Electrospun Silk Fibroin Mats for Tissue Engineering

Abstract

AbstractProcessing Silk Fibroin (SF) with electrospinning (ES) offers a very attractive opportunity for producing a variety of 2D and 3D matrices with great potential for tissue regeneration and repair due to the superior biocompatibility and mechanical properties of SF. Different combinations of ES parameters were explored to investigate the best experimental set‐up related to the dimension and uniformity of the fibers in the electrospun silk fibroin (ES‐SF) mats. Using SEM it was found that the ES‐SF mats contain uniform fibers with a diameter in the nanometric range obtained by electrospinning a 7.5 % w/v SF solution in formic acid, with an electric field of 2.4 kV/cm and a spinneret‐collector distance of 10 cm. FT‐IR and DSC analyses were performed to investigate the structure of the ES‐SF mats before and after immersion in methanol for different times (5, 10, and 15 min). The methanol treatment was able to promote the crystallization of SF by conformational transition of random coil and other poorly ordered conformations (turns and bends) to the β‐sheet structure. The degree of crystallinity was enhanced as shown by the trend of both the FT‐IR crystallinity index and the melting/decomposition peak temperature (from DSC). To study the cytocompatibility of ES‐SF mats, tests with L929 murine fibroblasts were carried out. Samples were seeded with the cells and incubated for 1, 3, and 7 days at 37 °C. At each time point, SEM investigations and Alamar blue tests were performed. The SEM images showed cell adhesion and proliferation just after 1 day and cell confluence at 7 days. Alamar blue test demonstrated that there were very low differences between cell viability on ES‐SF mats and the tissue culture plastic control.