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Crosslinking reaction system of polymers

고분자 가교반응 시스템

  • Ko, Jong-Sung (Korea Institute of Science and Technology Information)
  • Received : 2011.12.20
  • Accepted : 2012.03.20
  • Published : 2012.03.30

Abstract

Pharmaceutical use accounts for a great part of articles and papers on crosslinking of polymers. Crosslinking of polymers used for tissue engineering and drug delivery respects non-cytotoxicity and in situ gelling. The crosslinking of polymers is aimed not only at the improvement of modulus, chemical resistance, and thermal resistance, but also at endowing them with such functions as metal adsorption, antifouling, and ion exchange via crosslinked segments. Smart polymers responding to environmental change, and cosslinking mediated by light, enzyme, natural compound and in aqueous medium in consideration of environment are being studied. Developing new polymeric materials is essential along with the pharmaceutics aiming at the longevity of 120 years old. Functionalization and property adjustment of polymers through crosslinking will be done more delicately. Hydrogels will be focused on injectable and in situ gel forming. In the coating industry crosslinking system with low non-toxicity and low energy consumption will be developed in consideration of workers and environment.

가교에 관한 리뷰논문으로 특허의 다수는 의료용이다. 조직공학용 지지체나 약물전달용 매체로 쓰이는 고분자의 가교는 세포 무독성, 제 자리 겔 형성성이 있는 가교반응을 중시하고 있다. 가교를 탄성률, 내약품성, 내열성의 증대 목적 외에 가교부위에 금속 흡착성, 방오성, 항균성, 이온교환성 등의 기능을 부여하고 있다. 환경의 자극에 응답하는 스마트 가교, 환경을 고려한 광 가교, 물리적 가교, 효소가교, 천연물 가교, 수성가교가 연구되고 있다. 120세 수명을 목표로 의용재료의 발전에 고분자 소재의 개발도 필수적이다. 가교를 통한 고분자의 기능성 부여 및 물성 강화도 더욱 섬세하게 될 것이다. 고분자 가교물 중의 중요한 분야를 점하는 히드로젤은 주사용 제자리 겔 형성성의 개선 방향으로 전개될 것이다. 코팅용 고분자 가교제는 작업자, 작업환경을 고려하여 저독성-무독성의 가교제, 낮은 에너지에서 가교되는 에너지 절약형 가교제가 개발될 것이다.

Keywords

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