Development of Chitosan Dermal Scaffold and its Characterization

Chun Ho Kim; Young Ju Choi; Seung Jae Lee; Yong Jae Gin; Young Sook Son

doi:10.4028/www.scientific.net/KEM.342-343.181

Paper Titles

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Crosslinked Gelatin Nanofibers and their Potential for Tissue Engineering
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Hybrid Type of Tissue Engineered Biodisc Using Annulus Fibrosus Seeded PLGA Scaffold and Nucleus Pulposus Seeded MPEG-PCL Hydrogel: Preliminary Study
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Injectable Chitosan Carrier for Demineralized Bone Matrix
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Development of Chitosan Dermal Scaffold and its Characterization
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Increase in the Biocompatibility of the Neutralized Chitosan Dermal Scaffold by Reconstruction of Wound Healing Microenvironment: In Vitro Study
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Vascular Smooth Muscle Cell Behaviors onto Epigallocatechin- 3-O-Gallate-Blended L-Lactide/ε-Caprolactone Copolymers
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The Role of Endothelial Cells Differentiated from Bone Marrow Stem Cells in Cartilage and Bone Regeneration
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High Hepatic Function Was Maintained on Electrospun Nanofibrous Scaffold
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HomeKey Engineering MaterialsKey Engineering Materials Vols. 342-343Development of Chitosan Dermal Scaffold and its...

Development of Chitosan Dermal Scaffold and its Characterization

Abstract:

We have developed tensile and porous neutralized chitosan scaffold (NCS) whose pore size was controlled by freezing temperatures. At -70 oC, mean pore size of 112 μm was obtained. At -196 oC, mean pore size was approximately 70 μm at surface. The scaffold processed at -196 oC showed homogeneous small pores with structural integrity, which may be more useful as a guidance dermal scaffold for inward cell migration. The scaffold processed at –70 oC may be more useful for cell loading scaffold requiring wider pore. Since biodegradability and biocompatibility are crucial parameters for the development of dermal scaffold, we evaluated the rate of NCS degradation in the culture medium containing lysozyme by measuring weight loss as well as mean molecular weight of the scaffold. Approximately 40% weight loss at one week and 70% weight loss at 30 days was observed, which means that 70% of the scaffold will be degraded and releasable if the wound microenvironment is similar to the test condition. Again, mean molecular weight of the scaffold based on gel permeation chromatography was less than 1x105 after 10 day incubation. This result suggests that degradation of the NCS begins earlier than the observation of gross weight loss. We also evaluated whether degradation product of NCS are toxic to the human dermal fibroblast or not. Chitosan oligomer up to 1.0 mg/ml, which corresponds to 10% of the total degradation derivatives of the NCS, did not affect the viability of the dermal fibroblast based on MTT assay. This result along with the biodegradation data suggests that the NCS can be developed as suitable dermal scaffold.