Effect of liver enzymes on the mutagenicity of nitroheterocyclic compounds: activation of 3a,4,5,6,7,7a-hexahydro-3-(1-methyl-5-nitro-1H-imidazol-2-yl)- 1,2-benzisoxazole and deactivation of nitrofurans and nitroimidazoles in the Ames test.

The effect of liver enzymes (S9) on the mutagenic response of nitroimidazoles and nitrofurans in the Ames test was evaluated with strain TA100. A diminished response was observed with a 5-nitroimidazole and 5-nitrofurans when the S9 preparation was incorporated in the agar layer. Preincubation with S9 under anaerobic conditions prior to adding the bacteria resulted in a greater and sometimes complete loss of the mutagenic effect. The loss of mutagenic potency was dependent on both incubation time and quantity of the S9 preparation. These results suggest that metabolites formed after reductive metabolism are neither mutagenic (presumably due to the loss of the nitro group) nor capable of activation to mutagenic metabolites. One 5-nitroimidazole, 3a,4,5,6,7,7a-hexahydro-3-(1-methyl-5-nitro -1H-imidazol-2-yl)-1,2-benzisoxazole (MK-0436), gave an increased response in the presence of S9 in both the plate test and when preincubated under aerobic conditions. 7 metabolites were produced by the incubation. 4 monooxygenated metabolites were isolated and found to possess significant mutagenic activity. 2 synthetic dihydroxy analogs were more mutagenic than MK-0436. Similar results were obtained with S9 preparations from human liver and the livers of control, phenobarbital and Aroclor-1254 pretreated rats.

Identification of in vitro (rat liver postmitochondrial S9 fraction) metabolites of the antiprotozoal agent 3a,4,5,6,7,7a-hexahydro-3-(1-methyl-5-nitro-1H-imidazol-2-yl)-1,2-benzisoxazole .

Twelve in vitro oxygenated metabolites of 3a,4,5,6,7,7a-hexahydro-3-(1-methyl-5-nitro-1H-imidazol-2-yl)-1,2-benzisoxazole (MK-0436) were produced by incubation of this antiprotozoal agent with the postmitochondrial supernatant (S9) fraction isolated from the livers of rats treated with phenobarbital. Metabolite structure elucidation was achieved using NMR and mass spectrometry. Seven monohydroxy and two dihydroxy metabolites were fully characterized; two other metabolites were partially characterized as dihydroxy derivatives of the drug. The major in vitro metabolite is the 5 axial hydroxy compound, and a minor metabolite is the corresponding ketone. In all cases metabolite formation involved biotransformation on the hexahydrobenzisoxazole ring.

Urinary metabolites of 3a,4,5,6,7,7a-hexahydro-3-(1-methyl-5-nitro-1H-imidazol-2-yl)-1,2-benzisoxazole in the dog.

The antiprotozoal drug 3a,4,5,6,7,7a-hexahydro-3-(1-methyl-5-nitro-1H-imidazol-2-yl)-1,2-benzisoxazole (I), which exhibits activity against trypanosomiasis, is also antibacterial in vivo. Since the urine from a dog dosed with I showed a broader spectrum of antibacterial activity than I itself, metabolites from this urine were isolated and partially characterized. The metabolites were mono- and dihydroxy-substituted species with the hydroxyl groups on carbons 4--7 of the hexahydrobenzisoxazole ring. These observations led to the synthesis of several such hydroxy derivatives of I, and their properties fully supported the proposed positions of metabolic hydroxylation. One synthetic compound, the 6,7-cis-dihydroxy compound, exhibited higher antibacterial activity against Salmonella schottmuelleri in mice and greater trypanocidal activity in vivo against Trypanosoma cruzi (Brazil strain) than I.

Pharmacokinetics and comparative pharmacology of cefoxitin and cephalosporins.

Features of the distribution, metabolism, elimination, and pharmacokinetics of the cephalosporins and cefoxitin must be considered when concentrations of these drugs in biological fluids are interpreted. The extensive (approximately 86%) binding of cefazolin to plasma protein may account for the smaller volume of distribution and slower rate of renal clearance than are observed for cefoxitin, which is less extensively (73%) bound to protein. Results of microbiological assays of drug in urine may be influenced by the extent of metabolism of the drugs, which is 33% for cephalothin but less than 2% for cefoxitin. Elimination of cephalosporins and cefoxitin occurs by both glomerular filtration and tubular secretion and can be inhibited by the concurrent administration of probenecid. The pharmacokinetics of cefoxitin may be described by a linear, two-compartment, open model that has been used to predict levels of drug achieved in serum and urine after various dose regimens, including administration by intravenous bolus or infusion. The bioavailability of intramuscularly administered cefoxitin is equivalent to that of intravenously administered cefoxitin and is 90% complete within 3-4 hr after the dose is given.

Mutagenic evaluation of nitroparaffins in the Salmonella typhimurium/mammalian-microsome test and the micronucleus test.

Three nitroparaffins (nitroethane, 1-nitropropane, and 2-nitropropane) were studied in the Salmonella typhimurium/mammalian microsome (Ames) test, with and without microsomal activation systems. Nitroethane and 2-nitropropane also were studied in an in vivo mutagenic (micronucleus) test. These studies were undertaken because these solvents are widely used in the chemical and pharmaceutical industries and 2-nitropropane was reported to cause liver cancer in rats exposed by the inhalation route. Neither nitroethane nor 1-nitropropane was active in the Ames test with Salmonella tester-strains TA1537, TA92, TA98, or TA100. However, 2-nitropropane produced a significant increase in revertants in all of these tester strains, particularly strain TA100, where 3 microliter/plate doubled the number of revertants in the presence of microsomal enzymes. Negative results were obtained with both nitroethane and 2-nitropropane in micronucleus tests. These studies have shown that 2-nitropropane has the potential for causing point mutations in a microbial test system. However, this compound probably will not cause a chromosome mutation of the clastogenic type.

Effect of lidocaine on the absorption, disposition and tolerance of intramuscularly administered cefoxitin.

The use of lidocaine HCL solution at concentrations of 0.5 and 1.0% to reconstitute sodium cefoxitin relieves the pain associated with intramuscular injections of the antibiotic. Cefoxitin absorption by the intramuscular route is initially rapid and is virtually complete. Peak serum concentrations, corresponding to about one-half those of a comparable intravenous infusion, are achieved in 30 min. Continuing absorption tends to maintain higher serum concentrations for longer times. Renal clearance and serum half-life of cefoxitin do not appear to be affected by lidocaine at its effective anaesthetic concentrations.

Mutagenic evaluation of ronidazole.

Ronidazole was evaluated for mutagenic potential using in vitro microbial tests and in vivo studies in mice. The microbial test used the histidine requiring mutants of Salmonella typhimurium with and without a rat liver microsomal activation system (Ames test). The studies in mice included the dominant lethal test, micronucleus test and cytogenetic assays. Ronidazole was given orally in doses of 50, 100 and 200 mg/kg/day in the in vivo studies. In the dominant lethal test, groups of male mice were treated for five consecutive days before being mated with untreated females. In the micronucleus test, the mice were administered the compound for 2 or 5 consecutive days; they were killed 6 h after the last dose and bone marrow was examined for the presence of micronuclei in developing erythrocytes. In the cytogenetic assays, bone marrow cells in metaphase were examined for chromosome aberrations, 6, 24 and 48 h after mice were treated acutely with the test compound. In addition, similar examinations of chromosomes were made on mice given five consecutive dosages of ronidazole and killed 6 h after the last dose. The results of the various in vivo studies did not suggest that ronidazole would be mutagenic for the mammal. Ronidazole at concentrations of 10 and 50 mug/plate was found to increase the number of back mutations of missense mutants in the in vitro bacterial test. This finding confirms the results of Voogd et al. [19]. Incorporation of the microsomal activation system had no effect on the mutagenic capability of the test compound. In conclusion, although ronidazole was shown to be mutagenic in in vitro bacterial systems, the in vivo systems did not suggest that the compound would be mutagenic for the mammal.

Comparative clinical pharmacology of intravenous cefoxitin and cephalothin.

Intravenous doses of 0.5, 1, and 2 g cephalothin and cefoxitin, a semi-synthetic cephamycin antibiotic highly resistant to bacterial cephalosporinase, were infused over a period of 3 minutes into 18 normal adult males by a randomized, crossover design. Serum and urine data on cefoxitin best fit a two-compartment open model. Serum concentrations following cefoxitin were higher and more prolonged and urine recoveries higher than those following equal doses of cephalothin. The terminal serum half-life of cefoxitin was longer at all dose levels. Renal clearance of cephalothin-like activity exceeded that of cefoxitin, which may possess dose-dependent kinetics. Whereas cephalothin has been reported to metabolize by greater than 35% to the less active desacetyl form, cefoxitin was metabolized by 0.1 to 6% to the descarbamyl form in individual subjects.

Serum concentrations of ampicillin and probenecid and ampicillin excretion after repeated oral administration of a pivampicillin-probenecid salt (MK-356).

Twenty male volunteers received oral doses (2100, 1050, and 525 mg) of a pivampicillin-probenecid salt in a 1 to 1 molar ratio (MK-356) at 12 hour intervals. After each dose peak serum concentrations of probenecid were observed 2 hours later than peak concentrations of ampicillin. Following the first dose of MK-356 the apparent elimination rate of ampicillin was dose-dependent and did not follow first order kinetics, as it showed a longer apparent half life after a higher dose. An equal dose of MK-356 administered 12 hours later caused an increase in the peak serum ampicillin level greater than expected from the concentration of ampicillin after the preceding dose. In twelve male volunteers who received at random 525 mg of MK-356 or 350 mg of pivampicillin, each three times daily for 4 days, the areas under the ampicillin concentration curve were the same after the first or last dose of either drug. When 2100 or 1050 mg of MK-356 was taken as an initial dose, 30 to 40 per cent of the ampicillin was recovered from urine in the ensuing 12 hours. The results indicate that when at least 400 mg probenecid was coadministered twice daily with 700 mg pivampicillin (MK-356), the peak serum concentrations of ampicillin were increased and its elimination rate slowed following successive doses.

Effects of rate of infusion and probenecid on serum levels, renal excretion, and tolerance of intravenous doses of cefoxitin in humans: comparison with cephalothin.

Using a randomized crossover design, 1-g intravenous doses of cephalothin and cefoxitin, a cephalosporinase-resistant cephamycin, were infused into 12 normal adult males over periods of 120, 30, and 3 min, the last with and without prior intravenous infusions of probenecid (1 g). Mean peak serum concentrations of antibiotic activity after cephalothin infusions were 23, 56, 103, and 102 mug/ml, respectively, and after cefoxitin infusions they were 27, 74, 115, and 125 mug/ml, respectively. Probenecid treatment prolonged the terminal serum half-life of cephalothin-like activity from 0.52 to 1.0 h, and of cefoxitin from 0.68 to 1.4 h. In contrast to cephalothin, which was found to be metabolized about 25% to the less active desacetyl form, cefoxitin was metabolized less than 2% to the virtually inactive descarbamyl form, as judged from urinary recoveries. Neither antibiotic displayed detectable organ toxicity. Of 300 recent clinical isolates of gram-negative bacilli other than Pseudomonas spp., 83% were susceptible to cephalothin but 95% were susceptible to cefoxitin. Organisms resistant to cephalothin but susceptible to cefoxitin included strains of Escherichia coli, Proteus vulgaris, Klebsiella spp., Serratia marcescens, Enterobacter spp., and Bacteroides spp.