Kinetic analysis of sequential metabolism of triazolam and its extrapolation to humans using an entero-hepatic two-organ microphysiological system.

The microphysiological system (MPS) is a promising tool for predicting drug disposition in humans, although limited information is available on the quantitative assessment of sequential drug metabolism in MPS and its extrapolation to humans. In the present study, we first constructed a mechanism-based pharmacokinetic model for triazolam (TRZ) and its metabolites in the entero-hepatic two-organ MPS, composed of intestinal Caco-2 and hepatic HepaRG cells, and attempted to extrapolate the kinetic information obtained with the MPS to the plasma concentration profiles in humans. In the two-organ MPS and HepaRG single culture systems, TRZ was found to be metabolized into α- and 4-hydroxytriazolam and their respective glucuronides. All these metabolites were almost completely reduced in the presence of a CYP3A inhibitor, itraconazole, confirming sequential phase I and II metabolism. Both pharmacokinetic model-dependent and -independent analyses were performed, providing consistent results regarding the metabolic activity of TRZ: clearance of glucuronidation metabolites in the two-organ MPS was higher than that in the single culture system. The plasma concentration profile of TRZ and its two hydroxy metabolites in humans was quantitatively simulated based on the pharmacokinetic model, by incorporating several scaling factors representing quantitative gaps between the MPS and humans. Thus, the present study provided the first quantitative extrapolation of sequential drug metabolism in humans by combining MPS and pharmacokinetic modeling.

Total gastrectomy may result in reduced drug effectiveness due to an increase in the expression of the drug-metabolizing enzyme Cytochrome P450, in the liver.

In patients with gastrectomy, it is possible that drug effectiveness is reduced compared to healthy subjects due to the increased of the drug-metabolizing enzyme, Cytochrome P450 (CYP). The purpose of this study is to verify this possibility. Gastrectomy model mice were prepared to evaluate the expression level of various CYPs in the liver from 2 to 24 weeks post-operation. No significant differences were observed in the protein expression levels of CYP3A, CYP1A, CYP2C, and CYP2D between the sham operation group and the gastrectomy group up to 4 weeks after the gastrectomy. On the other hand, significant increases in the protein expression levels of any CYPs were observed in the gastrectomy group compared to the sham operation group from 12 weeks after the gastrectomy onward. These increases in expression levels were maintained until 24 weeks after the gastrectomy. The examination of metabolic activity in the liver in the gastrectomy group using triazolam revealed that the metabolic activity at 12 weeks after the gastrectomy was significantly increased in the gastrectomy group. The administration of the anticancer drug imatinib, which is a substrate of CYP3A, to mice at 12weeks after gastrectomy resulted in an increase in the metabolic rate, suggesting a possible decrease in drug effectiveness. It has been revealed that drug effectiveness may be reduced after gastrectomy because the expression levels of various CYPs in the liver were increased over a prolonged period. The results of this study can serve as valuable fundamental knowledge for drug therapy in patients with gastrectomy.

An in vitro approach to detect metabolite toxicity due to CYP3A4-dependent bioactivation of xenobiotics.

Many adverse drug reactions are caused by the cytochrome P450 (CYP) dependent activation of drugs into reactive metabolites. In order to reduce attrition due to metabolism-mediated toxicity and to improve safety of drug candidates, we developed two in vitro cell-based assays by combining an activating system (human CYP3A4) with target cells (HepG2 cells): in the first method we incubated microsomes containing cDNA-expressed CYP3A4 together with HepG2 cells; in the second approach HepG2 cells were transiently transfected with CYP3A4. In both assay systems, CYP3A4 catalyzed metabolism was found to be comparable to the high levels reported in hepatocytes. Both assay systems were used to study ten CYP3A4 substrates known for their potential to form metabolites that exhibit higher toxicity than the parent compounds. Several endpoints of toxicity were evaluated, and the measurement of MTT reduction and intracellular ATP levels were selected to assess cell viability. Results demonstrated that both assay systems are capable to metabolize the test compounds leading to increased toxicity, compared to their respective control systems. The co-incubation with the CYP3A4 inhibitor ketoconazole confirmed that the formation of reactive metabolites was CYP3A4 dependent. To further validate the functionality of the two assay systems, they were also used as a "detoxification system" using selected compounds that can be metabolized by CYP3A4 to metabolites less toxic than their parent compounds. These results show that both assay systems can be used to screen for metabolic activation, or de-activation, which may be useful as a rapid and relatively inexpensive in vitro assay for the prediction of CYP3A4 metabolism-mediated toxicity.

Comparative metabolic capabilities of CYP3A4, CYP3A5, and CYP3A7.

The human cytochromes P450 (P450) CYP3A contribute to the biotransformation of 50% of oxidatively metabolized drugs. The predominant hepatic form is CYP3A4, but recent evidence indicates that CYP3A5 contributes more significantly to the total liver CYP3A than was originally thought. CYP3A7 is the major fetal form and is rarely expressed in adults. To compare the metabolic capabilities of CYP3A forms for 10 substrates, incubations were performed using a consistent molar ratio (1:7:9) of recombinant CYP3A, P450 reductase, and cytochrome b5. A wide range of substrate concentrations was examined to determine the best fit to kinetic models for metabolite formation. In general, K(m) or S(50) values for the substrates were 3 to 4 times lower for CYP3A4 than for CYP3A5 or CYP3A7. For a more direct comparison of these P450 forms, clearance to the metabolites was determined as a linear relationship of rate of metabolite formation for the lowest substrate concentrations examined. The clearance for 1'-hydroxy midazolam formation at low substrate concentrations was similar for CYP3A4 and CYP3A5. For CYP3A5 versus CYP3A4, clearance values at low substrate concentrations were 2 to 20 times lower for the other biotransformations. The clearance values for CYP3A7-catalyzed metabolite formation at low substrate concentrations were substantially lower than for CYP3A4 or CYP3A5, except for clarithromycin, 4-OH triazolam, and N-desmethyl diltiazem (CYP3A5 - CYP3A7). The CYP3A forms demonstrated regioselective differences in some of the biotransformations. These results demonstrate an equal or reduced metabolic capability for CYP3A5 compared with CYP3A4 and a significantly lower capability for CYP3A7.

Progesterone: does it affect response to drug?

This article presents an overview of the gamma-aminobutyric acid (GABA)-benzodiazepine receptor complex (GBRC) and its in vitro modulation by THP, a metabolite of progesterone, as well as the results of a single-dose study of progesterone and triazolam in 16 post-menopausal women. The study results indicate that a 300 mg oral dose of progesterone administered 2.5 hours prior to a challenge dose of triazolam significantly increases sensitivity to triazolam: concentration values required for 50 percent of maximum effect (EC50) decreased by 20 to 32 percent after pre-treatment with progesterone. These data support the In vitro findings that THP enhances binding of benzodiazepines to the GBRC. The full clinical implications of these data, including extensions to other steroids, need to be explored.

Role of GABA-A and mitochondrial diazepam binding inhibitor receptors in the anti-stress activity of neurosteroids in mice.

Neuroactive steroidal modulation of immobilization-stress and possible involvement of GABA-A and mitochondrial diazepam binding inhibitor (DBI) receptors (MDR) has been investigated in mice. Immobilization of mice for 2 h induced intense antinociception, anxiety state, and associated with a fall in adrenal ascorbic acid levels. Pretreatment with high dose of progesterone (10 mg/kg), a precursor of neurosteroids, significantly decreased the stress-induced antinociception, anxiety and fall in adrenal ascorbic acid, while low doses (1 and 5 mg/kg) or hydrocortisone (10 and 100 mg/kg) were ineffective. In contrast, progesterone (1 mg/kg, for 9 days) produced a significant antistress effect, which was blocked by GABA-A antagonists picrotoxin (1 mg/kg) and bicuculline (1 mg/kg), but not by flumazenil (2 mg/kg), a specific benzodiazepine (BZD) antagonist. 4'-chlordiazepam (0.1 and 0.25 mg/kg), a specific high affinity MDR agonist, produced significant anti-stress effect in a flumazenil-insensitive manner, but was blocked by pretreatment with PK11195 (1.5 mg/kg), a selective partial agonist of MDR, and with bicuculline (1 mg/kg), a potent GABA-A receptor antagonist. At higher doses, progesterone and 4'-chlordiazepam which are effective in immobilization stress also reduced locomotion. However, lower doses of progesterone (6.5 mg/kg) neither affected locomotion, nor produced any motor toxicity on rota-rod test. At the lower doses, the MDR ligand 4'-chlordiazepam (50 micrograms/kg) decreased locomotor activity, without altering motor toxicity on rota-rod test. Further, the per se effects of these treatments on unstressed mice were not significantly different from those of untreated controls, except for plus-maze test. The antistress profile of progesterone may be attributed to the in vivo production of neurosteroid allopregnanolone, thus resembled that of BZDs. Furthermore, the antistress actions are flumazenil-resistant, reaffirming that there may be an increase in the levels of pregnane neurosteroids in vivo, which may act on a specific allosteric site on GABA-A receptors distinct from BZD site. Because 4'-chlordiazepam binds to MDRs and stimulate mitochondrial neurosteroidogenesis, the anti-stress effects of 4'-chlordiazepam may be imputed to its MDR-induced neurosteroids, which then act on GABA-A receptors. These data suggest a pivotal role for GABA-A and mitochondrial DBI receptors in the antistress actions of neurosteroids and reinforces their ameliorative effect in physiological stress.

Lack of influence of cigarette smoking on triazolam pharmacokinetics.

The influence of cigarette smoking on the pharmacokinetics of a single dose of the triazolobenzodiazepine hypnotic triazolam was evaluated in 12 healthy nonsmoking male volunteers and in 12 male subjects, matched for age, height and weight, who smoked an average of 24 cigarettes a day (range: 15-30). Triazolam kinetics were determined from multiple serum concentrations measured during 15 h after a single 0.5 mg dose. There were no significant differences between nonsmoking controls and cigarette smokers in the peak serum triazolam concentration (4.64 vs 4.73 ng ml-1), the time of peak concentration (0.98 vs 1.0 h after dosage), elimination half-life (2.8 vs 2.5 h), or oral clearance of triazolam (506 vs 627 ml min-1). Likewise there were no significant differences between groups in the extent of triazolam binding to serum protein (18.8 vs 18.5% unbound). Altered pharmacodynamics of triazolam in cigarette smokers are not likely to be explained by altered pharmacokinetics.

Effect of oral contraceptives on triazolam, temazepam, alprazolam, and lorazepam kinetics.

The effects of low-dose estrogen oral contraceptives (OC) on the elimination of the oxidized benzodiazepines triazolam (TRZ) and alprazolam (ALP) and the conjugated benzodiazepines temazepam (TMZ) and lorazepam (LOR) were studied in two parallel crossover studies of 20 women each. Women taking OC steroids containing low doses of estrogen and women matched for age, weight, and cigarette smoking received single oral doses of TRZ (0.5 mg) and TMZ (30 mg) or ALP (1 mg) and LOR (2 mg). Kinetics were determined as plasma concentrations during 48 hr after dosing. OCs inhibited the metabolism of ALP: The AUC increased and the elimination rate constant was greater in users of OCs. For TRZ, which has an intermediate extraction ratio, the AUC was increased by OCs but not significantly so. In contrast, OCs decreased the AUC for TMZ and the elimination rate constants for LOR and TMZ. The AUC of LOR was not affected by OCs. Low-dose estrogen OCs may therefore inhibit the metabolism of some oxidized benzodiazepines and accelerate the metabolism of some conjugated benzodiazepines.

PIP: Because benzodiazepines and oral contraceptives (OCs) are among the most widely prescribed drugs and have a potential for interaction, 2 parallel crossover studies were conducted to determine the effects of OCs on the elimination of the oxidized benzodiazepines triazolam (TRZ) and alprozolam (ALP) and the conjugated benzodiazepines temazepam (TMZ) and lorazepam (LOR). 20 healthy women taking OCs containing does of under 35 mcg of ethinyl estradiol for 3 months or more and 20 women matched for age, weight, and cigarette smoking received single oral doses of TRZ (.5 mg) and TMZ (30 mg) or ALP (1 mg) and LOR (2 mg). Treatments were seperated by 28 days to control for effects of menstural cycle on drug metabolism. Kinetics were determined as plasma concentrations during 48 hours after dosing. The data indicated that OCs differentially affect the elimination of the benzodiazepines studied. OCs inhibited the metabolism of ALP: the area under the curve (AUC) increased and the elimination rate constant was greater in users of OCs. For TRZ, which has an intermediate extraction ratio, the AUC was increased by OCs but not significantly so. OCs decreased the AUC for TMZ and the elimination rate constants for LOR and TMZ. The AUC of LOR was not affected by OCs. It was concluded that low-dose estrogen OCs may inhibit the metabolism of some conjugated benzodiazepines and accelerate the metabolism of some conjugated benzodiazepines, but the clinical implications are unclear. The relationship between plasma concentration and effect has not been determined for most benzodiazepines, but the results suggest that the time required to achieve steady-state concentrations would be longer and that there would be higher steady state concentrations of ALP in OC users. Because both TMZ and LOR are eliminated more rapidly by OC users, women taking OCs should achieve steady-state concentrations more rapidly than nonusers. Because TMZ clearance is increased by OCs, mean plasma concentration may be decreased. The usual 30 mg dose of TMZ may therefore be less effective as a hypnotic in OC users.

Nuevas Benzodiazepinas / New Benzodiazepines

En el último decenio han aparecido en nuestro mercado cuatro benzodiazepinas, ellas podrían representar avances sutiles pero importantes en el tratamiento de los desórdenes de ansiedad y del insomnio. En este trabajo se revisa brevemente la farmacología, la farmacocinética y las características clínicas de este grupo para facilitar su mejor manejo por el médico. Además, se presenta someramente algunas perspectivas futuras.