Use of gum arabic to improve the fabrication of chitosan-gelatin-based nanofibers for tissue engineering.

Current techniques for fabricating chitosan-gelatin-based nanofibers require the use of corrosive and expensive solvents. Our novel method, however, using gum arabic and a mild (20 wt%) aqueous acetic acid solution as solvent can produce a solution with much higher chitosan-gelatin content (16 wt%). Without gum arabic, which greatly decreases the viscosity of the solution, such an outcome was unachievable. The solution was utilized to prepare electrospun chitosan-gelatin-polyvinyl alcohol-gum arabic nanofibers with a weight ratio of 8:8:2:0.5 (C8G8P2A0.5 nanofibers), in which polyvinyl alcohol could stabilize the electrospinning process. The stability and tensile strength (2.53 MPa) of C8G8P2A0.5 nanofibers (mats) were enhanced by glutaraldehyde crosslinking. Furthermore, mesenchymal stem cells attached and proliferated well on the mat. The strength-enhanced and cytocompatible C8G8P2A0.5 mats are thereby suitable for tissue engineering applications. More importantly, we have created a less expensive and safer method (one not using hazardous solvents) to fabricate chitosan-gelatin-based nanofibers.

Chitosan/pectin/gum Arabic polyelectrolyte complex: process-dependent appearance, microstructure analysis and its application.

Novel chitosan/pectin/gum Arabic polyelectrolyte complex (PEC) solutions and membranes with various compositions were prepared for biomedical applications. The appearance of the PEC solutions, either clear or turbid, was process-dependent and depended on how the three components were dissolved and mixed. The addition of gum Arabic to the chitosan and pectin significantly decreased the viscosities of the resultant PEC solutions due to the formation of globe-like microstructures that was accompanied by network-like microstructures and other molecular entanglements. The mechanical strength and hydrophilicity of the PEC membranes manufactured from the PEC solutions, especially for a weight ratio of 84/8/8 (chitosan/pectin/gum Arabic), were enhanced compared to pure chitosan membranes. Moreover, the use of the 84/8/8 PEC membranes as a drug carrier exhibited steady and fairly complete release of a drug (insulin) for 6h. Based on these promising results, the chitosan/pectin/gum Arabic PEC membranes have great potential in controlled drug release applications.

Use of dicarboxylic acids to improve and diversify the material properties of porous chitosan membranes.

Several nontoxic dicarboxylic acid solutions (oxalic acid, succinic acid, malic acid, and adipic acid solutions) instead of an acetic acid solution were used as solvents for chitosan dissolution. The amount of free amino groups of the chitosan in the solution decreased due to the ionic cross-linking of the dicarboxylic acids with chitosan. These solutions were used to fabricate porous chitosan membranes. Replacing acetic acid with these dicarboxylic acids for membrane preparation improved the water uptake (by 35% at most), tensile strength (by 110% at most), and elongation capability (by 50% at most) of the membranes. These dicarboxylic acid solutions not only act as solvents but also improve the material properties of the chitosan membranes due to the ionic cross-linking and hydrogen bond formation. In brief, a nontoxic and straightforward cross-linking method has been developed for chitosan material; this method does not result in a brittle product, thus making it better than the use of toxic cross-linking reagents.