Effect of Temperature and Cell Viability on Uranium Biomineralization by the Uranium Mine Isolate Penicillium simplicissimum

Schaefer, Sebastian; Steudtner, Robin; Hübner, René; Krawczyk-Bärsch, Evelyn; Merroun, Mohamed L.

doi:10.3389/fmicb.2021.802926

Cited by 7 publications

(1 citation statement)

References 53 publications

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“…The aforementioned process induces ion activity, thereby facilitating the mineralization of the solution, leading to the substantial precipitation of calcium carbonate. The entrapment of Cr by Candida orthopsilosis resulting in the formation of calcium carbonate precipitate has been observed to enhance the removal of HM and facilitate the mineralization of the surfaces of concrete cubes [ 151 ].…”

Section: Bioremediation: Interaction Of Microorganisms With Hmsmentioning

confidence: 99%

Toxicity of Heavy Metals and Recent Advances in Their Removal: A Review

Abd Elnabi,

Elkaliny,

Elyazied

et al. 2023

Toxics

111

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Natural and anthropogenic sources of metals in the ecosystem are perpetually increasing; consequently, heavy metal (HM) accumulation has become a major environmental concern. Human exposure to HMs has increased dramatically due to the industrial activities of the 20th century. Mercury, arsenic lead, chrome, and cadmium have been the most prevalent HMs that have caused human toxicity. Poisonings can be acute or chronic following exposure via water, air, or food. The bioaccumulation of these HMs results in a variety of toxic effects on various tissues and organs. Comparing the mechanisms of action reveals that these metals induce toxicity via similar pathways, including the production of reactive oxygen species, the inactivation of enzymes, and oxidative stress. The conventional techniques employed for the elimination of HMs are deemed inadequate when the HM concentration is less than 100 mg/L. In addition, these methods exhibit certain limitations, including the production of secondary pollutants, a high demand for energy and chemicals, and reduced cost-effectiveness. As a result, the employment of microbial bioremediation for the purpose of HM detoxification has emerged as a viable solution, given that microorganisms, including fungi and bacteria, exhibit superior biosorption and bio-accumulation capabilities. This review deals with HM uptake and toxicity mechanisms associated with HMs, and will increase our knowledge on their toxic effects on the body organs, leading to better management of metal poisoning. This review aims to enhance comprehension and offer sources for the judicious selection of microbial remediation technology for the detoxification of HMs. Microbial-based solutions that are sustainable could potentially offer crucial and cost-effective methods for reducing the toxicity of HMs.

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Section: Bioremediation: Interaction Of Microorganisms With Hmsmentioning

confidence: 99%

Toxicity of Heavy Metals and Recent Advances in Their Removal: A Review

Abd Elnabi,

Elkaliny,

Elyazied

et al. 2023

Toxics

111

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Biostimulation of indigenous microbes for uranium bioremediation in former U mine water: multidisciplinary approach assessment

Newman-Portela,

Krawczyk-Bärsch,

Lopez-Fernandez

et al. 2023

Environ Sci Pollut Res

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Characterizing uranium (U) mine water is necessary to understand and design an effective bioremediation strategy. In this study, water samples from two former U-mines in East Germany were analysed. The U and sulphate (SO42−) concentrations of Schlema-Alberoda mine water (U: 1 mg/L; SO42−: 335 mg/L) were 2 and 3 order of magnitude higher than those of the Pöhla sample (U: 0.01 mg/L; SO42−: 0.5 mg/L). U and SO42− seemed to influence the microbial diversity of the two water samples. Microbial diversity analysis identified U(VI)-reducing bacteria (e.g. Desulfurivibrio) and wood-degrading fungi (e.g. Cadophora) providing as electron donors for the growth of U-reducers. U-bioreduction experiments were performed to screen electron donors (glycerol, vanillic acid, and gluconic acid) for Schlema-Alberoda U-mine water bioremediation purpose. Thermodynamic speciation calculations show that under experimental conditions, U(VI) is not coordinated to the amended electron donors. Glycerol was the best-studied electron donor as it effectively removed 99% of soluble U, 95% of Fe, and 58% of SO42− from the mine water, probably by biostimulation of indigenous microbes. Vanillic acid removed 90% of U, and no U removal occurred using gluconic acid.

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Unveiling the promise of biosorption for heavy metal removal from water sources

Karnwal

2024

Desalination and Water Treatment

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Effect of Temperature and Cell Viability on Uranium Biomineralization by the Uranium Mine Isolate Penicillium simplicissimum

Cited by 7 publications

References 53 publications

Toxicity of Heavy Metals and Recent Advances in Their Removal: A Review

Toxicity of Heavy Metals and Recent Advances in Their Removal: A Review

Biostimulation of indigenous microbes for uranium bioremediation in former U mine water: multidisciplinary approach assessment

Unveiling the promise of biosorption for heavy metal removal from water sources

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