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Formation of an acyl-CoA thioester has been proposed, but not directly demonstrated, to be a key step in mediating both lactonization and atypical β-oxidation of 3-hydroxy-3-methylglutaryl-CoA reductase inhibitors. Here, we describe studies to characterize formation of acyl-CoA thioesters in vitro in mouse liver preparations, using the hydroxy acid form of simvastatin (SVA) as a model substrate. With an optimized chromatography method, three new products were detected in addition to the dehydration product (P1) and the lactone form of simvastatin, which have been characterized previously (Prueksaritanont et al., 2001). Based on HPLC analysis, UV spectroscopy, mass spectrometry and NMR spectral characterization, two metabolites were identified as acyl-CoA thioester conjugates of SVA and P1, respectively, whereas the third metabolite (M1) was confirmed to be the L-β-hydroxy isomer of simvastatin. M1 was likely formed by stereospecific hydration, a previously reported reaction, and subsequent lactonization of P1-S-acyl CoA. Among all the mouse liver subcellular fractions, microsomes exhibited the highest capacity to catalyze the CoASH-dependent metabolism of SVA, while such activity was totally absent in cytosol. Together, these results provide direct experimental evidence that SVA (and conceivably other statins as well) is able to form an acyl-CoA thioester, possibly by microsomal long-chain acyl-CoA synthetase(s), leading to formation of two parallel metabolic pathways; one resulting in the two diastereomers of statin lactones (simvastatin and M1), and the other to the β-oxidation pathway of statin hydroxy acids

Metabolite profiling and pharmacokinetic evaluation of hydrocortisone in a perfused 3D human liver bioreactor

Endotoxin lipopolysaccharide (LPS) is known to cause liver injury primarily involving inflammatory cells such as Kupffer cells, but few in vitro culture models are applicable for investigation of inflammatory effects on drug metabolism. We have developed a 3D human microphysiological hepatocyte-Kupffer-cell coculture system and evaluated the anti-inflammatory effect of glucocorticoids on liver cultures. LPS was introduced to the cultures to elicit an inflammatory response and assessed by the release of pro-inflammatory cytokines, IL6 and TNFα. A sensitive and specific RP-UHPLC-QTOF-MS method was used to evaluate hydrocortisone disappearance and metabolism at near physiological levels. For this, the systems were dosed with 100 nM hydrocortisone and circulated for two days; hydrocortisone was depleted to approximately 30 nM, with first-order kinetics. Phase I metabolites, including tetrahydrocortisone and dihydrocortisol, accounted for 8-10 % of the loss, and 45-52 % was phase II metabolites, including glucuronides of tetrahydrocortisol and tetrahydrocortisone. Pharmacokinetic parameters, i.e., half-life (t1/2), rate of elimination (kel), clearance (CL), and area under the curve (AUC), were 23.03 h, 0.03 h-1, 6.6x10-5 L. h-1 and 1.03 mg/L*h respectively. The ability of the bioreactor to predict the in vivo clearance of hydrocortisone was characterized and the obtained intrinsic clearance values correlated with human data. This system offers a physiologically-relevant tool for investigating hepatic function in an inflamed liver. Endotoxin lipopolysaccharide (LPS) is known to cause liver injury primarily involving inflammatory cells such as Kupffer cells, but few in vitro culture models are applicable for investigation of inflammatory effects on drug metabolism. We have developed a 3D human microphysiological hepatocyte-Kupffer-cell coculture system and evaluated the anti-inflammatory effect of glucocorticoids on liver cultures. LPS was introduced to the cultures to elicit an inflammatory response and assessed by the release of pro-inflammatory cytokines, IL6 and TNFα. A sensitive and specific RP-UHPLC-QTOF-MS method was used to evaluate hydrocortisone disappearance and metabolism at near physiological levels. For this, the systems were dosed with 100 nM hydrocortisone and circulated for two days; hydrocortisone was depleted to approximately 30 nM, with first-order kinetics. Phase I metabolites, including tetrahydrocortisone and dihydrocortisol, accounted for 8-10 % of the loss, and 45-52 % was phase II metabolites, including glucuronides of tetrahydrocortisol and tetrahydrocortisone. Pharmacokinetic parameters, i.e., half-life (t[subscript 1/2]), rate of elimination (k[subscript el]), clearance (CL), and area under the curve (AUC), were 23.03 h, 0.03 h[superscript -1], 6.6x10[superscript -5] L. h-1 and 1.03 mg/L*h respectively. The ability of the bioreactor to predict the in vivo clearance of hydrocortisone was characterized and the obtained intrinsic clearance values correlated with human data. This system offers a physiologically-relevant tool for investigating hepatic function in an inflamed liver.United States. Defense Advanced Research Projects Agency (DARPA-BAA-11-73 Microphysiological Systems W911NF-12-2-0039)National Institutes of Health (U.S.) (5-UH2-TR000496)Massachusetts Institute of Technology. Center for Environmental Health Sciences (P30-ES002109

Ontogeny and cross species comparison of pathways involved in drug absorption, distribution, metabolism and excretion in neonates (review) : KIDNEY

The kidneys play an important role in many processes, including urine formation, water conservation, acid-base equilibrium, and elimination of waste. The anatomic and functional development of the kidney has different maturation time points in humans versus animals, with critical differences between species in maturation before and after birth. Absorption, distribution, metabolism, and excretion (ADME) of drugs vary depending on age and maturation, which will lead to differences in toxicity and efficacy. When neonate/juvenile laboratory animal studies are designed, a thorough knowledge of the differences in kidney development between newborns/children and laboratory animals is essential. The human and laboratory animal data must be combined to obtain a more complete picture of the development in the kidneys around the neonatal period and the complexity of ADME in newborns and children. This review examines the ontogeny and cross-species differences in ADME processes in the developing kidney in preterm and term laboratory animals and children. It provides an overview of insights into ADME functionality in the kidney by identifying what is currently known and which gaps still exist. Currently important renal function properties such as glomerular filtration rate, renal blood flow, and ability to concentrate are generally well known, while detailed knowledge about transporter and metabolism maturation is growing but is still lacking. Preclinical data in those properties is limited to rodents and generally covers only the expression levels of transporter or enzyme-encoding genes. More knowledge on a functional level is needed to predict the kinetics and toxicity in neonate/juvenile toxicity and efficacy studies

Risk Assessment of Mechanism-based Inactivation in Drug-Drug Interactions

is used for inhibitor concentration. However, the use of total C max led to great over prediction of DDI risk. The risk assessment using λ/k deg coupled with unbound C max can be useful for the DDI risk evaluation via MBI in drug discovery and development. DMD #46649