Abstract: A visible light-curable chitosan derivative, a hydrogel thereof, and a preparation method therefor are disclosed. The visible light-curable glycol chitosan derivative is curable by light in the visible light range and has a wound healing activity. A hydrogel obtained by cross-linkage of the visible light-curable glycol chitosan derivative using visible light has a wound healing effect per se, and further, a hydrogel obtained by cross-linkage in a combination of one or more growth factors has an excellent wound healing effect. In addition, a glycol chitosan hydrogel that can prevent the denaturation of contained drugs and growth factors due to the cross-linkage by visible light and is optimized for application to a wet dressing dosage form can be prepared.

Abstract: A visible light-curable chitosan derivative, a hydrogel thereof, and a preparation method therefor are disclosed. The visible light-curable glycol chitosan derivative is curable by light in the visible light range and has a wound healing activity. A hydrogel obtained by cross-linkage of the visible light-curable glycol chitosan derivative using visible light has a wound healing effect per se, and further, a hydrogel obtained by cross-linkage in a combination of one or more growth factors has an excellent wound healing effect. In addition, a glycol chitosan hydrogel that can prevent the denaturation of contained drugs and growth factors due to the cross-linkage by visible light and is optimized for application to a wet dressing dosage form can be prepared.

Abstract: The present invention relates to a visible light-curable chitosan derivative, a hydrogel, and a preparation method therefor and, more specifically, to a visible light-curable glycol chitosan derivative which is cured by light in the visible light range and has wound healing ability, a hydrogel, and a preparation method therefor. A hydrogel obtained by cross-linkage of the visible light-curable glycol chitosan derivative according to the present invention using visible light has a wound healing effect per se, and further, a hydrogel obtained by cross-linkage in a combination of one or more growth factors has an excellent wound healing effect. In addition, a glycol chitosan hydrogel that can prevent the denaturation of contained drugs and growth factors due to the cross-linkage by visible light and is optimized for application to a wet dressing dosage form can be prepared.

Abstract: There is provided a thermosensitive biodegradable hydrogel including MPEG-PCL to which a cell-adhesive peptide binds, and MPEG-PCL. The thermosensitive biodegradable hydrogel has excellent cellular adhesiveness while maintaining thermosensitivity of polymers intact, and is biodegradable in vivo after a predetermined period of time.

Abstract: There is provided a thermosensitive biodegradable hydrogel including MPEG-PCL to which a cell-adhesive peptide binds, and MPEG-PCL. The thermosensitive biodegradable hydrogel has excellent cellular adhesiveness while maintaining thermosensitivity of polymers intact, and is biodegradable in vivo after a predetermined period of time.

Abstract: The present invention provides a three-dimensional nanofibrous scaffold for tissue regeneration, which is increased in porosity and thickness to enlarge the surface area thereof, thereby enabling cell adhesion at a high density, and a method for fabricating the same. The method for fabricating a three-dimensional nanofibrous scaffold for tissue regeneration includes the steps of: (a) preparing a polymer solution; (b) preparing a nanofiber matrix, in which a plurality of nanofibers is entangled with each other, from the polymer solution prepared in step (a) using electrospinning; and (c) immersing the prepared nanofiber matrix in a solution and subjecting the solution to ultrasonication, thereby increasing the thickness and porosity of the nanofiber matrix.

Abstract: The present invention provides a three-dimensional nanofibrous scaffold for tissue regeneration, which is increased in porosity and thickness to enlarge the surface area thereof, thereby enabling cell adhesion at a high density, and a method for fabricating the same. The method for fabricating a three-dimensional nanofibrous scaffold for tissue regeneration includes the steps of: (a) preparing a polymer solution; (b) preparing a nanofiber matrix, in which a plurality of nanofibers is entangled with each other, from the polymer solution prepared in step (a) using electrospinning; and (c) immersing the prepared nanofiber matrix in a solution and subjecting the solution to ultrasonication, thereby increasing the thickness and porosity of the nanofiber matrix.