International Journal of Nanobiotechnology

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Metal oxides occupy a critical part in numerous zones of science, and material science. Metal oxide nano materials are vital and fantastic materials. Present work concentrated on to union of MgO nanoparticle by Green technique utilizing [6]-Gingerol, were subjected to sub-atomic docking ponders for the restraint of leukotriene A4 hydrolase (LTA4H) protein is viewed as a significant focus for disease treatment. In silico expectation utilizing a docking approach uncovered that LTA4H may be a potential focus of MgO np utilizing [6]-gingerol. It stifles safe haven autonomous tumor cell development by restraining LTA4H action in HT 29 colorectal disease cells. All things considered, these discoveries show a critical part of LTA4H in malignancy furthermore bolster the anticancer adequacy of MgO np utilizing [6]-gingerol focusing of LTA4H for the counteractive action of colorectal disease. The actuation space of LTA4H docked with the MgO np utilizing [6]-gingerol demonstrated the docking scoring of - 218.92, Kcal.mol-1. The outcomes uncovered that MgO np utilizing [6]-gingerol is considered as a decent inhibitor of LTA4H. The incorporated Magnesium oxide nanoparticles have been described by auxiliary, optical, warm, and indicated powerful cytotoxic impact against HT29 colon growth cell line with in IC50 estimation of 25 µg/ml by the MTT assay. The present study shows the green incorporated Magnesium oxide nanoparticle is utilized noteworthy higher anticancer movement. From the outcomes got it is recommended that the green combined MgO nanoparticle which is a compelling anticancer specialist. Keywords: Cytotoxic Effect, [6]-gingerol, LTA4H, Metal oxides, Nontoxic nature

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