Management options for reducing the release of antibiotics and antibiotic resistance genes to the environment
about
sameAs
Colistin in Pig Production: Chemistry, Mechanism of Antibacterial Action, Microbial Resistance Emergence, and One Health PerspectivesThe global threat of antimicrobial resistance: science for interventionA treatment plant receiving waste water from multiple bulk drug manufacturers is a reservoir for highly multi-drug resistant integron-bearing bacteriaIs gray water the key to unlocking water for resource-poor areas of the Middle East, North Africa, and other arid regions of the world?Safely coupling livestock and crop production systems: how rapidly do antibiotic resistance genes dissipate in soil following a commercial application of swine or dairy manure?Lateral Antimicrobial Resistance Genetic Transfer is active in the open environmentIntegrons: past, present, and future.Antibiotic Concentrations Decrease during Wastewater Treatment but Persist at Low Levels in Reclaimed Water.Metagenomics of urban sewage identifies an extensively shared antibiotic resistome in China.Pollution from drug manufacturing: review and perspectivesImpact of fertilizing with raw or anaerobically digested sewage sludge on the abundance of antibiotic-resistant coliforms, antibiotic resistance genes, and pathogenic bacteria in soil and on vegetables at harvest.Shotgun metagenomics reveals a wide array of antibiotic resistance genes and mobile elements in a polluted lake in India.Reconnaissance of 47 antibiotics and associated microbial risks in seafood sold in the United States.Does the Recent Growth of Aquaculture Create Antibiotic Resistance Threats Different from those Associated with Land Animal Production in Agriculture?Enhanced horizontal transfer of antibiotic resistance genes in freshwater microcosms induced by an ionic liquid.Using the class 1 integron-integrase gene as a proxy for anthropogenic pollutionThe Microbiota and Abundance of the Class 1 Integron-Integrase Gene in Tropical Sewage Treatment Plant Influent and Activated Sludge.Antimicrobial-Resistant Bacterial Populations and Antimicrobial Resistance Genes Obtained from Environments Impacted by Livestock and Municipal Waste.The horizontal transfer of antibiotic resistance genes is enhanced by ionic liquid with different structure of varying alkyl chain length.A Comprehensive Analysis on Spread and Distribution Characteristic of Antibiotic Resistance Genes in Livestock Farms of Southeastern ChinaMonitoring Antibiotic Use and Residue in Freshwater Aquaculture for Domestic Use in Vietnam.Antimicrobial Resistance in AgricultureImpact of manure fertilization on the abundance of antibiotic-resistant bacteria and frequency of detection of antibiotic resistance genes in soil and on vegetables at harvest.Human Health Risk Assessment (HHRA) for environmental development and transfer of antibiotic resistance.Acquired genetic mechanisms of a multiresistant bacterium isolated from a treatment plant receiving wastewater from antibiotic production.Change in microbial community in landfill refuse contaminated with antibiotics facilitates denitrification more than the increase in ARG over long-term.Antibiotics in the environment.Antibacterial resistance: an emerging 'zoonosis'?Isolation and Characterization of NDM-Positive Escherichia coli from Municipal Wastewater in Jeddah, Saudi Arabia.Application of veterinary antibiotics in China's aquaculture industry and their potential human health risks.Environmental and human health risks of antimicrobials used in Fenneropenaeus chinensis aquaculture production in China.Veterinary pharmaceuticals in aqueous systems and associated effects: an update.Persistence of antibiotic resistance and plasmid-associated genes in soil following application of sewage sludge and abundance on vegetables at harvest.Seasonality of antibiotic prescriptions for outpatients and resistance genes in sewers and wastewater treatment plant outflow.Impacts of coexisting antibiotics, antibacterial residues, and heavy metals on the occurrence of erythromycin resistance genes in urban wastewater.Sulfonamide and tetracycline resistance genes in total- and culturable-bacterial assemblages in South African aquatic environments.Autoclave treatment of pig manure does not reduce the risk of transmission and transfer of tetracycline resistance genes in soil: successive determinations with soil column experiments.Dominant plasmids carrying extended spectrum β-lactamases blaCTX-M genes in genetically diverse Escherichia coli from slaughterhouse and urban wastewaters.Lateral gene transfer, bacterial genome evolution, and the Anthropocene.Resistance Mutations in gyrA and parC are Common in Escherichia Communities of both Fluoroquinolone-Polluted and Uncontaminated Aquatic Environments
P2860
Q28076261-508FE396-8F9D-4755-82EE-B63972E88C38Q28083609-0701B7B7-CF75-4B30-A70C-F4ED79C213A6Q28534693-41F0D08E-FDAB-4047-AF8C-1AA2AAD1A77CQ28655718-4D61C4FA-B2D8-4A8D-B437-B0B85CE3CD14Q33602016-6CFB3492-7B9F-44D9-AE0D-77EF14433EAEQ33674296-763BD32D-09C1-4F81-A7A2-8D4954CF1D90Q33743517-0B756170-D348-4B96-AB61-D658C6980DD3Q33840073-C50DE9F6-9880-47F8-A37A-5D167AA94821Q33919222-417BF761-CF98-4BA0-BDE2-53502151DD7AQ34423503-B7E8F6F3-9E36-4F26-8BA6-F805B94F17A0Q34594230-29BEC6FC-7712-4E15-AC26-C4C13DDE5D5EQ34608928-3765A97C-7630-42C1-8026-722AF4D17DA8Q34625912-BAE763CF-A1EC-4963-9FFE-A667D859DB47Q35529139-6032FFFA-88BD-4129-9355-9CDCB750B2D9Q35581108-B6FC0F9B-5DAB-4599-8A27-80A05C3F535FQ35626365-E03CBA5F-033C-42E7-9819-A3AD00855491Q35675681-9511F9BD-D6A0-4AE4-B3F4-B125429117FCQ35702845-A3129C90-6A75-4A5C-A5B2-6979263F9ED0Q35999145-F1C74181-9775-4031-BC9C-9DD97E2E0062Q36070038-76836426-783D-42F0-BE7F-7F485648C365Q36214784-D7BA541F-BD76-4332-8551-84A453842FDDQ36849965-AF39F77C-6DAB-44EE-8AB8-59921C24C665Q37123686-DFD8892B-04C2-4D26-949D-5E964F722E97Q37149760-074C2FE1-4DF7-4F6E-88B6-87871EE6D229Q37335341-D145E43B-6C76-4384-BE8C-3E3615641124Q37605104-B3C3755E-B13A-494A-B01B-E662CA05CE0AQ38197282-AC05F07E-EDD6-44D6-A742-256B1688460CQ38263035-91B8052F-40C8-43EA-BC26-0FC1C76A9DE9Q38379421-D85A2B03-1372-4361-AB20-8F0BBD567A72Q38615899-74FC23D5-CF1D-4DEB-993F-C8AE4B9C5F97Q38872715-B828E774-AA2A-4FCD-8082-357B28023E2CQ38983583-75BDDFD2-34F6-468A-97EC-B9CEC8F72BFAQ39699337-4EF76B39-E168-41DC-8429-0AF484246B2EQ39854828-633F0506-4CCC-4E8F-A5C9-130A1711A211Q40253059-AF563D3C-6FB0-49FF-9CFE-741A2D5CE33BQ40307727-CC33FB4E-6C41-4C99-942F-B785F5BE817CQ40374549-9558C758-09D2-4240-BFA3-CAC300C58509Q40388695-E6A051F4-84B2-4FE6-8573-4666D5596B41Q40515882-CF7C3E7F-DA66-4147-9C8F-9F4F9AAC6C23Q40860093-A99B1247-8C34-45BB-A854-A52DD7CDA6C8
P2860
Management options for reducing the release of antibiotics and antibiotic resistance genes to the environment
description
2013 nî lūn-bûn
@nan
2013 թուականի Օգոստոսին հրատարակուած գիտական յօդուած
@hyw
2013 թվականի օգոստոսին հրատարակված գիտական հոդված
@hy
2013年の論文
@ja
2013年論文
@yue
2013年論文
@zh-hant
2013年論文
@zh-hk
2013年論文
@zh-mo
2013年論文
@zh-tw
2013年论文
@wuu
name
Management options for reducin ...... tance genes to the environment
@ast
Management options for reducin ...... tance genes to the environment
@en
Management options for reducin ...... tance genes to the environment
@nl
type
label
Management options for reducin ...... tance genes to the environment
@ast
Management options for reducin ...... tance genes to the environment
@en
Management options for reducin ...... tance genes to the environment
@nl
prefLabel
Management options for reducin ...... tance genes to the environment
@ast
Management options for reducin ...... tance genes to the environment
@en
Management options for reducin ...... tance genes to the environment
@nl
P2093
P2860
P50
P3181
P356
P1476
Management options for reducin ...... tance genes to the environment
@en
P2093
Alejandro Amézquita
Amy Pruden
James M. Lazorchak
Jason R. Snape
Peter Silley
Satoru Suzuki
Tong Zhang
Yong-Guan Zhu
P2860
P304
P3181
P356
10.1289/EHP.1206446
P407
P577
2013-08-01T00:00:00Z