about
Rhamnolipids modulate swarming motility patterns of Pseudomonas aeruginosaUtilization of banana peel as a novel substrate for biosurfactant production by Halobacteriaceae archaeon AS65.Biodegradability of bacterial surfactants.Simultaneous phenanthrene and cadmium removal from contaminated soil by a ligand/biosurfactant solution.Genome shuffling of Bacillus amyloliquefaciens for improving antimicrobial lipopeptide production and an analysis of relative gene expression using FQ RT-PCR.Differential proteomics analysis of Bacillus amyloliquefaciens and its genome-shuffled mutant for improving surfactin productionExploiting the genetic and biochemical capacities of bacteria for the remediation of heavy metal pollution.Removal of mercury by foam fractionation using surfactin, a biosurfactant.Simultaneous Removal of Lindane, Lead and Cadmium from Soils by Rhamnolipids Combined with Citric Acid.Bioemulsifier production byMicrobacterium SP. strains isolated from mangrove and their application to remove cadmiun and zinc from hazardous industrial residueNatural functions of lipopeptides from Bacillus and Pseudomonas: more than surfactants and antibiotics.Biosurfactants as green stabilizers for the biological synthesis of nanoparticles.Quorum sensing: implications on rhamnolipid biosurfactant production.Biosurfactants in agricultureContributions of biosurfactants to natural or induced bioremediationReview lipopeptides biosurfactants: Mean classes and new insights for industrial, biomedical, and environmental applications.Citric acid- and Tween(®) 80-assisted phytoremediation of a co-contaminated soil: alfalfa (Medicago sativa L.) performance and remediation potential.Spray drying as a strategy for biosurfactant recovery, concentration and storage.Leaching heavy metals in municipal solid waste incinerator fly ash with chelator/biosurfactant mixed solution.Removal of Pb and Zn from contaminated soil by different washing methods: the influence of reagents and ultrasound.Enhancement of sophorolipid production of Wickerhamiella domercqiae var. sophorolipid CGMCC 1576 by low-energy ion beam implantation.Decontamination of a polychlorinated biphenyls-contaminated soil by phytoremediation-assisted bioaugmentation.Antifungal Lipopeptides Produced by Bacillus sp. FJAT-14262 Isolated from Rhizosphere Soil of the Medicinal Plant Anoectochilus roxburghii.Cultivar and Metal-Specific Effects of Endophytic Bacteria in Helianthus tuberosus Exposed to Cd and Zn.Effects of three low-molecular-weight organic acids (LMWOAs) and pH on the mobilization of arsenic and heavy metals (Cu, Pb, and Zn) from mine tailings.Utilization of palm oil decanter cake as a novel substrate for biosurfactant production from a new and promising strain of Ochrobactrum anthropi 2/3.Optimizing removal of arsenic, chromium, copper, pentachlorophenol and polychlorodibenzo-dioxins/furans from the 1-4 mm fraction of polluted soil using an attrition process.Utilization of Agro-Industry Residue for Rhamnolipid Production by P. aeruginosa AMB AS7 and Its Application in Chromium Removal.Aseptic hydroponics to assess rhamnolipid-Cd and rhamnolipid-Zn bioavailability for sunflower (Helianthus annuus): a phytoextraction mechanism study.Synergistical enhancement by Ni2+ and Tween-80 of nanoscale zerovalent iron dechlorination of 2,2',5,5'-tetrachlorinated biphenyl in aqueous solution.The activity of silver against Escherichia coli biofilm is increased by a lipopeptide biosurfactant.Use of Surfactant-Modified Zeolites and Clays for the Removal of Heavy Metals from WaterApplications of nanotechnology in agriculture and water quality managementNanoagriculture and Water Quality ManagementBiosorption of zinc ion: a deep comprehension
P2860
Q24536028-596A78D4-8C44-48AC-BFB6-3C40C586E4ABQ30796098-B348D792-7EE0-4D20-8D71-57C6E419E693Q33739337-77068A50-1FDD-4BD6-8D8C-90CEC41BCBAEQ33849872-4D2F1636-CF13-44B0-8C91-BFCFDEB7B5FDQ34164558-17D5D69A-5552-4831-B77C-3E0F76F8C3DEQ34685115-94EC52C0-A2C9-458D-990E-7E86CAD2627FQ34987448-18FA1F57-F9BC-4A26-B3ED-EAD374106A3CQ35600253-49FDE203-ABDC-468E-8980-D1D7F0CDBB15Q35667605-85E86D37-F900-485E-81A8-CDA151C4DB45Q37159447-58BE3437-39AC-444E-9E98-2A55E1D550F5Q37735905-D1055AAA-32F3-4392-BF0D-C86A81AB5C31Q37831302-0A367AAA-1825-42FC-B764-83DAD22CE63EQ37854445-8310DD37-9204-4AC1-862D-FC2E36CEC4A8Q38070989-6D754D37-7179-4181-B8BB-2124C293317CQ38080747-4E120F24-04C9-4AE0-9F6B-CF6FFE1463D1Q38390729-4A6D33B0-5F02-4CC2-96CC-CE235DBDB029Q38912954-CEC50267-F112-4398-997C-ACAA641E905AQ41907638-DEE5AF41-B9AD-4F74-8D7D-2EA9E2927053Q43336118-1A62482D-2225-4AEF-96C7-A162D0226025Q43337665-F461A993-56B8-457D-8A32-42B196AC8079Q43343701-16B77E16-D05B-44F6-B6D1-F9A340847CB6Q46166928-12CFFB8A-00D3-4E9A-8B17-421CE123F50FQ46459115-489AA954-3DB8-43DB-8291-F8B26D7D280EQ47133969-6522A3E2-8B94-49AF-AB2A-14773B7E9FFEQ47306691-C4D8A0B3-A77B-47B8-9B8A-55D84842F4C2Q48037514-0AA097AD-01EF-4014-973D-55F46993E2B7Q48342622-6B8A884F-C893-431D-9759-0FCA0F6773ABQ51017240-B3E51740-58AD-456D-93BE-59AEAD603CD7Q51210824-D5332E2D-38F6-49A0-98B9-F276BE93C9BEQ53482605-A9F639AE-2CA7-4BBA-85E7-4C54ED76BBCFQ54386319-DFF20B5B-9F02-4363-B423-B9253D3C4566Q57528372-112664EC-1138-46AE-9A3E-4632B715E65BQ58620377-63A28F82-F5EC-4A69-B404-11B430894875Q58620391-B3437B62-3691-4E3D-9FA0-B82301D882BEQ59318452-5DFB59EC-5634-4956-84F6-3792DBB7E9A5
P2860
description
2001 nî lūn-bûn
@nan
2001年の論文
@ja
2001年学术文章
@wuu
2001年学术文章
@zh
2001年学术文章
@zh-cn
2001年学术文章
@zh-hans
2001年学术文章
@zh-my
2001年学术文章
@zh-sg
2001年學術文章
@yue
2001年學術文章
@zh-hant
name
Heavy metal removal from sediments by biosurfactants.
@en
Heavy metal removal from sediments by biosurfactants.
@nl
type
label
Heavy metal removal from sediments by biosurfactants.
@en
Heavy metal removal from sediments by biosurfactants.
@nl
prefLabel
Heavy metal removal from sediments by biosurfactants.
@en
Heavy metal removal from sediments by biosurfactants.
@nl
P2093
P1476
Heavy metal removal from sediments by biosurfactants.
@en
P2093
P304
P356
10.1016/S0304-3894(01)00224-2
P577
2001-07-01T00:00:00Z