Hydrogels can be one of the best polymeric wound dressings due to the desirable properties of wound healing. In this study, emphasizing the use of natural biomaterials such as Aloe vera and honey in the structure of cross-linked polymers, a novel hydrogel was produced that might be applied to healing wounds.In the beginning, four hydrogel groups were made from a combination of Sodium Alginate and Chitosan with Aloe vera extract and honey in optimum concentrations. Then the structure of those was evaluated by SEM and FTIR. After confirming hydrogels' structural properties, their physical properties, including swelling, porosity, density, mass loss, stability, and WVTR, were examined. Besides, the hydrogel biocompatibility was assessed by analyzing the cell viability and hemolytic activity. Adhesion of the cells to the hydrogel was also observed by SEM imaging. The results showed that the designed hydrogel has a porous structure with interconnected cavities, which their size can provide suitable conditions for cell adhesion, migration, and proliferation. Also, their physical and structural properties can be a strong suit to wound healing. Although honey's application can weaken the hydrogel structure, honey has beneficial properties due to its complex biomolecules. In contrast, Aloe vera in hydrogel generally improved the hydrogel's specificity for wound healing. According to the results of this study, taking advantage of hydrogels containing honey and Aloe vera based on alginate and chitosan polymers led to the formation of an acceptable structure and biocompatibility that can be used in future researches to repair tissues, especially wounds.
A combination of bioceramics and nanofibrous scaffolds holds promising potential for inducing of mineralization in connective tissues. The aim of the present study was to investigate the attachment, proliferation and odontogenic differentiation of dental pulp stem cells (DPSC) on poly(L-lactide) (PLLA) nanofibers coated with mineral trioxide aggregate (MTA). Polymeric scaffolds were fabricated via the electrospinning method and their surface was coated with MTA. DPSC were isolated from dental pulp and their biological behavior was evaluated on scaffolds and the control group using MTT assay. Alkaline phosphatase (ALP) activity, biomineralization and the expression of odontogenic genes were analyzed during odontogenic differentiation. Isolated DPSC showed spindle-shaped morphology with multi-lineage differentiation potential and were positive for CD73, CD90 and CD105. MTA-coated PLLA (PLLA/MTA) exhibited nanofibrous structure with average fiber diameter of 756 ± 157 nm and interconnected pores and also suitable mechanical properties. Similar to MTA, these scaffolds were shown to be biocompatible and to support the attachment and proliferation of DPSC. ALP activity transiently peaked on day 14 and was significantly higher in PLLA/MTA scaffolds than in the control groups. In addition, increasing biomineralization was observed in all groups with a higher amount in PLLA/MTA. Odontogenic-related genes, DSPP and collagen type I showed a higher expression in PLLA/MTA on days 21 and 14, respectively. Taken together, MTA/PLLA electrospun nanofibers enhanced the odontogenic differentiation of DPSC and showed the desired characteristics of a pulp capping material.
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