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ACOMS+ 및 학술지 리포지터리 설명회

  • 한국과학기술정보연구원(KISTI) 서울분원 대회의실(별관 3층)
  • 2024년 07월 03일(수) 13:30
 

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상온 대기압 플라즈마의 치의학적 응용

Applications of Non-Thermal Atmospheric Pressure Plasma in Dentistry

초록

물질의 제3상인 기체가 고온의 에너지를 얻으면 그 물질이 물리학적으로 상태변화하여 제4상이 되며, 우주의 대부분이 이러한 제4상의 물질로 이루어져 있음에 대한 과학적 증명이 1879년 Crook 등에 의하여 밝혀졌다. 1850년에 Simens가 오존을 생성시키기 위하여 최초로 기체를 이온 단위로 분해한 전기적 방전을 선보였으며 1929년, 이러한 전기적 방전현상이 Langmuir에의하여 ‘Plasma(플라즈마)’ 로 명명되었다. 이러한 플라즈마 현상은 현재 빠른 속도로 생물의학, 환경, 우주항공, 농업 및 군사분야로 확장되어 연구되고 있다. 플라즈마 현상의 치의학의 응용은 두 가지의 중요한 관점으로 나누어질 수 있다. 한 가지는, 직집적으로 인체 내 구강조직에 플라즈마 조사(irradiation 또는 treatment)를 통한 치료목적의 응용방법이며, 다른 한가지는 소독이나 표면개질(surface modification)을 위한 치과의료기기 및 치과생체재료의 표면처리 응용이다.

keywords
dentistry, plasma, atmospheric pressure plasma, NTAPP, dental application

Abstract

Since the introduction of non-thermal atmospheric pressure plasma in the field of the dentistry, numerous applications have been investigated. Especially with its advantages over existing vacuum plasma in terms of portability, low cost, and non-thermal damage, it can be directly applied in the oral cavity, giving number of potentials for dental application. First, possible application of non-thermal atmospheric pressure plasma in the field of dentistry is relation to dental caries and periodontal diseases. Teeth and alveolar bones are one of the strongest bony structures in our body, but it cannot be regenerated when they are damaged by dental caries or periodontal disease. Hence many studies to prevent such diseases have been carried out, though no perfect solution has been found yet. With recent studies of modifying surfaces through non-thermal atmospheric pressure application that can prevent attachment of bacteria, or studies on bactericidal effects of non-thermal atmospheric pressure plasma can be applied here to prevent oral pathogen and ‘biofilm’ attachment to the surface of teeth or directly eliminate the dental caries/periodontal disease causing germs. Secondly, non-thermal atmospheric pressure application will be useful on the surface of dental implant. It is well known that the success of dental implant surgery depends on the process known as ‘osseointegration’ that result from osteoblast attachment, proliferation and differentiation. As the application of non-thermal atmospheric pressure plasma on the surface of dental implant just before its introduction by the chair-side of dental surgery. Despite its long history, the generation of non-thermal atmospheric pressure plasma has been greatly increased with its application in dentistry.

keywords
dentistry, plasma, atmospheric pressure plasma, NTAPP, dental application

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