chloramphenicol has been researched along with methane in 21 studies
| Timeframe | Studies, this research(%) | All Research% |
|---|---|---|
| pre-1990 | 2 (9.52) | 18.7374 |
| 1990's | 2 (9.52) | 18.2507 |
| 2000's | 3 (14.29) | 29.6817 |
| 2010's | 9 (42.86) | 24.3611 |
| 2020's | 5 (23.81) | 2.80 |
| Authors | Studies |
|---|---|
| Myers, DK | 1 |
| Pflegel, P; Shoukrallah, I; Wagner, G | 1 |
| Jouany, JP; Ushida, K | 1 |
| Amils, R; Rodríguez, N; Sanz, JL | 1 |
| Dang, X; Hu, S; Lü, S; Wu, K | 1 |
| Li, J; Xiao, F; Yan, R; Yu, J; Zeng, B; Zhao, F | 1 |
| Ding, L; Ju, H; Lei, J; Tu, W | 1 |
| Dai, Z; Lu, Y; Shen, Q; Zhang, H | 1 |
| C Bols, N; Chan, TS; Ghafari, P; Hadjout-Rabi, N; Mandal, HS; Nasser, F; St-Denis, CH; Tang, XS | 1 |
| Yang, G; Zhao, F | 1 |
| Bond, T; Chu, T; Chu, W; Du, E; Gao, N; Guo, Y | 1 |
| Cao, Z; Liu, X; Shi, X; Xu, J; Yang, Y; Zhan, Y; Zhao, H; Zhou, J | 1 |
| Maeda, T; Mustapha, NA; Sakai, K; Shirai, Y | 1 |
| Bajwa, SZ; Khan, WS; Lieberzeit, PA; Munawar, A; Shaheen, A; Tahir, MA | 1 |
| Deng, F; Liu, J; Tang, BB; Tang, M; Zhang, JZ | 1 |
| Guo, N; Ma, X; Ren, S; Wang, S; Wang, Y | 1 |
| Chi, H; Fu, L; Jiang, N; Lai, G; Li, X; Lin, CT; Wei, Q; Wu, L; Xu, Y; Ye, C; Yu, A; Zhu, Y | 1 |
| Dong, D; Hua, X; Liu, H; Lv, Y; Qu, J; Wang, Z; Zhang, Y; Zhang, YN | 1 |
| Feng, H; Feng, J; Luo, J; Tang, W; Wang, D; Zhang, J; Zhao, F | 1 |
| Bai, XB; Kou, ZH; Lei, CN; Liu, LX; Wang, B; Xie, YS; Zhang, H | 1 |
| Fang, Y; Feng, Y; Jiang, Y; Li, D; Song, Y; Sun, M; Zhang, Z | 1 |
21 other study(ies) available for chloramphenicol and methane
| Article | Year |
|---|---|
Characteristics of the radiation-induced degradation of DNA in Escherichia coli.
Topics: Age Factors; Chloramphenicol; Cold Temperature; Culture Media; Dinitrophenols; DNA Repair; DNA, Bacterial; Edetic Acid; Escherichia coli; Freezing; Methane; Nucleic Acid Denaturation; Phosphates; Radiation Dosage; Radiation Effects; Sodium Chloride; Sulfonic Acids; Ultraviolet Rays | 1972 |
[Experiments on the gas chromatography determination of chloramphenicol and azidoamphenicol as trimethylsilyl Ethers].
Topics: Acetamides; Acetone; Anti-Bacterial Agents; Azides; Chloramphenicol; Chromatography, Gas; Methane; Methods; Phenethylamines; Pyridines; Silicon; Spectrophotometry, Infrared; Strontium Radioisotopes; Temperature; Time Factors | 1973 |
Methane production associated with rumen-ciliated protozoa and its effect on protozoan activity.
Topics: Animals; Anti-Bacterial Agents; Chloramphenicol; Culture Media; Eukaryota; Euryarchaeota; Methane; Penicillin G; Penicillins; Rumen; Sheep; Streptomycin | 1996 |
The action of antibiotics on the anaerobic digestion process.
Topics: Anaerobiosis; Anti-Bacterial Agents; Antibiotics, Antitubercular; Bacteria, Anaerobic; Biodegradation, Environmental; Chloramphenicol; Fermentation; Lactams; Macrolides; Methane; Rifampin; Sewage; Tetracyclines; Waste Disposal, Fluid | 1996 |
Electrocatalytic reduction of chloramphenicol at multiwall carbon nanotube-modified electrodes.
Topics: Biosensing Techniques; Catalysis; Chloramphenicol; Coated Materials, Biocompatible; Electrochemistry; Electrodes; Equipment Design; Equipment Failure Analysis; Hydrogen-Ion Concentration; Microchemistry; Microelectrodes; Nanotechnology; Nanotubes, Carbon; Organophosphates; Oxidation-Reduction; Reproducibility of Results; Sensitivity and Specificity | 2003 |
Sensitive voltammetric determination of chloramphenicol by using single-wall carbon nanotube-gold nanoparticle-ionic liquid composite film modified glassy carbon electrodes.
Topics: Animals; Anti-Bacterial Agents; Carbon; Chloramphenicol; Electrodes; Glass; Gold; Imidazoles; Ionic Liquids; Metal Nanoparticles; Microscopy, Electron, Scanning; Milk; Nanotubes, Carbon; Potentiometry | 2007 |
Sandwich nanohybrid of single-walled carbon nanohorns-TiO2-porphyrin for electrocatalysis and amperometric biosensing towards chloramphenicol.
Topics: Catalysis; Chloramphenicol; Electrochemistry; Nanotubes, Carbon; Porphyrins; Spectrum Analysis, Raman; Titanium | 2009 |
Multi-walled carbon nanotubes as solid-phase extraction adsorbent for the ultra-fast determination of chloramphenicol in egg, honey, and milk by fused-core C18-based high-performance liquid chromatography-tandem mass spectrometry.
Topics: Adsorption; Animals; Anti-Bacterial Agents; Bees; Cattle; Chickens; Chloramphenicol; Chromatography, High Pressure Liquid; Eggs; Food Contamination; Honey; Milk; Nanotubes, Carbon; Solid Phase Extraction; Tandem Mass Spectrometry | 2010 |
Carbon nanotube compared with carbon black: effects on bacterial survival against grazing by ciliates and antimicrobial treatments.
Topics: Anti-Infective Agents; Cell Count; Chloramphenicol; Coculture Techniques; Disinfectants; Ecotoxicology; Escherichia coli; Glutaral; Green Fluorescent Proteins; Microbial Viability; Nanotubes, Carbon; Soot; Tetrahymena thermophila; Vacuoles | 2013 |
Electrochemical sensor for chloramphenicol based on novel multiwalled carbon nanotubes@molecularly imprinted polymer.
Topics: Biosensing Techniques; Chloramphenicol; Graphite; Limit of Detection; Molecular Imprinting; Nanotubes, Carbon; Polymers | 2015 |
Impact of persulfate and ultraviolet light activated persulfate pre-oxidation on the formation of trihalomethanes, haloacetonitriles and halonitromethanes from the chlor(am)ination of three antibiotic chloramphenicols.
Topics: Acetonitriles; Chloramphenicol; Chlorine; Disinfectants; Disinfection; Halogenation; Hydrocarbons, Chlorinated; Methane; Nitroparaffins; Oxidation-Reduction; Sulfides; Thiamphenicol; Trihalomethanes; Ultraviolet Rays; Water Pollutants, Chemical; Water Purification | 2016 |
Adsorption behavior and mechanism of chloramphenicols, sulfonamides, and non-antibiotic pharmaceuticals on multi-walled carbon nanotubes.
Topics: Adsorption; Anti-Bacterial Agents; Carbamazepine; Chloramphenicol; Diclofenac; Hydrogen-Ion Concentration; Hydrophobic and Hydrophilic Interactions; Ibuprofen; Nanotubes, Carbon; Sulfonamides; Waste Disposal, Fluid; Water Pollutants, Chemical | 2016 |
Impact of different antibiotics on methane production using waste-activated sludge: mechanisms and microbial community dynamics.
Topics: Anaerobiosis; Anti-Bacterial Agents; Archaea; Azithromycin; Bacteria; Biota; Chloramphenicol; Kanamycin; Methane; Sewage | 2016 |
Investigating nanohybrid material based on 3D CNTs@Cu nanoparticle composite and imprinted polymer for highly selective detection of chloramphenicol.
Topics: Anti-Bacterial Agents; Chloramphenicol; Copper; Limit of Detection; Molecular Imprinting; Nanoparticles; Nanotechnology; Nanotubes, Carbon; Polymers | 2018 |
[Removal of Chloramphenicol in Wastewater by Electrocatalytic Reduction with Carbon Nanotubes-Modified Electrode].
Topics: Chloramphenicol; Electrodes; Nanotubes, Carbon; Oxidation-Reduction; Wastewater; Water Purification | 2016 |
Mechanisms of metabolic performance enhancement during electrically assisted anaerobic treatment of chloramphenicol wastewater.
Topics: Anaerobiosis; Bioreactors; Chloramphenicol; Methane; Waste Disposal, Fluid; Wastewater | 2019 |
Intertwined Carbon Nanotubes and Ag Nanowires Constructed by Simple Solution Blending as Sensitive and Stable Chloramphenicol Sensors.
Topics: Chloramphenicol; Electrochemical Techniques; Electrodes; Humans; Nanotubes, Carbon; Nanowires; Reproducibility of Results; Silver | 2021 |
Effective electrocatalytic elimination of chloramphenicol: mechanism, degradation pathway, and toxicity assessment.
Topics: Chloramphenicol; Ecosystem; Electrodes; Humans; Nanotubes, Carbon; Water Pollutants, Chemical | 2021 |
Ferrate modified carbon felt as excellent heterogeneous electro-Fenton cathode for chloramphenicol degradation.
Topics: Carbon; Carbon Fiber; Chloramphenicol; Electrodes; Escherichia coli; Hydrogen Peroxide; Iron; Oxidation-Reduction; Water Pollutants, Chemical | 2022 |
[Determination of 41 veterinary drug residues in livestock and poultry meat using a composite purification system coupled with direct analysis in real time-tandem mass spectrometry].
Topics: Amines; Animals; Cattle; Chickens; Chloramphenicol; Drug Residues; Livestock; Nanotubes, Carbon; Poultry; Tandem Mass Spectrometry | 2023 |
Three-dimensional graphene aerogel mitigated the toxic impact of chloramphenicol wastewater on microorganisms in an EGSB reactor.
Topics: Anaerobiosis; Bioreactors; Chloramphenicol; Graphite; Methane; Sewage; Waste Disposal, Fluid; Wastewater | 2023 |