches based on the use of UC-MSCs in regenerative medicine, focusing on with special focus on in vivo researches.
Biological matrices can be modified with cross‐linkers to improve some of their characteristics as scaffolds for tissue engineering. In this study, chemical cross‐linker 1‐Ethyl‐3‐(3‐dimethylaminopropyl) carbodiimide (EDC) was used with different ratios (5, 10, 20, 30, and 40 mM) to improve properties such as mechanical strength, denaturation temperature, and degradability of the acellular fish skin as a biological scaffold for tissue engineering applications. Morphological analysis showed that the use of cross‐linker at low concentrations had no effect on the structure and textiles of the scaffold, while increasing mechanical strength, denaturation temperature, and degradation time. Cytotoxicity and cellular studies showed that the optimal cross‐linker concentration did not significantly affect cell viability as well as cell adhesion. In general, utilising the carbodiimide cross‐linker with the optimal ratio can improve the characteristics and function of the biological tissues such as acellular fish skin.
The decellularization of plant tissues can be one of the design options of scaffolds in tissue engineering. Chemical detergents such as Triton X‐100 and sodium dodecyl sulfate (SDS) in different concentrations were used to decellularize olive leaves as an acellular plant matrix for tissue engineering. The samples were investigated by different analyses such as Hematoxylin and Eosin staining, SEM, tensile strength, swelling, water vapor transmission, and toxicity. The results of staining and toxicity tests showed that the Triton X‐100 decellularized samples at a concentration of 0.1% had the best morphology and the lowest toxicity. Mechanical results showed that the elasticity modulus of acellular samples was significantly reduced compared to normal leaf samples. While swelling rate and water vapor transmission in acellular samples compared to the control sample doubled and tripled, respectively. In general, acellular olive leaf can be suggested as a scaffold for tissue engineering applications.
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