Degradation of ronidazole by electrochemically simultaneously generated persulfate and ferrous ions.

Nitroimidazoles are found in pharmaceuticals and personal care products (PPCPs) and, when discharged into the environment, have adverse effects on human health and survival. Advanced oxidation technologies (AOTs) based on persulfate (PS) can rapidly and efficiently degrade organic pollutants via strong oxidizing radicals under activation conditions. This study investigated the degradation of ronidazole (RNZ) by indirect electrolytic generation of PS and its activator, ferrous ion (Fe2+). An electrochemical system was developed, with a high concentration of PS generated at the anode while the activator Fe2+ was produced at the cathode. It showed that ammonium polyphosphate (APP) could effectively promote the electrolysis of PS. A high current efficiency (88%) at the anode could be obtained after 180 min at a high current density (300 mA cm-2). However, Fe2+ was inhibited at the cathode due to material control. The degradation of RNZ in the Fe2+/PS system generated from the electrochemical system was also explored. Increasing PS concentration and Fe2+/PS ratio were beneficial to the RNZ degradation. In homogeneous reactions, the degradation efficiency of RNZ could be improved by decreasing the Fe2+ addition rate through a peristaltic pump. Five intermediates were also detected and the degradation pathways were proposed. These findings provide a new method and mechanism for rapid and efficient degradation of RNZ.

Transfer of nitroimidazoles from contaminated beeswax to honey.

Nitroimidazoles are not authorised for the treatment of honey bees in the European Union. However, they can be found in honey largely because they are illegally used in apiculture for the treatment of Nosema. The aim of the study was to examine the possible transfer of nitroimidazoles (metronidazole, ronidazole, dimetridazole and ipronidazole) from contaminated beeswax to honey. The wax foundations fortified with a mixture of four nitroimidazoles at three concentration levels (1000, 10,000 and 100,000 µg kg-1) were placed in beehives to let the honeybees (Apis mellifera L.) draw out the contaminated wax foundations to honeycombs. At 1 month from the start, the frames filled with capped honey were removed from the hives for a first sampling of honey. Next, the honeycombs were further incubated for 5 months in the laboratory at 35°C and sampled monthly. In the sampled honey, the concentrations of nitroimidazoles and their main metabolites (hydroxymetronidazole, 2-hydroxymethyl-1-methyl-5-nitroimidazole, hydroxyipronidazole) were determined by LC-MS/MS and compared with those determined in the nitroimidazole-containing wax foundations. Each of the tested nitroimidazoles could migrate from beeswax to honey kept in the contaminated combs at each tested concentration level. Higher maximum concentrations of residues in honey sampled from contaminated combs at 1000, 10,000 and 100,000 µg kg-1 were observed for metronidazole (28.9, 368.5 and 2589.4 µg kg-1 respectively) and ronidazole (27.4, 232.9 and 2351.2 µg kg-1 respectively), while lower maximum concentrations were measured for dimetridazole (0.98, 8.4 and 67.7 µg kg-1) and ipronidazole (0.9, 7.9 and 35.7 µg kg-1 respectively). When we took into account that a frame completely filled with honey on both sides of the comb contained 110 g of beeswax and 2488 g of honey, and that this ratio was constant, then maximum amounts of initial metronidazole, ronidazole, dimetridazole and ipronidazole that migrated from contaminated wax foundations to honey could be calculated: 65-89%, 55-63%, 1.7-2.7% and 1.4-2.3%, respectively.

Covalent interaction of 5-nitroimidazoles with DNA and protein in vitro: mechanism of reductive activation.

Human hepatic microsomal enzymes catalyzed the NADPH-dependent anaerobic reductive activation of [1-14C]metronidazole [1-(2-hydroxyethyl)-2-methyl-5-nitroimidazole] and [4,5-14C]ronidazole [(1-methyl-5-nitroimidazole-2-yl)methyl carbamate] to species that became covalently bound to proteins. Due to the low efficiency of the enzyme-catalyzed covalent binding of metronidazole, the stoichiometry of anaerobic reductive activation was studied with dithionite as the reductant. Two moles of dithionite was consumed per mole of [1-14C]metronidazole for maximal covalent binding to either DNA or immobilized sulfhydryl groups, demonstrating that four electrons are required for the reductive activation of metronidazole. These data implicate the involvement of a hydroxylamine in covalent binding. Maximal covalent binding of [4,5-14C]ronidazole to DNA also required four-electron reduction, consistent with previous studies of the covalent binding of this agent to immobilized sulfhydryl groups [Kedderis et al. (1988) Arch. Biochem. Biophys. 262, 40-48]. Studies of the covalent binding of variously radiolabeled ronidazole molecules to DNA suggested that the imidazole ring was intact while greater than 80% of the 2-carbamoyl group and the C4 proton were not present in the DNA adduct. Studies of both the chemical and human hepatic microsomal reduction of [4-3H]metronidazole demonstrated that covalent binding occurred with the stoichiometric loss of this label, implicating binding at the C4 position. These results suggest that the reductive activation of 5-nitroimidazoles generally proceeds via four-electron reduction to form hydroxylamines followed by nucleophilic attack at C4.

Mechanism of reductive activation of a 5-nitroimidazole by flavoproteins: model studies with dithionite.

The flavoprotein nitroreductases NADPH:cytochrome P-450 reductase and xanthine oxidase catalyzed the cofactor-dependent anaerobic nitro group reduction and covalent binding to protein sulfhydryl groups of the 5-nitroimidazole substrate ronidazole [1-methyl-5-nitroimidazole-2-yl)-methyl carbamate). Studies with variously radiolabeled ronidazole molecules demonstrated that the imidazole ring was intact while greater than 80% of the C-4 3H and 2-carbamoyl group were lost from the covalently bound product. The stoichiometry of cofactor consumption during the enzyme-catalyzed reduction of the substrate could not be determined, so a model nitroreductase system which utilized dithionite as the reductant and agarose-immobilized cysteine as the target for alkylation was developed. Two moles of dithionite was consumed per mole of substrate for maximal reduction of uv absorbance due to the nitro group, for maximal release of C-4 3H, and for maximal covalent binding to agarose-immobilized cysteine. These results indicate that four electrons are required for the reductive activation of the substrate, consistent with formation of a hydroxylamine reactive intermediate. Covalent binding of variously radiolabeled substrate molecules after dithionite reduction exhibited the same labeling pattern as flavoprotein-catalyzed covalent binding, suggesting that covalent binding is mediated by the same species in both chemical and biological systems. The data are consistent with a mechanism where the substrate undergoes four-electron reduction to form a hydroxylamine, which is susceptible to nucleophilic attack at C-4. When water attacks C-4, the 2-carbamoyl group can eliminate to form a Michael-like acceptor which adds thiols at the 2-methylene position.

Studies on the mechanism of activation and the mutagenicity of ronidazole, a 5-nitroimidazole.

Substantial evidence implicates the obligatory nucleophilic attack by water at C4 for the elimination of the carbamate and subsequent immobilization by electrophilic attack on protein thiols. Consequently, the strong correlation between the structural requirements for protein alkylation and for mutagenicity in TA100 suggests a possible role of nucleophilic addition at C4 or at the 2-methylene carbon for the expression of mutagenicity. Further studies directed at evaluating this possibility are currently in progress.

[Preclinical research on Pharmachim's ronidazole]. / Predklinichni izsledvaniia na ronidazol "Farmakhim".

Ronidazol-Pharmachim (RPh) in the form of 10 per cent water-soluble powder was studied in terms of resistance to various values of pH of the surrounding medium, acute toxicity, the species-specific tolerance of various mammals of it, its subchronic toxicity and residual amounts with pigs. The preparation was found to be stable in water solutions (pH 5.0 to 9.0) in the course of at least 96 hours, and in n HCl--for more than a month. At oral administration LD50 of RPh was 34000 mg (2982 divided by 3876) per kg for albino rats weighing 150-200 g. At intraperitoneal injection in the form of pure substance LD50 was 1500 mg (1320 divided by 1690) per kg. With pigs at single oral application at the rates of 20, 60, and 180 mg/kg (= 20-30 times the ED50) RPh was tolerated with no changes in the behaviour and appetite. When used with the drinking water at rates of 60, 180, and 300 ppm in the course of 30 days there was no unfavourable effect on the gain and the blood picture and no injury of the structure of viscera of pigs. In concentrations of 180 ppm it was shown to stimulate the growth of pigs. The withdrawal time with pigs given RPh with the drinking water was at least 72 hours after the preparation was offered last.

Drug residue formation from ronidazole, a 5-nitroimidazole. VII. Comparison of protein-bound products formed in vitro and in vivo.

In vivo experiments were conducted with ronidazole radiolabelled in the 2-14CH2-, 4,5-14C-, N-14CH3- and 4-3H-positions. The hepatic protein-bound residues, assessed by the radioactivity of exhaustively washed protein samples, were independent of the radiolabel position and occurred with 4-3H loss (greater than 80%) in excellent agreement to previous results obtained in vitro with anaerobic incubations of liver microsomes (Miwa et al., Chem. Biol. Interact., 41 (1982) 297). HPLC analysis of acid hydrolyzed in vivo protein-bound residues, obtained from [2-14CH2] ronidazole, produced a radiochromatographic profile which was virtually identical to that obtained from a similarly treated in vitro sample. Moreover, almost quantitative (76-96%) liberation of radiolabelled methylamine was obtained from hydrolysates of in vivo and in vitro residue samples formed from [N-14CH3] ronidazole. With 4,5-ring labeled ronidazole the distribution of total radioactivity of the protein hydrolysate on cation exchange resin and the fraction of the residue recovered as oxalic acid were nearly identical for the in vivo and in vitro products. We interpret these data to indicate that ronidazole alkylates proteins with retention of most of the carbon framework of the molecule, in vivo. It is also concluded that the in vitro model, previously used to examine the mechanism of protein alkylation, accurately reflects the salient process initially occurring in the intact animal during the formation of protein-bound residues of this drug.

Drug residue formation from ronidazole, a 5-nitroimidazole. V. Cysteine adducts formed upon reduction of ronidazole by dithionite or rat liver enzymes in the presence of cysteine.

When ronidazole (1-methyl-5-nitroimidazole-2-methanol carbamate) is reduced by either dithionite or rat liver microsomal enzymes in the presence of cysteine, ronidazole-cysteine adducts can be isolated. Upon reduction with dithionite ronidazole can react with either one or two molecules of cysteine to yield either a monosubstituted ronidazole-cysteine adduct substituted at the 4-position or a disubstituted ronidazole-cysteine adduct substituted at both the 4-position and the 2-methylene position. In both products the carbamoyl group of ronidazole has been lost. The use of rat liver microsomes to reduce ronidazole led to the formation of the disubstituted ronidazole-cysteine adduct. These data indicate that upon the reduction of ronidazole one or more reactive species can be formed which can bind covalently to cysteine. The proposed reactive intermediates formed under these conditions may account for the observed binding of ronidazole to microsomal protein and the presence of intractable drug residues in the tissues of animals treated with this compound. They may also account for the mutagenicity of this compound in bacteria.

Drug residue formation from ronidazole, a 5-nitroimidazole. VI. Lack of mutagenic activity of reduced metabolites and derivatives of ronidazole.

The potential toxicity of ronidazole residues present in the tissues of food-producing animals was assessed using the Ames mutagenicity test. Since ronidazole is activated by reduction, reduced derivatives of ronidazole and metabolites formed by enzymatic reduction of ronidazole were tested for mutagenicity. When tested at levels several orders of magnitude higher than that at which ronidazole was mutagenic, 5-amino-4-S-cysteinyl-1,2- dimethylimidazole , a product of the dithionite reduction of ronidazole in the presence of cysteine, the 5-N-acetylamino derivative of ronidazole and 5-amino-1,2- dimethylimidazole all lacked mutagenic activity in Ames strain TA100. The metabolites of ronidazole formed by the incubation of ronidazole with microsomes under anaerobic conditions were also not mutagenic. These data demonstrate that although ronidazole is a potent mutagen, residues from it which may be present in the tissues of food-producing animals lack any mutagenic activity.

Drug residue formation from ronidazole, a 5-nitro-imidazole. IV. The role of the microflora.

When radioactive 1-methyl-5-nitroimidazole-2-methanol carbamate, ronidazole, labeled at the 4,5-ring positions was administered orally to germ-free and conventional rats, a much larger fraction of the radioactivity was excreted in the feces of the conventional animals. Determination of the total radioactive residues present in the carcass, blood, plasma, liver, fat and kidney 5 days after dosing indicated that the carcass of the germ-free animals contained a greater quantity of residue than that of conventional rats. On the other hand, the blood of the conventional animals contained a much higher level of radioactivity than that of the germ-free animals. These results show that while the microflora influence the distribution of the drug their presence is not obligating for the formation of persistent tissue residues in rats dosed with ronidazole.

Drug residue formation from ronidazole, a 5-nitroimidazole. I. Characterization of in vitro protein alkylation.

The metabolic activation of [14C]ronidazole by rat liver enzymes to metabolite(s) bound to macromolecules was investigated. The alkylation of protein by [14C]ronidazole metabolite(s) was catalyzed most efficiently by rat liver microsomes, in the absence of oxygen utilizing NADPH as a source of reducing equivalents. Based on a comparison of total ronidazole metabolized versus the amount bound to microsomal protein, approximately one molecule alkylates microsomal protein for every 20 molecules of ronidazole metabolized. Protein alkylation was strongly inhibited by sulfhydryl-containing compounds such as cysteine and glutathione whereas methionine had no effect. Based on HPLC analysis of ronidazole, cysteine was found not to inhibit microsomal metabolism of ronidazole ruling out a decrease in the rate of production of the reactive metabolite(s) as the mechanism of cysteine inhibition.

Drug residue formation from ronidazole, a 5-nitroimidazole. II. Involvement of microsomal NADPH-cytochrome P-450 reductase in protein alkylation in vitro.

Purified liver microsomal NADPH-cytochrome P-450 reductase is able to catalyze the activation of [14C]ronidazole to metabolite(s) which bind covalently to protein. Like the reaction catalyzed by microsomes, protein alkylation catalyzed by the reductase is (1) sensitive to oxygen, (2) requires reducing equivalents, (3) is inhibited by sulfhydryl-containing compounds and (4) is stimulated several fold by either flavin mononucleotide (FMN) or methytlviologen. A cytochrome P-450 dependent pathway of ronidazole activation can be demonstrated as judged by the inhibition of the reaction by carbon monoxide, metyrapone and 2,4-dichloro-6-phenylphenoxyethylamine but the involvement of specific microsomal cytochrome P-450 isozymes has not been definitively established. Milk xanthine oxidase is also capable of catalyzing ronidazole activation. Polyacrylamide sodium dodecyl sulfate (SDS)-gel electrophoresis reveals that the reactive intermediate(s) of ronidazole does not alkylate proteins selectively.