New approach to rifampicin stability and first-line anti-tubercular drug pharmacokinetics by UPLC-MS/MS

Comparative analysis of impurity profiles in rifampicin capsules with different crystal forms using LC-MS/MS

Rifampicin (RIF) is a kind of semi-synthetic antibiotic with broad-spectrum antibacterial action, which has remarkable antibacterial activity against many pathogenic microorganisms. The World Health Organization classifies RIF as critically important for human medicine, especially for tuberculosis treatment. The polymorphic nature of RIF contributes to the complexity of the impurities of the drug. Lack of systematic and comparative studies on its impurities in different crystal forms may affect the efficiency of this drug and increase the incidence of adverse reactions. Current methods in pharmacopoeias and literature can only separate a limited number of known impurities, and the process of preparing the mobile phase is highly cumbersome. In this work, response surface methodology was employed to optimize the conditions of one-dimensional liquid chromatography (LC) as an alternative approach to pharmacopoeia methods. This method demonstrated high accuracy and sensitivity, enabling the quantification of impurities as low as 0.25 μg/mL. The proposed method provided satisfactory linearity, percentage of recovery from 88 to 101 % with relative standard, deviations (RSD) lower than 5 %, indicating good precision. Additionally, the parallel determination of 6 sample solutions showed that the content changes of the relevant components were within an acceptable range, demonstrating method repeatability. A detection method based on high-resolution two-dimensional LC-mass spectrometry (2D-LC-MS/MS) was developed to analyze. A total of 25 impurities were identified and the impurity profiles were systematically investigated for the first time, providing experimental basis for the quality control of the drug.

Urinary drug metabolite profiling of tuberculosis treatment failure using proton nuclear magnetic resonance

The underlying cause of tuberculosis (TB) treatment failure is still largely unknown. A 1H NMR approach was applied to identify and quantify a subset of TB drugs and drug metabolites: ethambutol (EMB), acetyl isoniazid (AcINH), isonicotinic acid, pyrazinamide (PZA), pyrazinoic acid and 5-hydroxy-pyrazinoic acid, from the urine of TB patients. Samples were collected before, during (weeks one, two and four) and after standardised TB treatment. The median concentrations of the EMB and PZA metabolites were comparable between the samples from patients with eventually cured and failed treatment outcomes. The INH metabolites showed comparatively elevated concentrations in the treatment failure patients during and after treatment. Variation in INH metabolite concentrations couldn't be associated with the varying acetylator genotypes, and it is therefore suggested that treatment failure is influenced more so by other conditions, such as environmental factors, or individual variation in other INH metabolic pathways.

From Bed to Bench: Pre-analytical Stability of 29 Anti-infective Agents in Plasma and Whole Blood to Improve Accuracy of Therapeutic Drug Monitoring

BACKGROUND

Therapeutic drug monitoring requires a validated assay and appropriate conditions for sample shipment and storage based on the stability of the compound to be analyzed. This study evaluated the stability of 29 antimicrobial compounds in whole blood (WB) and plasma samples under various storage conditions.

METHODS

The pre-analytical stability of 22 antibiotics (amoxicillin, aztreonam, cefazolin, cefepime, cefotaxime, cefoxitin, ceftazidime, ceftobiprole, ceftolozane, ceftriaxone, ciprofloxacin, clindamycin, cloxacillin, daptomycin, levofloxacin, linezolid, meropenem, metronidazole, moxifloxacin, piperacillin, sulfamethoxazole, and trimethoprim), 2 beta-lactamase inhibitors (avibactam, tazobactam), and 5 antituberculosis drugs (ethambutol, isoniazid, pyrazinamide, rifabutin, and rifampicin) was assessed by WB for up to 24 hours at room temperature (RT) and 72 hours at +4°C. The stability in plasma was evaluated for up to 6 hours at RT, 24 hours at +4°C, 1 month at -20°C, and 6 months at -80°C.

RESULTS

Concerning WB stability, all investigated compounds were stable for 24 hours at RT, except meropenem and isoniazid, which were stable for 6 hours; however, for 24 hours at +4°C, all the compounds were stable. For storage durations of 48 and 72 hours at +4°C, all compounds were stable, except for ciprofloxacin, cotrimoxazole, and isoniazid. Concerning stability in plasma, all compounds were stable for 6 hours at RT, and all except isoniazid were stable for 24 hours at +4°C. All the tested compounds were stable for 7 days at -20°C, except isoniazid, for which a degradation of approximately 20% was observed. An important degradation was observed for beta-lactam antibiotics after 1 month at -20°C. All compounds were stable at -80°C for 6 months.

CONCLUSIONS

The pre-analytical stabilities of several anti-infective compounds was described. The present results can be used to determine the appropriate conditions for shipping and storing samples dedicated to therapeutic drug monitoring of the investigated compounds.

Evaluation of critical parameters in the hollow-fibre system for tuberculosis: A case study of moxifloxacin

Aims

The hollow‐fibre system for tuberculosis (HFS‐TB) is a preclinical model qualified by the European Medicines Agency to underpin the anti‐TB drug development process. It can mimic in vivo pharmacokinetic (PK)–pharmacodynamic (PD) attributes of selected antimicrobials, which could feed into in silico models to inform the design of clinical trials. However, historical data and published protocols are insufficient and omit key information to allow experiments to be reproducible. Therefore, in this work, we aim to optimize and standardize various HFS‐TB operational procedures.

Methods

First, we characterized bacterial growth dynamics with different types of hollow‐fibre cartridges, Mycobacterium tuberculosis strains and media. Second, we mimicked a moxifloxacin PK profile within hollow‐fibre cartridges, in order to check drug–fibres compatibility. Lastly, we mimicked the moxifloxacin total plasma PK profile in human after once daily oral dose of 400 mg to assess PK–PD after different sampling methods, strains, cartridge size and bacterial adaptation periods before drug infusion into the system.

Results

We found that final bacterial load inside the HFS‐TB was contingent on the studied variables. Besides, we demonstrated that drug–fibres compatibility tests are critical preliminary HFS‐TB assays, which need to be properly reported. Lastly, we uncovered that the sampling method and bacterial adaptation period before drug infusion significantly impact actual experimental conclusions.

Conclusion

Our data contribute to the necessary standardization of HFS‐TB experiments, draw attention to multiple aspects of this preclinical model that should be considered when reporting novel results and warn about critical parameters in the HFS‐TB currently overlooked.

Ten-year results of an international external quality control programme for measurement of anti-tuberculosis drug concentrations

OBJECTIVES

Participation in an external (interlaboratory) quality control (QC) programme is an essential part of quality assurance as it provides laboratories with valuable insights into their analytical performance. We describe the 10 year results of an international QC programme for the measurement of anti-tuberculosis (TB) drugs.

METHODS

Each year, two rounds were organized in which serum (or plasma) samples, spiked with known concentrations of anti-TB drugs, were provided to participating laboratories for analysis. Reported measurements within 80%-120% of weighed-in concentrations were considered accurate. Mixed model linear regression was performed to assess the effect of the measured drug, concentration level, analytical technique and performing laboratory on the absolute inaccuracy.

RESULTS

By 2022, 31 laboratories had participated in the QC programme and 13 anti-TB drugs and metabolites were included. In total 1407 measurements were reported. First-line TB drugs (isoniazid, rifampicin, pyrazinamide and ethambutol) represented 58% of all measurements. Overall, 83.2% of 1407 measurements were accurate, and the median absolute inaccuracy was 7.3% (IQR, 3.3%-15.1%). The absolute inaccuracy was related to the measured anti-TB drug and to the performing laboratory, but not to the concentration level or to the analytical technique used. The median absolute inaccuracies of rifampicin and isoniazid were relatively high (10.2% and 10.9%, respectively).

CONCLUSIONS

The 10 year results of this external QC programme illustrate the need for continuous external QC for the measurement of anti-TB drugs for research and patient care purposes, because one in six measurements was inaccurate. Participation in the programme alerts laboratories to previously undetected analytical problems.

Development and Validation of a UPLC-MS/MS Method for Therapeutic Drug Monitoring, Pharmacokinetic and Stability Studies of First-Line Antituberculosis Drugs in Urine

Tuberculosis (TB) remains one of the leading global causes of mortality. Several methods have been established to detect anti-TB agents in human plasma and serum. However, there is a notable absence of studies analyzing TB drugs in urine. Thus, our objective was to validate a method for quantifying first-line anti-TB agents: isoniazid (INH), pyrazinamide (PZA), ethambutol (ETH), and rifampicin (RIF), along with its metabolite 25-desacetylrifampicin, and degradation products: rifampicin quinone and 3-formyl-rifampicin in 10 µL of urine. Chromatographic separation was achieved using a Kinetex Polar C18 analytical column with gradient elution (5 mM ammonium acetate and acetonitrile with 0.1% formic acid). Mass spectrometry detection was carried out using a triple-quadrupole tandem mass spectrometer operating in positive ion mode. The lower limit of quantification (LLOQ) was 0.5 µg/mL for INH, PZA, ETH, and RIF, and 0.1 µg/mL for RIF's metabolites and degradation products. The method was validated following FDA guidance criteria and successfully applied to the analysis of the studied compounds in urine of TB patients. Additionally, we conducted a stability study of the anti-TB agents under various pH and temperature conditions to mimic the urine collection process in different settings (peripheral clinics or central laboratories).