Concentrations of progesterone in milk of cows administered an intravaginal progesterone insert.

Milk from pregnant cows contains concentrations of progesterone (P4) considered safe for human consumption. The objective of this study was to determine if concentrations of P4 in milk during administration of an intravaginal progesterone insert (CIDR insert) are less than concentrations of P4 in milk associated with pregnancy. Results have implications for human use of milk from cows receiving CIDR inserts. Holstein cows (N = 64; > 40 and < 150 d after calving) were administered 25 mg of PGF2alpha i.m. (study d 0) and 20 cows detected in estrus from 2 to 4 d later were assigned randomly to either control (N = 10; no further treatment) or CIDR insert (N = 10; 1.38 g of P4) inserted on study d 17 (14 +/- 1 d after estrus) and removed 7 d later. Composite milk samples were collected contemporaneously from each of the 20 estrous cycling cows and from 10 pregnant cows (> or = 60 and < or = 220 d of gestation) twice daily from study d 17 to 27. Concentrations of P4 in defatted milk samples were quantified using a validated radioimmunoassay. Mean logs of areas under the curve of concentrations of P4 from the afternoon on study d 17 through the afternoon on study d 27 were 3.05 ng day/ml for control, 3.33 ng day/ml for CIDR insert, and 3.81 ng day/ml for pregnant cows. Therefore, increased P4 due to pregnancy was 0.76 ng day/ml (3.81-3.05), whereas the increase in P4 due to CIDR insert was only 0.28 ng day/ml (3.33-3.05). Applying a 95% confidence interval to 0.28 ng day/ml provided an upper value of 0.70 ng day/ml, lower than the increase due to pregnancy. Because milk from pregnant cows is considered safe for human consumption, it follows that milk from cows administered CIDR inserts should also be considered safe, based on concentrations of P4.

Quantitation of spectinomycin residues in bovine tissues by ion-exchange high-performance liquid chromatography with post-column derivatization and confirmation by reversed-phase high-performance liquid chromatography-atmospheric pressure chemical ionization tandem mass spectrometry.

Determinative and confirmatory methods of analysis for spectinomycin residue in bovine kidney, liver, muscle and fat have been developed. The determinative method is a single-column HPLC ion-exchange procedure that incorporates a two-step post-column oxidation of the secondary amines to primary amines followed by derivatization with o-phthalaldehyde. The method was validated in all tissues to a low-end concentration of 0.10 micrograms/g (limit of quantitation) and to a high-end of 10 micrograms/g for kidney, which is the rate-limiting tissue for residues of spectinomycin. The recovery of spectinomycin from all tissues was > 80% and the variability (R.S.D.) was generally < 10%. For liver, an alternative reversed-phase HPLC separation was required for incurred-residue samples. The confirmatory method employed an atmospheric pressure chemical ionization-MS-MS approach utilizing a rapid reversed-phase HPLC system with a mobile phase of methanol and 1% acetic acid. The protonated molecular ion for spectinomycin at m/z 333 produced four diagnostic reaction-product ions at 98, 116, 158 and 189 for confirmation. The method was validated to a lower limit of confirmation of 0.10 micrograms/g.

Pirlimycin residue in bovine liver--a case of reverse metabolism.

Samples of liver obtained from twenty dairy cows treated with pirlimycin hydrochloride (Pirsue) by the intramammary route and slaughtered at five different time intervals out to 28 days were incubated at room temperature and at 37 degrees C and analyzed by two HPLC-MS methods to examine the metabolite profile of the residue and to establish the quantitative relationship of the residue components. The evidence from these experiments suggests that the metabolism of pirlimycin in postmortem bovine liver is somewhat reversible, where the concentration of parent pirlimycin increases in the incubated liver with a concomitant reduction in the concentration of the pirlimycin sulfoxide metabolite. This increased parent-drug residue phenomenon is limited to liver and was not observed in kidney or muscle. The highest relative change in concentration was observed for low level biologically incurred samples and appeared to be a saturable process following Michaelis-Menten kinetics. All of the evidence collected appears to indicate that the phenomenon is the result of residual enzyme activity present in the postmortem liver samples and likely involves some type of reductase enzyme capable of reducing sulfur-oxidized substrates to the sulfide state. No attempts were made to identify specific enzymes responsible for this phenomenon.

Ceftiofur hydrochloride: plasma and tissue distribution in swine following intramuscular administration at various doses.

Twelve mixed-breed swine (26.5-42.5 kg) received three daily intramuscular (i.m.) doses of 14C-ceftiofur hydrochloride. Three males and three females, received 6.76 +/- 0.83 mg of 14C-ceftiofur free acid equivalents (CFAE)/kg body weight (b.w.)/day, while the other group received 4.41 +/- 0.97 mg.CFAE/kg b.w./day. The swine were slaughtered 12 h following the last dose. Total dose accountability for the 6.76 mg dose was 91.44 +/- 16.11% (72.51% in urine; 12.63% in faeces). For the 4.41 mg dose, accountability was 100.35 +/- 20.45% (82.48% in urine; 12.85% in faeces). Within the tissues used for residue monitoring, the highest concentrations were observed in the kidneys (10.68 and 6.33 micrograms.CFAE/g for the 6.76 and 4.41 mg doses, respectively), followed by the injection sites, lungs, liver and muscle. In a separate study, twelve mix-breed swine (23.1-39.7 kg) received 14C-ceftiofur hydrochloride at 3.08 mg.CFAE/kg b.w. once daily for 3 days. Two males and two females were slaughtered at either 12, 72 or 120 h after the last dose. Total dose accountability for the 3.08 mg dose was > 83% (> 68% in urine; > 13% in faeces). In swine slaughtered 12 h after last dose, residue concentrations closest to the safe concentrations were observed in the kidneys (3.62 micrograms.CFAE/g), followed by the injection sites, lungs, liver and muscle.

Identification and determination of pirlimycin residue in bovine milk and liver by high-performance liquid chromatography-thermospray mass spectrometry.

Determinative and confirmatory methods of analysis for pirlimycin (I) residue in bovine milk and liver have been developed based on HPLC-thermospray (TSP) MS. Milk sample preparation consisted of precipitating the mill proteins with acidified acetonitrile followed by a solvent partitioning with a mixture of n-butyl chloride and hexane extraction of I from the aqueous phase into methylene chloride (MC), and solid-phase extraction clean-up. For liver, samples (2 g) were extracted with 0.25% trifluoroacetic acid in acetonitrile. The aqueous component was released from the organic solvent with n-butyl chloride. The aqueous solution was reduced in volume by evaporation, basified with ammonium hydroxide, then extracted with MC. The MC was evaporated to dryness and the dried residue reconstituted in 2.0 ml of 0.1 M ammonium acetate for analysis. A chromatographically resolved stereoisomer of I with TSP-MS response characteristics identical to I was used as an internal standard (I.S.) for quantitative analysis based on the ratio of peak areas of I to I.S. in the protonated molecular-ion chromatogram at m/z 411.2. The method for milk was validated by the analysis of control milk samples spiked with I at concentrations from 0.05 to 0.8 micrograms/ml. The overall recovery of pirlimycin across this concentration range was 95.4% +/- 8.7%. The limit of quantitation (LOQ) and limit of confirmation (LOC) of the method were validated to be 0.05 micrograms/ml and 0.10 micrograms/ml, respectively. The method for liver was validated by the analysis of control liver samples spiked with I at concentrations ranging from 0.025 to 1.0 micrograms/g. The overall recovery of pirlimycin was 97.6% +/- 5.1% in this concentration range. The validated limit of quantitation (LOQ) and limit of confirmation (LOC) of the method were 0.025 micrograms/g and 0.10 micrograms/g, respectively. Four diagnostic ions for I were monitored for confirmation: the pseudo-molecular ions (M+H)+ at m/z 411.2 (35Cl) and m/z 413.2 (37Cl), and fragment ions at m/z 375.2 and 158.1. Confirmatory criteria were defined for these assays.

Depletion of intramuscularly injected ceftiofur from the milk of dairy cattle.

Ceftiofur sodium, a new broad-spectrum cephalosporin, has been approved in the US, Canada, and several other countries throughout the world to treat bovine respiratory disease in cattle and dairy cows. In Experiment 1, 6 lactating cows were intramuscularly treated with 2.29 mg of [14C]ceftiofur/kg of BW daily for 5 d. In Experiment 2, 30 additional cows at three locations were similarly treated with 2.2 mg of ceftiofur (unlabeled)/kg of BW. Milk was collected every 12 and 24 h after each dose and every 12 h up to 5 d after the last dose. The majority of milk samples, both during treatment (12 and 24 h after each dose) and after the last dose (up to 5 d following ceftiofur treatment), were negative by screening procedures based on microbial inhibition (Delvotest-P, Bacillus stearothermophilus disk assay, and cylinder plate assays). The receptor-binding Charm Test II assay, which has a limit of detection of .005 ppm of ceftiofur, gave positive tests for milk samples up to 48 h following treatment. When the Charm Test II assay is used with .008 IU/ml of penicillin as a positive control, 44% of the samples from individual cows were negative at 12 h posttreatment. Ninety percent of the samples from individual cows were negative at 24 h after the last treatment. The use of ceftiofur in dairy cattle in accordance with the label directions does not result in total residues in milk higher than the FDA-calculated safe concentration of 1-ppm ceftiofur equivalents. The milk from individual cows did not test positive by the commercial screening assays examined in this study, except for the Charm Test II. The Charm Test II was 90% negative using the Charm Sciences criteria at 24 h after the last treatment.

Tissue concentrations of clindamycin after multiple oral doses in normal cats.

Eighteen normal cats were randomly allocated into two blocks with three treatment groups and dosed orally with clindamycin aqueous solution for 10 days at a dosage rate of 5.5 mg/kg twice daily (Group 1), 11 mg/kg twice daily (Group 2), or 22 mg/kg once daily (Group 3). At the end of dosing, all cats were killed and tissues were taken for clindamycin concentration analysis. Clindamycin was extracted from tissues using solid-phase extraction columns followed by microbiological assay of clindamycin using a cylinder plate assay using M. luteus. Recovery from each tissue was determined by inoculating known concentrations of clindamycin into drug-naive tissues and comparing the observed concentration from the expected concentration. Confirmation that the bioassay detected clindamycin and not N-desmethylclindamycin, its active metabolite, was done using gas-chromatography-mass-spectrometry. Concentrations were highest in the lung, with tissue:serum ratios greater than 3 in all groups. Concentrations were higher in Group 3 than Group 1 (P less than 0.05). Only liver concentrations in Group 3 were statistically higher than in Group 2, although all tissues except bone marrow and CSF had numerically higher concentrations in Group 3 than Group 2. The tissue:serum ratio was greater than 1 in all tissues studied except bone, cerebrospinal fluid, brain, and skeletal muscle.