Antibiotics, detection macrolides

Other sources of PPCP contamination to groundwater can originate from farms, leaking septic tanks, and lagoons. For instance, Campagnolo et al. (2002) detected several types of antibiotics including macrolides, tetracycline, sulfonamides, and (3-lactams in groundwater samples collected from sites that were in proximity of a swine farm. 

Macrolide antibiotics (clarithromycin, dehydroerythromycin, etc.) and sulfonamides (sulfamethoxazole, sulfadimethoxine, sulfamethazine, and sulfathi-azole) are the most prevalent antibiotics found in the environment with levels around a few micrograms per liter, whereas fluoroquinolones, tetracyclines, and penicillins have been detected in fewer cases and usually at low concentrations (nanograms per liter) [3,20,23,72]. This result is not surprising, since penicillins are easily hydrolyzed and tetracyclines readily precipitate with cations such as calcium and are accumulated in sewage sludge or sediments. Several reviews have reported the environmental occurrence of different antibiotics in aquatic and soil compartments. Some of these data are detailed in Table 1. 

Erythromycin, a macrolide antibiotic, lacks a significant chromophore. Detection sensitivity was enhanced by using a wavelength of 200 nm and selecting an injection solvent of lower conductivity than the BGE. In order to facilitate the separation of erythromycin and its related substances, 35% (v/v) ethanol was incorporated into a 150 mM phosphate buffer pH 7.5. Resolution of all of the compounds was achieved in approximately 45 min. The method was employed as an assay method for erythromycin and for impurity determination. Peptide antibiotics, such as colistin and polymyxin, are mixtures of many closely related compounds. A validated CZE method for impurity analysis of polymyxin B was described, employing 130 mM triethanolamine-phosphate buffer at pH 2.5 to reduce the adsorption of analyte onto the capillary wall. Methyl-/l-cyclodextrin (M-/1-CD) and 2-propanol were found to be necessary for selectivity enhancement. Using similar buffer additives, the same group developed and validated a method for colistin analysis. ... 

Siemann M, Andersson LI, Mosbach K. Separation and detection of maciolide antibiotics by HPLC using macrolide-imprinted synthetic polymers as stationary phases. J Antibiot 1997 50 89-91. 

Maximal plasma concentrations occur 2 to 3 hours after oral administration of reboxetine (178). Reboxetine has linear pharmacokinetics over its clinically relevant dosing range and a half-life of approximately 12 hours. For this latter reason, a twice a day, equally divided dosing schedule was used during clinical trial development. Its clearance is reduced and half-life becomes longer as a function of advanced age (mean = 81 years of age) and renal and hepatic impairment ( 178, 322, 323). Reboxetine is principally metabolized by CYP 3A3/4 such that its dose should be reduced when used in combination with drugs that are substantial inhibitors of CYP (e.g., certain azole antifungals, certain macrolide antibiotics). Reboxetine itself, however, does not cause detectable inhibition of CYP 3A3/4 based on formal in vivo pharmacokinetic interaction studies as well as its own linear pharmacokinetics. 

Results showed a total of 2.8% of the samples (n 2972) to be inhibitor positive by the Delvotest SP test further examination identified 1.7% as -lactam antibiotics, and 1.1 % as sulfonamides and dapsone. The percentage of chloramphenicol suspicious samples determined by the Charm II test was amazingly high however, tests for confirmation were not available and contamination of the samples by residues of the chloramphenicol-based preservative azidiol could not be excluded with certainty. Low concentrations of streptomycins were also detected in 5.7% of the samples (n 1221), but the MRL was not exceeded. Macrolide and tetracycline residues were not found in significant levels. Model trials with commercially applied yoghurt cultures confirmed how important the compliance to MRLs can be to dairy industry compared to antibiotic-free milk, a pH of 5.0 was reached with a delay of 15 min in the case of contamination with cloxacillin 30 min in the case of penicillin, spiramycin, and tylosin and 45 min in the case of oxytetracycline contamination. 

Microbial inhibition tests are extremely sensitive for -lactam antibiotics, primarily penicillin, but mostly are more than 100-fold less sensitive for other commonly used antibacterials such as macrolides, sulfonamides, tetracyclines, or chloramphenicol (4, 5). Therefore, inhibition tests usually classify residues as belonging to the -lactam group. Antibiotics other than -lactams and sulfonamides can be detected by use of the enzyme penicillinase and aminobenzoic acid, respectively (1, 6). 

However, recent investigations on the effect of the tissue matrix on the detection limits attained by this test have indicated that ceftiofur, sulfonamides, streptomycin, and some macrolide antibiotics cannot be detected in intact meat with the plates and the bacterial strains prescribed in the European four-plate test (81, 82). Two plates of this system were not found suitable for screening sulfamethazine or streptomycin at levels far above the MRL the third plate detected tetracyclines and -lactams up to the MRL levels whereas the fourth was sensitive to -lactams and some but not all macrolides. Detection, on the other hand, of the fluoroquinolones enrofloxacin and ciprofloxacin could only be made possible by an additional Escherichia coli plate not included in the four-plate test. 

The HPLC-receptorgram assay combined the advantages of HPLC separation with the multiresidue detection of the Charm II tests. The procedure was tested for identification and quantitation of the most common veterinary drugs at regulatory levels or lower. It was validated for 40 individual drugs from seven antibiotic families 10 /3-lactams, 13 sulphonamides, 8 tetracyclines, 4 macrolides, 3 amphenicols, and other miscellaneous antimicrobials. This procedure combined a simple aqueous extraction and SPE with HPLC fractionation of individual drugs. Final identification and quantitation was achieved with the Charm II test. A drug contaminant could be identified in less then 3 hours (50). 

Link, N., W. Weber, and M. Fussenegger. 2007. A novel generic dipstick-based technology for rapid and precise detection of tetracycline, streptogramin and macrolide antibiotics in food samples. J. Biotechnol. 128 668-680. 

Presence (+) or absence (—) of acyltransferase activity for 16-membered macrolide antibiotics. b Presence (+) or absence (—) of hybridizing band(s) in Southern blot analysis using acyA or acyBl as a probe. " Weakly hybridizing bands were detected. 

Pappa-Louisi, A. Papageorgiou, A. Zitrou, A. Sotiro-poulos, S. Georgarakis, E. Zougrou, F. Study on the electrochemical detection of the macrolide antibiotics clarithromycin and roxithromycin in reversed-phase high-performance liquid chromatography. J. Chromatogr. B Biomed. Sci. Appl. 2001, 755, 57-64. 

The performance of HSCCC-ESI-MS was evaluated by analyzing erythromycins and didemnins [10]. Because erythromycins (macrolide antibiotics) show weak UV absorbance and cannot be detected easily with a conventional UV detector, mass spectrometric detection is a very useful technique for analysis of these antibiotics. A mixture of erythromycin A (Er-A,... 

Hedenmo, M. Eriksson, B.-M. Liquid Chromatographic Determination of the Macrolide Antibiotics Roxithromycin and Clarithromycin in Plasma by Automated Sohd-Phase Extraction and Electrochemical Detection, J. Chromatogr. A 692(1-2), 161-166(1995). 

Hedenmo, M. Eriksson, B.-M. Liquid chromatographic determination of the macrolide antibiotics roxithromycin and clarithromycin in plasma by automated solid-phase extraction and electrochemical detection. J.ChromatognA, 1995, 692, 161-166... 

Ding et al. described an automated on-line SPE-LC-MS/MS method for the determination of macrolide antibiotics, including erythromycin, roxithromycin, tylosin, and tilmicosin in environmental water samples. A Capcell Pak ME Ph-1 packed-column RAM was used as SPE column for the concentration of the analytes and clean-up of the sample. One millilitre of a water sample was injected into the conditioned SPE column, and the matrix was washed out with 3 ml high-purity water. By rotation of the switching valve (see Fig. 4.2), macrolides were eluted in the back-flush mode and transferred to the analytical column. The limits of detection and quantification obtained were 2-6 and 7-20 ng/1, respectively, which is suitable for trace analysis of macrolides. The intra- and inter-day precisions ranged within 2.9-12% and 3.3-8.9%, respectively. At the three fortification concentrations tested (20, 200, and 2000 ng/1), recoveries of macrolides ranged from 86.5% to 98.3%. 

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