Abstract
Cryogelation is a developing technique for the production of polysaccharide materials for biomedical applications. The formation of a macroporous structure during the freeze-drying of polysaccharide solutions creates biomaterials suitable for tissue engineering. Due to its availability, biocompatibility, biodegradability, and non-toxicity, chitin is a promising natural polysaccharide for the production of porous materials for tissue engineering; however, its use is limited due to the difficulty of dissolving it. This work describes the preparation of cryogels using phosphoric acid as the solvent. Compared to typical chitin solvents phosphoric acid can be easily removed from the product and recovered. The effects of chitin dissolution conditions on the structure and properties of cryogels were studied. Lightweight (ρ 0.025–0.059 g/cm3), highly porous (96–98%) chitin cryogels with various heterogeneous morphology were produced at a dissolution temperature of 20 ± 3 °C, a chitin concentration of 3–15%, and a dissolution time of 6–25 h. The crystallinity of the chitin and chitin cryogels was evaluated by 13C CP-MAS NMR spectroscopy and X-ray diffractometry. Using FTIR spectroscopy, no phosphoric acid esters were found in the chitin cryogels. The cryogels had compressive modulus E values from 118–345 kPa and specific surface areas of 0.3–0.7 m2/g. The results indicate that chitin cryogels can be promising biomaterials for tissue engineering.
Highlights
Chitin is a widespread polysaccharide in Nature, the second most abundant after cellulose [1,2]
Previous work confirmed that chitin at concentrations up to 4% was dissolved in concentrated phosphoric acid [24]
Cryogels could not be produced from a solution with a chitin concentration of less than 3%, whereas obtaining a solution with a chitin concentration of 15% was difficult in the first stages of the dissolution process due to the complexity of mixing
Summary
Chitin is a widespread polysaccharide in Nature, the second most abundant after cellulose [1,2]. Biodegradability, renewability and antibacterial properties make it attractive for use in various fields, including the production of materials for biomedical applications [3,4,5]. The presence of strong inter- and intramolecular hydrogen bonds between the chitin polymer chains decreases the solubility of chitin in many organic solvents, thereby limiting its wide application [7]. [8,9,10], ionic liquids were used as chitin solvents, and several ionic liquids were used to produce chitin/cellulose composite gels. Heating up to 100 ◦ C produced a composite solution with a chitin concentration of 5% and cellulose concentration of
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