Role of textile effluent fertilization with biosurfactant to sustain soil quality and nutrient availability

Singh, Ratan; Glick, Bernard R.; Rathore, Dheeraj

doi:10.1016/j.jenvman.2020.110664

Cited by 28 publications

(18 citation statements)

References 45 publications

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“…Many relevant 16S rRNA gene sequences with validly published names were chosen as references from the GenBank. [5] The FASTA sequences of all chosen bacterial isolates were aligned using ClustalW. Multiple alignments of sequences were performed using MEGA 11 software and the permitted files were exported using the MEGA format.…”

Section: Identification Of Selected Bacterial Isolates By 16 S Rrna S...mentioning

confidence: 99%

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Dye Decolorization by Rhodococcus ruber Strain TES III Isolated from Textile Effluent Wastewater Contaminated Soil

et al. 2022

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Textile industries monopolize the use of synthetic and natural colors, claiming they are safe for the environment. These dyes have disastrous repercussions when released into the terrestrial and aquatic environment. The main purpose of the study was to isolate a biosurfactant‐producing bacterium from textile effluent‐contaminated soil and study its potential for dye degradation. Biosurfactant was extracted from Rhodococcus ruber strain TES III, a bacterium isolated from textile water contaminated soil. This biosurfactant‐producing bacterium was capable of decolorizing both synthetic dyes like methyl orange, methylene blue, and natural dyes like Indigo. There was a 2‐fold increase in methyl orange degradation after 48 hours, a 1‐fold increase in methylene blue degradation, and a 4.13‐fold increase in indigo dye degradation. Based on the foregoing data, we conclude that the biosurfactant‐producing bacteria Rhodococcus ruber strain TES III has a high potential for dye degradation and hence can be used in wastewater treatment of textile industries.

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Section: Identification Of Selected Bacterial Isolates By 16 S Rrna S...mentioning

confidence: 99%

“…The chemical oxygen demand, biochemical oxygen demand, sulfide, and total dissolved solids are also higher than the permissible limit. [5] International environmental regulations require industrial effluents to be treated before final disposal. It's difficult to reuse and remove dye from textile wastewater.…”

Section: Introductionmentioning

confidence: 99%

Dye Decolorization by Rhodococcus ruber Strain TES III Isolated from Textile Effluent Wastewater Contaminated Soil

et al. 2022

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“…This approach allowed the irrigation system to be more compatible with the integrated treatment of biological control. In recent years, there has been a growing number of innovative treatments, using irrigation systems, such as the application of biosurfactants ( Singh R. et al, 2020 ), generation of nanobubbles ( Xiao et al, 2020 ), air injections ( D’Alessio et al, 2020 ), and so on. In the Netherlands ( Hemming et al, 2020 ), artificial intelligence (AI) algorithms and sensor data were used to determine climate set points and crop management strategies in greenhouse operations.…”

Section: Concept and Characteristics Of Cea Systemsmentioning

confidence: 99%

Response of Plant Rhizosphere Microenvironment to Water Management in Soil- and Substrate-Based Controlled Environment Agriculture (CEA) Systems: A Review

Tan

Liu

et al. 2021

Front. Plant Sci.

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As natural agroecology deteriorates, controlled environment agriculture (CEA) systems become the backup support for coping with future resource consumption and potential food crises. Compared with natural agroecology, most of the environmental parameters of the CEA system rely on manual management. Such a system is dependent and fragile and prone to degradation, which includes harmful bacteria proliferation and productivity decline. Proper water management is significant for constructing a stabilized rhizosphere microenvironment. It has been proved that water is an efficient tool for changing the availability of nutrients, plant physiological processes, and microbial communities within. However, for CEA issues, relevant research is lacking at present. The article reviews the interactive mechanism between water management and rhizosphere microenvironments from the perspectives of physicochemical properties, physiological processes, and microbiology in CEA systems. We presented a synthesis of relevant research on water–root–microbes interplay, which aimed to provide detailed references to the conceptualization, research, diagnosis, and troubleshooting for CEA systems, and attempted to give suggestions for the construction of a high-tech artificial agricultural ecology.

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“…Treatment and reuse of wastewater in land application not only reduces the dependence on freshwater requirement for irrigation purpose but also restricts the wastewater disposal to the natural water bodies and thus minimizes the pollution (Agrafioti & Diamadopoulos, 2012; Aiello et al, 2007; Pedrero et al, 2010). Also, the wastewater possesses variety of nutrients (macro and micro), which benefits plant growth as well as enhances the soil quality by enriching with organic matter, potassium, nitrogen, and phosphorous (Libutti et al, 2018; Singh et al, 2020). In order to deal with the huge amount of wastewater generated every day, proper treatment and disposal methods should be adopted and land‐based treatment systems show the promising candidature for this purpose.…”

Section: Biological Treatment Technologiesmentioning

confidence: 99%

Current available treatment technologies for saline wastewater and land‐based treatment as an emerging environment‐friendly technology: A review

Marathe

Singh

Raghunathan

et al. 2021

Water Environment Research

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Different industrial activities such as agro‐food processing and manufacturing, leather manufacturing, and paper and pulp production generate highly saline wastewater. Direct discharge of saline wastewater has resulted in pollution of waterbodies by very high magnitudes. Consequently, an enormous number of pollutants such as heavy metals, salts, and organic matter are also released into the environment threatening the survival of human and biota. Saline wastewater also has significant effects on survival of plants, agricultural activities, and groundwater systems. Several treatments and disposal technologies are available for saline wastewater, but the selection of the most appropriate treatment and disposal technology still remains a major challenge with respect to the economic or technical constraints. Considering the sustainable management of saline wastewater, the present review is an attempt to compile the existing and emerging technologies for the treatment of saline wastewater. Among all the individual and hybrid technologies, land‐based treatment systems are proven to be the most efficient technologies considering the energy demands, economic, and treatment efficiencies. Likewise, new and sustainable technologies are the need of hour integrating both the treatment and management and the resource recovery factors along with the ultimate goal of the protection in terms of human health and environmental aspect. Practitioner points Physico‐chemical treatment technologies for saline wastewater. Combined/Hybrid technologies for the treatment of saline wastewater. Land‐based treatments as the environment friendly and sustainable method for saline wastewater treatment and disposal. Role of phytoremediation in land‐based treatment.

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Role of textile effluent fertilization with biosurfactant to sustain soil quality and nutrient availability

Cited by 28 publications

References 45 publications

Dye Decolorization by Rhodococcus ruber Strain TES III Isolated from Textile Effluent Wastewater Contaminated Soil

Dye Decolorization by Rhodococcus ruber Strain TES III Isolated from Textile Effluent Wastewater Contaminated Soil

Response of Plant Rhizosphere Microenvironment to Water Management in Soil- and Substrate-Based Controlled Environment Agriculture (CEA) Systems: A Review

Current available treatment technologies for saline wastewater and land‐based treatment as an emerging environment‐friendly technology: A review

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