Fabrication of gelatin/chitosan nanofibrous scaffold: process optimization and empirical modeling

The optimum condition for electrospinning of gelatin/chitosan was introduced using the model obtained in this study. The HDF cells attached and spread well on the optimized nanofibrous scaffold. Electrospinning is a very useful technique for producing polymeric nanofibers by applying electrostatic forces. This study reports on the modeling and optimization of the electrospinning process of gelatin/chitosan, using response surface methodology. The individual and the interaction effects of the gelatin/chitosan blend ratio (50/50, 60/40 and 70/30), applied voltage (20, 25 and 30 kV) and feeding rate (0.2, 0.4 and 0.6 mL h−1) on the mean fiber diameter and standard deviation of the fiber diameter were investigated on optimization section, using scanning electron microscopy. To fabricate the nanofibrous gelatin/chitosan blend, trifluoroacetic acid/dichloromethane was selected as the solvent system. The model obtained for the mean fiber diameter has a quadratic relationship with applied voltage and feeding rate. The interaction between applied voltage and flow rate were found significant but the interactions of blend ratio and flow rate and also blend ratio and applied voltage were negligible. A quadratic relationship was obtained for applied voltage and flow rate with standard deviation of the fiber diameter and there was no interaction between the parameters in the model. The optimum condition for electrospinning of gelatin/chitosan was also introduced using the model obtained in this study. Scanning electron micrographs of human dermal fibroblast cells on the nanofibrous structures show good attachment and proliferation on the fabricated scaffold surface. Electrospun gelatin/chitosan nanofibrous mats have great potential for use as a scaffold for skin tissue engineering. © 2014 Society of Chemical Industry