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: Disclosed herein is a method for the preparation of radioisotope-labeled compounds using CNT. It comprises filling the carbon nanotube with a radioisotope; and labeling a physiologically active material with the radioisotope charged in the carbon nanotube. Taking advantage of CNT, the method can prepare a radioisotope-labeled compound invention at a high yield and in a simple manner. Also, the radioisotope, when remaining unreacted, can be recovered by the filtration of the CNT, thereby achieving the prevention of radioactive contamination and the reduction of radioactive waste. Further, the radioisotope-labeled compound is useful as a contrast medium for imaging the hepatobiliary system.

Abstract: Disclosed relates to an ionic liquid type crown ether derivative, expressed by Chemical Formula 1 below, for isolating metal ions, a method for preparing the same and a method for isolating selectively the metal ions using the cycle size of the same. The present invention can provide the ionic liquid type crown ether and isolate metal ions including radioactive isotopes efficiently using the same. Furthermore, the prevent invention provides crown ether valuably used as a recyclable and environment-friendly isolating medium by preparing crown ether of ionic liquid type. wherein m, n, X? and R are identical with those in the description.

Abstract: The present invention relates to a biochip for the detection of phosphorylation and a method for measuring phosphorylation using the same, more precisely a biochip integrated with the substrate of kinase and a kit for measuring phosphorylation comprising the biochip and a radio-labeled co-factor, and a method for measuring phosphorylation using the same. The kit for the detection of phosphorylation of the present invention facilitates simple and fast measurement of phosphorylation with a minimum amount of a sample, compared with the conventional method using an antibody, because it uses a radioisotope. This chip and kit can be effectively used for the analysis of kinase activity since this method favors fast mass analysis.

Abstract: Disclosed herein are a method of preparing a technetium-99m-labeled iron oxide (Fe2O3) nanoparticle and a diagnostic imaging or therapeutic agent for cancer diseases comprising the nanoparticle. The 99mTc-iron oxide nanoparticle is prepared using an acidic solution or a borohydride anion exchange resin as a reducing agent, and thus, is easy to inject into the body, and its biodistribution and excretion from the body is easily predicted. The 99mTc-iron oxide nanoparticle eliminates cancerous tissues as well as enabling non-invasive real-time imaging for obtaining anatomical information about cancerous tissues and tissue functions without the need for surgery. Also, the iron oxide nanoparticle may be useful as an imaging agent for various diseases including tumors, contagious diseases and genetic defects.

Abstract: Disclosed relates to organic germanium nanocolloids, to which technetium-99m (99mTc), a radionuclide, is labeled, method of the same, and a spleen-imaging agent including the same. According to the invention, 99mTc-labeled organic germanium nanocolloids having high labeling efficiency and stability can be provided. Moreover, since the 99mTc-labeled organic germanium nanocolloids of the invention are accumulated in the spleen considerably higher than the conventional spleen-imaging agent, it is possible to use the 99mTc-labeled organic germanium nanocolloids of the present invention as a therapeutic radiopharmaceutical for the spleen imaging.

Abstract: Disclosed herein is a method for the preparation of radioisotope-labeled compounds using CNT. It comprises filling the carbon nanotube with a radioisotope; and labeling a physiologically active material with the radioisotope charged in the carbon nanotube. Taking advantage of CNT, the method can prepare a radioisotope-labeled compound invention at a high yield and in a simple manner. Also, the radioisotope, when remaining unreacted, can be recovered by the filtration of the CNT, thereby achieving the prevention of radioactive contamination and the reduction of radioactive waste. Further, the radioisotope-labeled compound is useful as a contrast medium for imaging the hepatobiliary system.

Abstract: A method for labelling a sulfide compound with technetium or rhenium, comprising the reaction of a disulfide compound with pertechnetate or perrhenate in the presence of borohydride exchange resin to obtain a complex of technetium or rhenium with the sulfide compound. The method can directly label disulfide compounds with technetium or rhenium, can skip the synthetic step of thiol-protected S-precursor, and is useful for high value-added radiopharmaceuticals.

Abstract: The present invention relates to a method of preparing technetium or rhenium complex for radiopharmaceuticals, through reaction of pertechnetate or perrhenate with a ligand in the presence of a reducing agent, wherein the reducing agent is a borohydride exchange resin (BER). The borohydride exchange resin of the present invention has advantages of being stable in a wide range of Ph, including acidic or alkaline condition(Ph 2˜14) and thus being applicable to biological materials as well as being easily removable through filtration when being administrated. Also since the radiolabelled complex is produced under conditions milder than those required for the conventional reducing agents as well as has high radiochemical purity and high labeling efficiency, the conventional reducing agents can be replaced by the BER of the present invention.

Abstract: The present invention relates to a method of preparing technetium or rhenium complex for radiopharmaceuticals, through reaction of pertechnetate or perrhenate with a ligand in the presence of a reducing agent, wherein the reducing agent is a borohydride exchange resin (BER) . The borohydride exchange resin of the present invention has advantages of being stable in a wide range of Ph, including acidic or alkaline condition(Ph 2˜14) and thus being applicable to biological materials as well as being easily removable through filtration when being administrated. Also since the radiolabelled complex is produced under conditions milder than those required for the conventional reducing agents as well as has high radiochemical purity and high labeling efficiency, the conventional reducing agents can be replaced by the BER of the present invention.

Abstract: The present invention relates to a method for labelling a sulfide compound with technetium or rhenium, comprising the reaction of a disulfide compound with pertechnetate or perrhenate in the presence of borohydride exchange resin to obtain a complex of technetium or rhenium with the sulfide compound. The method can directly label disulfide compounds with technetium or rhenium, can skip the synthetic step of thiol-protected S-precursor, and is useful for high value-added radiopharmaceuticals.