Abstract: Provided are a composition for blocking radon and a method for preparing the same, and more particularly, to a composition for blocking radon including ethylene vinyl acetate (EVA); one or more polymer resins selected from the group consisting of polyurethane (PU) and silicone resin; and anionic surfactants, and a method for preparing a composition for blocking radon including irradiating radiation to the composition for blocking radon.

Abstract: The present invention relates to a method for preparing a biocompatible porcine cartilage-derived extracellular matrix membrane capable of adjusting an in-vovo degradation rate and a mechanical property, and a composition containing the porcine cartilage-derived extracellular matrix as an active ingredient, for preventing adhesion between tissues and/or organs. Despite its high biocompatibility as a natural material, cartilage tissue extracellular matrix has a short decomposition period and its mechanical property is weak, thereby restricting the application. Accordingly, a method of enhancing the mechanical property through physical or chemical treatment and radiation treatment has been developed. In the present invention, biomaterials of various formulations were produced by treating the porcine cartilage-derived extracellular matrix with physiochemical methods.

Abstract: An absorbable periodontal tissue and bone regeneration material uses bacterial cellulose that has been exposed to radiation. The bacterial cellulose was confirmed to block the invasion of soft tissue in a calvarial defect in rat and rabbit models and to display excellent absorptiveness enough to contribute bone formation. Therefore, the bacterial cellulose can be developed as an absorbable periodontal tissue and bone regeneration material useful in the field of medical engineering by regulating biodegradability without using chemicals that are toxic to human and environment.

Abstract: An absorbable periodontal tissue and bone regeneration material uses bacterial cellulose that has been exposed to radiation. The bacterial cellulose was confirmed to block the invasion of soft tissue in a calvarial defect in rat and rabbit models and to display excellent absorptiveness enough to contribute bone formation. Therefore, the bacterial cellulose can be developed as an absorbable periodontal tissue and bone regeneration material useful in the field of medical engineering by regulating biodegradability without using chemicals that are toxic to human and environment.

Abstract: The present invention relates to a method for separating collagen from jellyfish by using radiation. More precisely, acid-soluble collagen and attelo collagen were prepared in this invention by using the method combining irradiation technique and chemical treatment. This method of the invention is expected to be useful for the separation of collagen from jellyfish with low costs but high yield.

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.