Remediation of Chromium-Contaminated Soil Based on Bacillus cereus WHX-1 Immobilized on Biochar: Cr(VI) Transformation and Functional Microbial Enrichment

Chen, Youyuan; Wu, Haixia; Sun, Ping; Liu, Jiaxin; Qiao, Shixuan; Zhang, Dakuan; Zhang, Zhiming

doi:10.3389/fmicb.2021.641913

Cited by 26 publications

(8 citation statements)

References 52 publications

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“…Low EC represents the less availability of nutrients, while high EC value indicated the presence of excessive nutrients (Liu et al, 2020 ). Microbial metabolic activities and carbon/ nitrogen turnover directly influence the nutrients balance of soil (Muniz et al, 2014 ; Chen et al, 2017 , 2021 ). Varied and low EC value range (relative to WW) for all ZnBC/FeBC microbial combinations might be due to an increase in metal-salt-OH groups or ionic and electrostatic interactions (Saffari et al, 2016 ; Liu et al, 2020 ).…”

Section: Discussionmentioning

confidence: 99%

Microbial-assisted soil chromium immobilization through zinc and iron-enriched rice husk biochar

Batool

Rahman²,

Ali³

et al. 2022

Front. Microbiol.

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Soil chromium toxicity usually caused by the tannery effluent compromises the environment and causes serious health hazards. The microbial role in strengthening biochar for its soil chromium immobilization remains largely unknown. Hence, this study evaluated the effectiveness of zinc and iron-enriched rice husk biochar (ZnBC and FeBC) with microbial combinations to facilitate the chromium immobilization in sandy loam soil. We performed morphological and molecular characterization of fungal [Trichoderma harzianum (F1), Trichoderma viride (F2)] and bacterial [Pseudomonas fluorescence (B1), Bacillus subtilis (B2)] species before their application as soil ameliorants. There were twenty-five treatments having ZnBC and FeBC @ 1.5 and 3% inoculated with bacterial and fungal isolates parallel to wastewater in triplicates. The soil analyses were conducted in three intervals each after 20, 30, and 40 days. The combination of FeBC 3%+F2 reduced the soil DTPA-extractable chromium by 96.8% after 40 days of incubation (DAI) relative to wastewater. Similarly, 92.81% reduction in chromium concentration was achieved through ZnBC 3%+B1 after 40 DAI compared to wastewater. Under the respective treatments, soil Cr(VI) retention trend increased with time such as 40 > 30 > 20 DAI. Langmuir adsorption isotherm verified the highest chromium adsorption capacity (41.6 mg g−1) with FeBC 3% at 40 DAI. Likewise, principal component analysis (PCA) and heat map disclosed electrical conductivity-chromium positive, while cation exchange capacity-chromium and pH-organic matter negative correlations. PCA suggested the ZnBC-bacterial while FeBC-fungal combinations as effective Cr(VI) immobilizers with >70% data variance at 40 DAI. Overall, the study showed that microbes + ZnBC/FeBC resulted in low pH, high OM, and CEC, which ultimately played a role in maximum Cr(VI) adsorption from wastewater applied to the soil. The study also revealed the interrelation and alternations in soil dynamics with pollution control treatments. Based on primitive soil characteristics such as soil metal concentration, its acidity, and alkalinity, the selection criteria can be set for treatments application to regulate the soil properties. Additionally, FeBC with Trichoderma viride should be tested on the field scale to remediate the Cr(VI) toxicity.

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Section: Discussionmentioning

confidence: 99%

Microbial-assisted soil chromium immobilization through zinc and iron-enriched rice husk biochar

Batool

Rahman²,

Ali³

et al. 2022

Front. Microbiol.

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“…The combination of waste fungus chaff-based biochar and Herbaspirillum huttiense was able to solidify 85.5% Cu 2+ and 64.4% Zn 2+ (total Cu 2+ and Zn 2+ in background soil: 218.2 mg/kg and 427.1 mg/kg) (Zhang X. et al, 2022). Bacillus cereus with biochar converted 94.22% of Cr(VI) to Cr(III) in the soil and increased the residual Cr by 60% (Chen et al, 2021). Arbuscular mycorrhizal fungi and biochar enhanced the immobilization of Cr and reduced the Cr(VI) concentration by 0.3%-64.5% (Chen et al, 2022).…”

Section: Toxicity Attenuation and Mineral Precipitation Mechanisms Of...mentioning

confidence: 99%

Biochar: An effective measure to strengthen phosphorus solubilizing microorganisms for remediation of heavy metal pollution in soil

Chen

Jiang

Nazhafati

et al. 2023

Front. Bioeng. Biotechnol.

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Introduction: Phosphorus solubilizing microbial remediation is a sustainable technology for soil heavy metal remediation 1.1 Microbial remediation is an effective measure to achieve sustainable remediation of heavy metals in soil Heavy metals (HMs) pollution of soil caused by human activities is a serious threat to human health and sustainable social development. The insidious, lagging, long-term, inhomogeneous and irreversible nature of heavy metal pollution has led to serious degradation of soil ecological structure and function. Most importantly, heavy metals in soil can be enriched into animals or humans through the food chain (food crops), threatening human health and life (Jan et al., 2015). Therefore, remediation of heavy metals for soils has been one of the key issues in the field of environmental remediation. Compared with physical or chemical remediation technologies, microbial remediation technology is gradually recognized for its green, low cost, easy operation and long sustainability (Maity et al., 2019). Although most HMs are difficult to degrade and remove by microorganisms in soil, microorganisms (microbial uptake, transformation, mineralization or immobilization) can convert HMs to less toxic forms or reduce their mobility (Kotrba and Ruml, 2000;Lin et al., 2023). Among them, biomineralization is a common and effective method for remediation of HMs pollution in soil, which is mainly through the interaction between microorganisms and HMs to form mineral crystals (such as, phosphate, carbonate, sulfate, arsenate, fluoride, oxide, hydroxide, and manganese oxide, etc.) outside, between or within the cells of microorganisms (Tayang and Songachan, 2021;Lin et al., 2023). Not only that, among up to 60 kinds of biomineralization products, metal phosphates have been of concern due to their high stability.

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“…When specific functional bacteria are used for biological enhancement of high concentration organic wastewater treatment systems, free-degrading bacteria have a variety of defects, such as low mechanical strength, low cell density, difficulty in separating biomass effluents, susceptibility to water flow patterns, and limitation in application of practical leachate treatment ( Mulla et al, 2013 ). Using immobilized microorganism technology to immobilize water treatment microorganism on the carrier is to restrict microorganism with specific functions to specific limited space to facilitate recycling and maintain stable biological activity, reduce biological loss, enhance the resistance to harsh environment, and improve the efficiency of wastewater treatment ( Qiao et al, 2010 ; Chen et al, 2021 ). Microorganisms can be adsorbed on the surface of the porous structure by inorganic carrier materials such as activated carbon and biochar.…”

Section: Introductionmentioning

confidence: 99%

Enhanced treatment of landfill leachate by biochar-based aerobic denitrifying bacteria functional microbial materials: Preparation and performance

Song

Li²,

Wang³

et al. 2023

Front. Microbiol.

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ObjectiveIn this work, polyvinyl alcohol (PVA) and sodium alginate (SA) were used as entrapped carriers and Artemisia argyi stem biochar (ABC) was used as an absorption carrier to immobilize aerobic denitrifying bacteria screened from landfill leachate, thus a new carbon-based functional microbial material (PVA/SA/ABC@BS) was successfully prepared.MethodsThe structure and characteristics of the new material were revealed by using a scanning electron microscope and Fourier transform infrared spectroscopy, and the performance of the material for treating landfill leachate under different working conditions was studied.ResultsABC had abundant pore structures and that the surface contained many oxygen-containing functional groups, carboxyl groups, and amide groups, etc. and it had good absorbing performance and strong acid and alkali buffering capacity, which was beneficial to the adhesion and proliferation of microorganisms. After adding ABC as a composite carrier, the damage rate of immobilized particles was decreased by 1.2%, and the acid stability, alkaline stability, and mass transfer performance were increased by 9.00, 7.00, and 56%, respectively. When the dosage of PVA/SA/ABC@BS was 0.017g/ml, the removal rates of nitrate nitrogen (NO3−-N) and ammonia nitrogen (NH4+-N) were the highest, which were 98.7 and 59.4%, respectively. When the pH values were 11, 7, 1, and 9, the removal rates of chemical oxygen demand (COD), NO3−-N, nitrite nitrogen (NO2−-N) and NH4+-N reached the maximum values, which were 14.39, 98.38, 75.87, and 79.31%, respectively. After PVA/SA/ABC@BS was reused in 5 batches, the removal rates of NO3−-N all reached 95.50%.ConclusionPVA, SA and ABC have excellent reusability for immobilization of microorganisms and degradation of nitrate nitrogen. This study can provide some guidance for the great application potential of immobilized gel spheres in the treatment of high concentration organic wastewater.

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Remediation of Chromium-Contaminated Soil Based on Bacillus cereus WHX-1 Immobilized on Biochar: Cr(VI) Transformation and Functional Microbial Enrichment

Cited by 26 publications

References 52 publications

Microbial-assisted soil chromium immobilization through zinc and iron-enriched rice husk biochar

Microbial-assisted soil chromium immobilization through zinc and iron-enriched rice husk biochar

Biochar: An effective measure to strengthen phosphorus solubilizing microorganisms for remediation of heavy metal pollution in soil

Enhanced treatment of landfill leachate by biochar-based aerobic denitrifying bacteria functional microbial materials: Preparation and performance

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