High-performance liquid chromatographic assay for metamizol metabolites in rat plasma: Application to pharmacokinetic studies

Pharmacokinetic Profiles of Metamizole Metabolites after Intramuscular and Intravenous Administration in Healthy Arabian Horses

Metamizole sodium (MT) is an analgesic and antipyretic drug molecule used in humans, horses, cattle, swine, and dogs. Metamizole rapidly hydrolyzes and turns into methylamino antipyrine (MAA), an active primary metabolite of MT. The present study aims to determine the pharmacokinetic (PK) profiles of MT metabolites after intravenous (IV) and intramuscular (IM) administration into sex of Arabian horses (Equus ferus caballus) using a cross-over study design. The plasma samples were extracted by solid-phase extraction (SPE) method, and plasma concentrations of MT metabolites were analyzed by high-performance liquid chromatography (HPLC). After administrations of MT, plasma concentrations of methylamino antipyrine (MAA), amino antipyrone (AA), and acetylamino antipyrone (AAA) were determined within range of 15 min-12 h. Plasma concentrations of AA and AAA were lower than the plasma concentrations of major metabolite MAA at each sampling point. The PK parameters were statistically evaluated for MT's metabolites between male and female horses and also between IM and IV administrations of PK parameters such as C_max , t_max , t_1/2λz , AUC_0-t , AUC_0-∞ , λz, Cl and V_ss (p < .05). The AUC_IM /AUC_IV ratio in female and male horses for MAA was 1.19 and 1.13, respectively. The AUC_IM /AUC_IV ratio for AA was lower than those found for MAA. AUC_IM /AUC_IV ratio was statistically significantly different between male and female horses for AA (p < .05). According to these results, some PK parameters such as Cmax, AUC, and MRT, MAA and AA concentrations have shown statistically significant differences by MT administrations.

Pharmacokinetic properties of metamizole active metabolites in Northeastern Brazilian donkeys (Equus asinus)

Metamizole (MT), also known as dipyrone, is an analgesic and antipyretic drug labeled for use in humans and domestic animals in some countries. As with other drugs, the administration of MT in donkeys is based on studies carried out with horses. In the present report, we aimed to determine the pharmacokinetics of the two main metamizole active metabolites (N-methyl-4-aminoantipyrine [MAA] and 4-aminoantipyrine [AA]) following 10 (M₁₀ ) and 25 mg/kg (M₂₅ ) IV metamizole doses in Northeast Brazilian donkeys (n = 10). Blood was collected at predetermined times within over 48 h; MAA and AA plasma concentrations were determined by a validated LC-MS/MS method. The metabolites were quantifiable in the M₁₀ until 12 h and M₂₅ until 24 h after drug administration. As expected, AUC_0→t , AUC_0→∞, and C_max demonstrated significant differences increases in metamizole metabolites profiles when groups were compared. No adverse effects were observed. This study indicates the need for an extremely sensitive analytical method to adequately characterize the pharmacokinetics of active metabolites of MT, MAA, and AA. In conclusion, the method developed in this research was able to measure the active metabolites of metamizole and with that it was possible to establish their pharmacokinetic profile. Furthermore, after projection of the minimum MAA concentrations, it is possible to infer that the dose of 10 mg/kg will be used on donkeys at 6 h intervals, while the M25 group at 12 h intervals. However, clinical studies are needed to assess this hypothesis.

Development and validation of an LC–MS/MS method for the bioanalysis of the major metamizole metabolites in human plasma

Aim: Metamizole is a frequently used antipyretic and analgesic prodrug, yet its pharmacokinetics has not been thoroughly studied in infants and with coadministered medications. Thus, an LC–MS/MS method was developed to quantify the four major metamizole metabolites in human plasma. Methodology: Pre- and postcolumn infusion was installed to enable robust analyte retention and electrospray ionization following deproteinization of plasma samples. Results: The method was linear (R > 0.996), accurate (93.1–106.0%) and precise (≤12.7%). Mean recovery was more than 91.8% and ion suppression less than 13.1% for all analytes. Pharmacokinetic profiles were reproducible after 4 years at -80°C except for the formylated metabolite (-22.2%). Conclusion: The method fulfilled pertinent criteria of validation guidelines and required only little sample volume. The method therefore qualifies for metamizole analyses in children.

Pharmacokinetics and pharmacodynamics of metamizol in co-administration with morphine under acute and chronic treatments in arthritic rats

Objective

To investigate the relationship between metamizol pharmacokinetics and the antinociceptive effect produced after subcutaneous administration of metamizol (177.8 mg/kg) alone or in combination with morphine (3.2 mg/kg), under acute and chronic treatments.

Methods

Antinociception was assessed using the pain-induced functional impairment model in rat (PIFIR). Serial blood samples were collected from the same animals to study the pharmacokinetics of metamizol.

Key findings

The co-administration of the drugs in single dose, confirmed the potentiation of their individual antinociceptive effects. When the drugs were administered alone following the chronic schedule, a pronounced tolerance development to their antinociceptive effects was found, whereas it was significantly attenuated when they were administered together. Metamizol pharmacokinetics was unaltered by the presence of morphine. Plasma concentrations of 4-methylaminoantipyrine, an active metabolite markedly decreased under chronic administration.

Conclusions

The mechanism involved in the potentiation of the antinociceptive effect produced by the combination, cannot be explained by the interaction of morphine on metamizol pharmacokinetics. Other pharmacokinetic interactions along with known pharmacodynamic interactions in which metamizol active metabolites contribute, should be considered. The frequency of administration enhances tolerance development and induces metamizol elimination process.

Effect of tramadol on metamizol pharmacokinetics and pharmacodynamics after single and repeated administrations in arthritic rats

Combined administration of certain doses of opioid compounds with a non-steroidal anti-inflammatory drug can produce additive or supra-additive effects while reducing unwanted effects. We have recently reported that co-administration of metamizol with tramadol produces antinociceptive effect potentiation, after acute treatment. However, none information about the effect produced by the combination after chronic or repeated dose administration exists. The aims of this study were to investigate whether the antinociceptive synergism produced by the combination of metamizol and tramadol (177.8 + 17.8 mg/kg, s.c. respectively) is maintained after repeated treatment and whether the effects observed are primarily due to pharmacodynamic interactions or may be related to pharmacokinetics changes. Administration of metamizol plus tramadol acute treatment significantly enhanced the antinociceptive effect of the drugs given alone (P < 0.05). Nevertheless, this effect decreased about 53% after the chronic treatment (3 doses per day, for 4 days). No pharmacokinetic interaction between metamizol and tramadol was found under acute treatment (P > 0.05). The mechanism involved in the synergism of the antinociceptive effect observed with the combination of metamizol and tramadol in single dose cannot be attributed to a pharmacokinetic interaction, and other pharmacodynamic interactions have to be considered. On the other hand, when metamizol and tramadol were co-administered under repeated administrations, a pharmacokinetic interaction and tolerance development occurred. Differences found in metamizol active metabolites’ pharmacokinetics (P < 0.05) were related to the development of tolerance produced by the combination after repeated doses. This work shows an additional preclinical support for the combination therapy. The clinical utility of this combination in a suitable dose range should be evaluated in future studies.

Simultaneous determination of dipyrone metabolites in rat hypothalamus, cerebrospinal fluid and plasma samples by LC-MS/MS

BACKGROUND

After oral administration dipyrone is rapidly hydrolyzed to 4-methylaminoantipyrine, which is absorbed and further metabolized to 4-formylaminoantipyrine and to 4-aminoantipyrine, which is acetylated by a polymorphic N-acetyltransferase system to 4-acetylaminoantipyrine. To evaluate the presence of dipyrone metabolites in different rat matrices after intraperitoneal administration, an analytical method was developed and validated.

METHODOLOGY

The four main dipyrone metabolites were extracted from plasma, cerebrospinal fluid and hypothalamus samples by LLE prior to LC-MS/MS.

RESULTS

Standard calibration graphs for all metabolites were linear (r > 0.99). The intra- and inter-day precision and accuracy values were both inferior to 15%.

CONCLUSION

This method is simple and specific for studying dipyrone metabolites after intraperitoneal administration.