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W2761366242 abstract "There has been a significant surge in consumption of radionuclides for various academic and commercial purposes. Correspondingly, there has been a considerable amount of generation of radioactive waste. Bacteria and archaea, being earliest inhabitants on earth serve as model microorganisms on earth. These microbes have consistently proven their mettle by surviving extreme environments, even extreme ionizing radiations. Their ability to accept and undergo stable genetic mutations have led to development of recombinant mutants that are been exploited for remediation of various pollutants such as; heavy metals, hydrocarbons and even radioactive waste (radwaste). Thus, microbes have repeatedly presented themselves to be prime candidates suitable for remediation of radwaste. It is interesting to study the behind-the-scenes interactions these microbes possess when observed in presence of radionuclides. The emphasis is on the indigenous bacteria isolated from radionuclide containing environments as well as the five fundamental interaction mechanisms that have been studied extensively, namely; bioaccumulation, biotransformation, biosorption, biosolubilisation and bioprecipitation. Application of microbes exhibiting such mechanisms in remediation of radioactive waste depends largely on the individual capability of the species. Challenges pertaining to its potential bioremediation activity is also been briefly discussed. This review provides an insight into the various mechanisms bacteria uses to tolerate, survive and carry out processes that could potentially lead the eco-friendly approach for removal of radionuclides." @default.
W2761366242 created "2017-10-20" @default.
W2761366242 creator A5024185937 @default.
W2761366242 creator A5029757228 @default.
W2761366242 creator A5034971459 @default.
W2761366242 date "2017-12-01" @default.
W2761366242 modified "2023-10-13" @default.
W2761366242 title "Radiation, radionuclides and bacteria: An in-perspective review" @default.
W2761366242 cites W1514486887 @default.
W2761366242 cites W1544288079 @default.
W2761366242 cites W1545036169 @default.
W2761366242 cites W1589618892 @default.
W2761366242 cites W1596325061 @default.
W2761366242 cites W1599395073 @default.
W2761366242 cites W1650279782 @default.
W2761366242 cites W1880223154 @default.
W2761366242 cites W1900205193 @default.
W2761366242 cites W1931665845 @default.
W2761366242 cites W1971411275 @default.
W2761366242 cites W1973215335 @default.
W2761366242 cites W1974316944 @default.
W2761366242 cites W1975913504 @default.
W2761366242 cites W1976228232 @default.
W2761366242 cites W1976728776 @default.
W2761366242 cites W1981307771 @default.
W2761366242 cites W1984116228 @default.
W2761366242 cites W1988805887 @default.
W2761366242 cites W1993142917 @default.
W2761366242 cites W1993840130 @default.
W2761366242 cites W1994606475 @default.
W2761366242 cites W1996583542 @default.
W2761366242 cites W2012591611 @default.
W2761366242 cites W2014715659 @default.
W2761366242 cites W2016376041 @default.
W2761366242 cites W2018461548 @default.
W2761366242 cites W2023070368 @default.
W2761366242 cites W2026174217 @default.
W2761366242 cites W2026883058 @default.
W2761366242 cites W2027733260 @default.
W2761366242 cites W2029626463 @default.
W2761366242 cites W2032861694 @default.
W2761366242 cites W2034084207 @default.
W2761366242 cites W2039128307 @default.
W2761366242 cites W2040670684 @default.
W2761366242 cites W2042343566 @default.
W2761366242 cites W2046097998 @default.
W2761366242 cites W2052956266 @default.
W2761366242 cites W2062698787 @default.
W2761366242 cites W2068931355 @default.
W2761366242 cites W2070876074 @default.
W2761366242 cites W2071886065 @default.
W2761366242 cites W2078826610 @default.
W2761366242 cites W2081423970 @default.
W2761366242 cites W2084472651 @default.
W2761366242 cites W2088052323 @default.
W2761366242 cites W2088339605 @default.
W2761366242 cites W2090495747 @default.
W2761366242 cites W2092296579 @default.
W2761366242 cites W2099195228 @default.
W2761366242 cites W2105769874 @default.
W2761366242 cites W2110797200 @default.
W2761366242 cites W2116132837 @default.
W2761366242 cites W2122915228 @default.
W2761366242 cites W2144589213 @default.
W2761366242 cites W2149519302 @default.
W2761366242 cites W2154159254 @default.
W2761366242 cites W2155261777 @default.
W2761366242 cites W2157963818 @default.
W2761366242 cites W2167005694 @default.
W2761366242 cites W2168325667 @default.
W2761366242 cites W2170887794 @default.
W2761366242 cites W2172323550 @default.
W2761366242 cites W2338212227 @default.
W2761366242 cites W2462805862 @default.
W2761366242 cites W2524425138 @default.
W2761366242 cites W2551173353 @default.
W2761366242 cites W2560752925 @default.
W2761366242 cites W2592887714 @default.
W2761366242 cites W270826353 @default.
W2761366242 cites W4250180411 @default.
W2761366242 doi "https://doi.org/10.1016/j.jenvrad.2017.09.013" @default.
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