In vitro dissolution absorption system (IDAS2): Use for the prediction of food viscosity effects on drug dissolution and absorption from oral solid dosage forms.

Existing in vitro dissolution or permeation models to predict food effect are mainly based on Pharmacopeias' compendial media, which specify such variables as pH, bile salts, lipolytic enzymes, and phospholipids content. However, the viscosity of food in the gastrointestinal (GI) tract is not taken into account, although it can affect both the dissolution of the oral solid dosage form and absorption of the released drug. Here, a new in vitro dissolution absorption system (IDAS2) is utilized, which comprises a dissolution apparatus USP2 (DISTEK) equipped with specially constructed permeability chambers containing Caco-2 monolayers, thereby allowing dissolution and transepithelial absorption to be ascertained simultaneously. The IDAS2 was used to evaluate the effect of medium viscosity on both the dissolution of oral solid dosage forms and absorption of released drugs. Such information, which is not ordinarily determined in dissolution and permeation studies, will be helpful to the formulators developing robust oral dosage forms. Commercially available solid dosage forms of ten model drugs from across all BCS classifications were used in this evaluation: metoprolol, minoxidil, and propranolol from BCS class 1; carbamazepine, ketoprofen, and simvastatin from BCS class 2; atenolol and ranitidine from BCS class 3; and acetazolamide and saquinavir from BCS class 4. The study revealed the applicability of IDAS2 as a tool for in vitro screening of dissolution and absorption of intact oral solid products to predict food viscosity effect. The most profound viscosity effect on dissolution and absorption was observed of solid dosage forms for the BCS class 2 compounds carbamazepine and simvastatin. A higher medium viscosity significantly slowed down the dissolution rate of tested BSC class 4 compounds acetazolamide and saquinavir, without significant effect on their absorption. The solid dosage forms least affected by the viscosity of the medium tested were the BCS class 1 compounds minoxidil and propranolol.

Rapid isolation of peptidic inhibitors of the solute carrier family transporters OATP1B1 and OATP1B3 by cell-based phage display selections.

OATP1B1 and OATP1B3 (1B3) are members of organic anion-transporting polypeptides (OATPs), a family of sodium-independent organic anion membrane transporters that contribute to transport of various drugs. To identify peptide inhibitors of OATP1B1, we developed a direct selection system on live cells using phage-displayed peptide libraries. Selections against OATP1B1 overexpressed cell-lines yielded three unique peptides able to inhibit the transport function of OATP1B1 and 1B3. Affinity maturation of one peptide led to identification of two peptides that demonstrated improved inhibition efficacy on drug uptake mediated by OATP1B1 and 1B3. We anticipate that these peptides will assist the identification of novel substrates for OATP1B1 and 1B3. Moreover, our selection system is a practical method for generating inhibitors of other membrane transporters.

Application of exogenous mixture of glutathione and stable isotope labeled glutathione for trapping reactive metabolites in cryopreserved human hepatocytes. Detection of the glutathione conjugates using high resolution accurate mass spectrometry.

Metabolites (including reactive metabolites) of troglitazone were generated by incubation with cryopreserved human hepatocytes and trapped in the presence of an exogenous mixture of unlabeled and stable isotope labeled (SIL: [1,2-(13)C, (15)N]-glycine) glutathione (GSH/SIL-GSH). The incubation samples were analyzed using liquid chromatography-high resolution accurate mass spectrometry (LC-HRAMS) implemented on a LTQ Orbitrap mass spectrometer. The GSH conjugates of the reactive metabolites were detected via a characteristic mono-isotopic pattern (peaks separated by 3.0037u). Analysis of the incubation samples led to detection of a number of previously described GSH conjugates, as well as two novel methylated GSH conjugates, which were partially characterized based on accurate mass measurements and MS/MS data. The addition of exogenous GSH led to an increase in the apparent level of detected GSH conjugates. Kinetic isotopic measurements showed that the rates of incorporation of exogenous GSH are conjugate-specific. In conclusion, this approach, based on the use of a mixture of GSH/SIL-GSH, allows facile capture and detection of reactive metabolites in human hepatocytes. Moreover, the data suggest that routine addition of glutathione to the assay medium may be advisable for experiments with cryopreserved hepatocytes.

Inter-species comparison of 7-hydroxycoumarin glucuronidation and sulfation in liver S9 fractions.

UDP glycosyltransferases (UGTs) and sulfotransferases (SULTs) are phase II enzymes that interact with a number of xenobiotics in humans and animals. Species differences in enzymatic characteristics have seldom been investigated. Liver S9 fractions are commonly used for studying phase II metabolism in vitro. The objective of this study was to characterize the UGT and SULT activities in liver S9 fractions from various species including humans, monkeys, dogs, and rats. A single substrate, 7-hydroxycoumarin (7-HC), at several concentrations was incubated at 37 degrees C with the S9 reaction matrices along with necessary cofactors. The rate of formation of two metabolites, 7-HC-glucuronide (7-HC-G) and 7-HC-sulfate (7-HC-S), was determined with Liquid Chromatography/Tanderm Mass Spectrometry (LC/MS/MS). Apparent Km and Vmax values were calculated for each species. For the UGTs, the apparent Km and Vmax for 7-HC-G formation varied greatly among different species, with dog UGTs having both the highest Km and Vmax values. In contrast to UGTs, the Km for 7-HC-S formation showed no significant difference among humans, monkeys, and rats (approximately 3 microM). However, the Km in dog was 8.7 microM. Species differences with respect to phase II metabolism must be carefully considered when selecting an in vitro model system to study various aspects of drug metabolism.