Lewis J. Klunk scite author profile

The determination of metabolic pathways of a drug candidate through the identification of circulating and excreted metabolites is vitally important to understanding its physical and biological effects. Knowledge of metabolite profiles of a drug candidate in animals and humans is essential to ensure that animal species used in toxicological evaluations of new drug candidates are appropriate models of humans. The recent FDA final guidance recommends that human oxidative metabolites whose exposure exceeds 10% of the parent AUC at steady-state should be assessed in at least one of the preclinical animal species used in toxicological assessment. Additional toxicological testing on metabolites that have higher exposure in humans than in preclinical species may be required. The metabolite profiles in laboratory animals and humans are generally accomplished by mass balance and excretion studies in which radiolabeled drugs are administered to these species. The biological fluids are collected, analysed for total radioactivity and evaluated for a quantitative profile of metabolites. Thus, these studies not only determine the rates and routes of excretion but also provide very critical information on the metabolic pathways of drugs in preclinical species and humans. In addition, these studies are required by regulatory agencies for the new drug approval process. Despite the usefulness of these radiolabeled mass balance studies, there is little concrete guidance on how to perform or assess these complex studies. This article examines the objectives, utilities and limitations of these studies and how these studies could be used for the determination of the metabolite exposure in animals and humans.

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Liquid Chromatography/Chemical Reaction Interface Mass Spectrometry as an Alternative to Radioisotopes for Quantitative Drug Metabolism Studies

Goldthwaite¹,

Hsieh²,

Womble³

et al. 1996

Anal. Chem.

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Chemical reaction interface mass spectrometry (CRIMS) was coupled on-line with HPLC using a Vestec particle beam interface. A helium-assisted nebulizer provided added stability with no loss in accuracy or precision as compared to the thermospray nebulizer at flow rates of up to 1.0 mL/min using isocratic conditions. However, mass spectral response was found to be solvent-dependent for both the helium-assisted and thermospray nebulizers. Postcolumn solvent addition of methanol eliminated solvent-dependent decreases in mass spectral response. This allowed gradient HPLC elutions to be performed. Under these conditions, the flow of solvent into the particle beam interface was 2.5 mL/min, so a conventional thermospray nebulizer had to be used instead of the helium-assisted nebulizer. Experiments were conducted with the antianxiety agent buspirone in order to validate the methodology. Metabolites from in vitro incubations of [15N]/[14C]buspirone with rat liver slices were analyzed by gradient LC/CRIMS and by gradient LC/[14C] radioactivity counting. The response from LC/CRIMS analysis for individual metabolites was then compared with that obtained by LC/[14C] radioactivity counting. An excellent correlation was observed between the two methods for metabolites with quite different HPLC characteristics. Thus, gradient LC/CRIMS in combination with stable isotopes provides an alternative to using radioisotopes for carrying out drug metabolism studies.

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Metabolism, Pharmacokinetics, and Protein Covalent Binding of Radiolabeled Maxipost (Bms-204352) in Humans

Zhang¹,

Krishna²,

Wang³

et al. 2004

Drug Metab Dispos

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MaxiPost [(3S)-(؉)-(5-chloro-2-methoxyphenyl)-1,3-dihydro-3-fluoro-6-(trifluoromethyl)-2H-indole-2-one); BMS-204352] is an investigational maxi-K channel opener to treat ischemic stroke. This study reports the disposition, metabolism, pharmacokinetics, and protein covalent binding of 14 C-labeled MaxiPost in healthy male volunteers as well as in dogs and rats. After each human subject received a single dose of 10 mg 14 C-labeled BMS-204352 (50 Ci) as a 5-ml intravenous infusion lasting 5 min, the plasma radioactivity concentrations showed a unique profile, wherein the concentration appeared to increase initially, followed by a terminal decline. The mean terminal t 1/2 of plasma radioactivity (259 h) was prolonged compared with that of unchanged parent (37 h). Furthermore, the extractability of radioactivity in plasma decreased over time, reaching approximately 20% at 4 h after dosing. The unextractable radioactivity was covalently bound to plasma proteins through a des-fluoro-des-methyl BMS-204352 lysine adduct. Unchanged BMS-204352 and minor metabolites were identified in plasma extract following protein precipitation. The recovery of the radioactive dose in urine and feces was nearly complete in 14-day collections (approximately 37% in urine and 60% in feces). The N-glucuronide of the parent was the prominent metabolite in urine (16.5% of dose), whereas the parent was a major drug-related component in feces (11% of dose). Similar disposition, metabolism, pharmacokinetic, and protein covalent binding properties of 14 C-labeled BMS-204352 were observed in humans, dogs, and rats.Stroke is a major cause of death and long-term disability, affecting more than 700,000 people in the United States annually (Williams et al., 1999). Acute ischemic stroke is the most common form, producing pathologically fatal levels of intracellular calcium (Ca 2ϩ ) in neurons at risk. Maxi-K channels are large-conductance voltage-and Ca 2ϩ -activated K ϩ channel proteins (Chang et al., 1997). BMS-204352, chemically designated as (3S)-(ϩ)-(5-chloro-2-methoxyphenyl)-1,3-dihydro-3-fluoro-6-(trifluoromethyl)-2H-indole-2-one), is a maxi-K channel opener . This compound has the potential to prevent and treat ischemic stroke. The fluoro-oxyindole, BMS-204352, provided significant levels of cortical neuroprotection in rat models of stroke by augmenting an endogenous mechanism for regulating Ca 2ϩ entry and membrane potential to protect the neurons (Cheney et al., 2001;Gribkoff et al., 2001).Metabolism appeared to be predominant in the disposition of BMS-204352 in rats and dogs (Krishna et al., 2002d). Following an intraarterial infusion of [ 14 C]BMS-204352 to rats (6 mg/kg) and dogs (2 mg/kg), the AUC values of the unchanged BMS-204352 represented only a very small fraction of the plasma radioactivity. Radioactivity was primarily excreted in the feces (more than 85% of administered dose over a 7-day collection period). Within an hour of dosing rats with [14 C]BMS-204352, over two-thirds of the radioactivity in plasma is covalently ...

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In vitrometabolism of the antianxiety drug buspirone as a predictor of its metabolismin vivo

et al. 1990

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1. Metabolism of the antianxiety drug buspirone was studied by in vitro incubations with rat liver microsomes and hepatocytes. Metabolites were isolated and purified by h.p.l.c. The purified metabolites were identified by co-elution on h.p.l.c. with authentic standards and by g.l.c.-electron impact mass spectrometry of their trimethylsilyl (TMS) derivatives. 2. Five metabolites of buspirone were identified in the microsomal incubates and seven in the hepatocyte incubates. The major metabolites arose from aromatic hydroxylation at C-5, N-dealkylation of the butyl chain, and hydroxylation at C-6' and C-3' on the azaspirodecanedione moiety. 3. Metabolism of buspirone by rat liver microsomes was NADPH-dependent and was completely inhibited by cytochrome P-450 inhibitors SKF-525A and metyrapone. 4. Metabolites of buspirone formed in vitro were good predictors of the primary metabolites formed in vivo. 5. Hepatocytes and phenobarbital-induced rat liver microsomes were better predictors of in vivo metabolism of buspirone than non-induced rat liver microsomes. These in vitro systems should provide excellent models for studying the metabolism of other azaspirodecanedione-containing drugs.

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Lewis J. Klunk

Drug Metabolites in Safety Testing

Human radiolabeled mass balance studies: objectives, utilities and limitations

Liquid Chromatography/Chemical Reaction Interface Mass Spectrometry as an Alternative to Radioisotopes for Quantitative Drug Metabolism Studies

Metabolism, Pharmacokinetics, and Protein Covalent Binding of Radiolabeled Maxipost (Bms-204352) in Humans

In vitrometabolism of the antianxiety drug buspirone as a predictor of its metabolismin vivo

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