NNK (4-(methylnitrosamino)―1-(3-pyridyl)-1-butanone) is a major form of nitrosamine abundant in cigarette smoke and is a powerful carcinogen. Mercury is a major component of the amalgam that is widely used as dental filling material. Concurrent exposure to these two agents may result in their interaction and alter their carcinogenic potential. The present study used an immortalized human epithelial cell system that allows continuous exposure to potential carcinogens, in an attempt to elaborate the carcinogenic potential of mercury and NNK in humans. Cytotoxicity of mercury chloride and NNK was measured by an MTT assay. Parameters of neoplastic cellular transformation such as cell saturation density, soft-agar colony formation, and cell aggregation were analyzed to examine the carcinogenic potential of mercury chloride and NNK. The study showed that exposure to mercury chloride with NNK resulted in increased soft agar colony formation and cell aggregation. ROS generation by mercury chloride was further enhanced by treatment with NNK. The apoptosis that was observed following mercury chloride exposure was further increased upon co-treatment with NNK. The interaction between these two agents was also observed in cytokine mRNA induction. In the present study, mercury alone did not seem to pose a significant threat as a carcinogen, but it may have potential to enhance the carcinogenic potential of a known carcinogen from cigarette smoke. The present study provides valuable data regarding the evaluation of potential carcinogenic risk of mercury chloride and NNK on concurrent exposure.

In this work, recent progress on graphene/metal oxide composites as advanced materials for HgCl2 and CO2 capture was investigated. Density Functional Theory calculations were used to understand the effects of temperature on the adsorption ability of HgCl2 and water vapor on CO2 adsorption on CaO (001) with reinforced carbon-based nanostructures using B3LYP functional. Understanding the mechanism by which mercury and CO2 adsorb on graphene/CaO (g-CaO) is crucial to the design and fabrication of effective capture technologies. The results obtained from the optimized geometries and frequencies of the proposed cluster site structures predicted that with respect to molecular binding the system possesses unusually large HgCl2 (0.1- 0.4 HgCl2 g/g sorbent) and CO2 (0.2-0.6 CO2 g/g sorbent) uptake capacities. The HgCl2 and CO2 were found to be stable on the surface as a result of the topology and a strong interaction with the g-CaO system; these results strongly suggest the potential of CaO-doped carbon materials for HgCl2 and CO2 capture applications, the functional gives reliable answers compared to available experimental data.

각종 유전독성학적 물질로 인한 생물체내의 영향을 평가해보기 위해 E. fetida를 대상으로 본 연구를 수행하였다. 염화수은에 대한 DNA 손상을 알아보는 실험에서는 노출 시간에 상관없이 노출 농도에 비례한 유전자의 손상이 나타났다. 방사선이 지렁이의 DNA 손상에 미치는 영향을 알아본 실험에서도 역시 방사선 총 선량의 증가에 따라 DNA 손상이 증가하는 경향을 보였다. 염화수은에 48시간 동안 노출시키고 방사선을 조사한 지렁이의 세포를 comet as

Metal ions are essential to life. However, some metals such as mercury are harmful, even when present at trace amounts. Toxicity of mercury arises mainly from its oxidizing properties. Ionizing radiation (IR) is an active tool for destruction of cancer ce

All organisms are being exposed to harmful factors present in the environmental. The combined action of various factors is a distinguishing feature of modern life. An interaction between two chemicals is considered as synergistic when the effect produced

세포에 미치는 염화수은(II)과 이온화 방사선의 영향과 수은 처리 전 후 방사선 조사 시 그 상호 작용에 관해 알아보고자 본 연구를 수행하였다. 염화수은(II)의 독성정도를 알아보기 위하여 사람의 자궁암 세포에 농도별로 염화수은(II)을 처리하였다. 세포의 생존율은 3가지 농도(1,0. 1,0. 0.01 μM)모두에서 유의하게 감소하였으며 이미 0.1 μM에서 약 73%의 생존율이 감소하는 것으로 나타났다. 염화수은(II)과 방

생태계는 수은의 화학적 형상 및 산업화에 따른 방출로 지속적이면서 다양하게 오염된다. 또한 수은은 화학적 여러 형태로 분류되며 쉽게 기화되는 성질로 인해 수은을 공정하는 과정에서 수많은 근로자들이 쉽게 급성 혹은 만성 중독이 될 수 있다. 그러나 수은의 유독성이 알려져 있기는 하나 생체가 환경에서 노출 가능한 저농도의 수은 영향에 대해서는 정확한 접근이 이루어지지 않고 있다. 따라서 본 실험은 이온화 방사선과 염화수은(II)의 영향을 비교해보고자 수행하