Effects of single-dose and fractionated cranial irradiation on rat brain accumulation of methotrexate.

The effects of single-dose and fractionated whole-brain irradiation on brain methotrexate (MTX) has been studied in a rat model. The amount of MTX present in the brain 24 hr after a single i.p. dose (100 mg/kg) was the same wether animals were sham irradiated or given a single dose of 2000 rads 6 or 48 hr prior to the drug (6.9, 8.3, and 6.8 pmol MTX/g, wet weight, respectively). Animals sham irradiated or given 2000 rads in 10 fractions over 11 days and treated with an average dose of 1.2 mg MTX/kg i.p. twice a week for 24 weeks did not differ significantly in their brain MTX concentration (7.9 and 8.3 pmol MTX/g, wet weight, respectively). Chronically MTX-treated animals became folate deficient whether they were irradiated or not (450 and 670 pmol folate/g, wet weight, brain in MTX-treated and control animals). Thus, MTX accumulates in the brain with acute or chronic administration, and this accumulation is not altered by this amount of brain irradiation.

Examination of purported probes of human CYP2B6.

7-Ethoxy-4-trifluoromethylcoumarin (7-EFC) was examined as a substrate for cytochrome P450 (P450) in microsomes from human livers and expressed in B-lymphoblastoid cells. The O-deethylation of 7-EFC to 7-hydroxy-4-trifluoromethylcoumarin (7-HFC) varied over a liver bank (n = 19) by a factor of 13 (40-507 pmol min-1 mg-1 protein). When compared with the ability of the bank of human liver samples to metabolize form-selective substrates of the P450, 7-HFC formation correlated strongly with the formation of the S-mephenytoin metabolite, nirvanol (r2 = 0.86, p < 0.0001). alpha-Napthoflavone (ANF), diethyldithiocarbamate (DDC) and chloramphenicol (CAP) inhibited the O-deethylation of 7-EFC by microsomes from human livers by greater than 60%. Orphenadrine (ORP), a reported specific CYP2B6 inhibitor, was a less potent inhibitor of 7-HFC formation by microsomes from human liver than DDC or ANF. Using microsomes from B-lymphoblastoid cells expressing specific P450s, CYP2B6 and CYP1A2 were found to produce substantial levels of 7-HFC whereas CYP2E1 and CYP2C19 produced detectable amounts of this metabolite. ORP inhibited expressed CYP2E1 and CYP2B6 mediated 7-HFC formation to a greater extent than the inhibition observed for CYP1A2. Methoxychlor and S-mephenytoin inhibited expressed CYP2B6 but not CYP1A2 mediated 7-EFC O-deethylation. Livers (n = 5) with high relative rates of 7-HFC formation displayed biphasic enzyme kinetics with the low K(m) site (average K(m) = 3.3 microM) demonstrating allosteric activation. Five livers with low relative rates of 7-HFC formation also exhibited biphasic kinetics but lacked evidence of an allosteric mechanism being involved in the low K(m) component (average K(m) = 2.4 microM). Furthermore, expressed CYP2B6 and CYP2E1 converted 7-EFC to 7-HFC with allosteric activation indicated, while CYP1A2 mediated metabolism of 7-EFC to 7-HFC best fit the classic Michaelis-Menten model. A commercially available antibody to rat CYP2B, suggested to be specific for CYP2B6, was found to cross react with all members to the CYP2 family examined including CYP2C19, which possessed a nearly identical electrophoretic mobility to that of CYP2B6 in the system examined. In total, the evidence presented indicates that multiple P450s are involved in the formation of 7-HFC from 7-EFC, therefore this does not appear to be a useful or a selective probe of CYP2B6 catalytic activity. Furthermore, the specificity of both antibody and chemical inhibitor (ORP) probes previously suggested to be specific for CYP2B6 is also questioned.

Interaction of human liver cytochromes P450 in vitro with LY307640, a gastric proton pump inhibitor.

The interactions in vitro of LY307640 with the cytochromes P450 (P450s) were studied using human liver microsomes, specific inhibitors of the P450s, and cDNA expressed enzymes. The kinetics of formation of the two major oxidative metabolites, desmethyl LY307640 and LY307640 sulfone, were determined using two human liver microsomal samples. The kinetic data indicated that high and low affinity sites were present for the production of both metabolites of LY307640. The Km(apparent) and Vmax(apparent) for desmethyl LY307640 formation by microsomes from human liver E (HL-E) for the high affinity site were 18.8 +/- 4.4 microM and 402 +/- 52 pmol product/min/mg protein. The high affinity site Km(apparent) and Vmax(apparent) for LY307640 sulfone formation by microsomes from HL-E were 4.4 +/- 2.1 microM and 81.8 +/- 18 pmol product/min/mg protein. The rates of desmethyl LY307640 and LY307640 sulfone formation by the high affinity site were determined using 14 human liver microsomal samples characterized for P450 marker catalytic activities and immunoquantified levels of the P450s. Rates of formation of desmethyl LY307640 significantly correlated with the immunoquantified levels of CYP 2C19 and the ability of the microsomes to 4'-hydroxylate S-mephenytoin. LY307640 sulfone formation significantly correlated with the immunoquantified levels of CYP 3A and the ability of the microsomes to 1'-hydroxylate midazolam. Inhibition studies and use of expressed cytochrome P450 systems confirmed the correlation data demonstrating that CYP 2C19 catalyzed the formation of desmethyl LY307640 and CYP 3A and catalyzed LY307640 sulfone formation. Further, LY307640 competitively inhibited S-mephenytoin 4'-hydroxylation and midazolam 1'-hydroxylation as did the structurally related compound, omeprazole. For the inhibition of S-mephenytoin 4'-hydroxylation and midazolam 1'-hydroxylation, LY307640 had higher Ki(apparent) values than that of omeprazole. These studies demonstrate that the high affinity enzymes which catalyze the formation of the desmethyl and sulfone metabolites of LY307640 are, respectively, CYP 2C19 and CYP 3A. In addition, the inhibition data suggest that LY307640 has less potential to inhibit the metabolism of CYP 2C19 substrates compared to omeprazole, and that LY307640 and omeprazole have a similarly low potential to inhibit the metabolism of CYP 3A substrates.

Human cytochrome P450 3A (CYP3A) mediated midazolam metabolism: the effect of assay conditions and regioselective stimulation by alpha-naphthoflavone, terfenadine and testosterone.

The effect of ionic strength, assay constituents, alpha-naphthoflavone (aNF), terfenadine and testosterone on human CYP3A mediated midazolam (MDZ) 1'-hydroxylation (MDZ 1'-OH) and 4-hydroxylation (MDZ 4-OH) in vitro was examined. Increasing concentration of Tris-HCl (Tris) and sodium phosphate (PO4) buffers differentially affected MDZ 1'-OH and MDZ 4-OH formation rates and had a different effect on MDZ metabolism mediated by microsomes containing CYP3A4 versus CYP3A4 and CYP3A5. MDZ metabolism was not affected by PO4 buffer concentration when cumene hydroperoxide (CUOOH) was used as the source of reactive oxygen. Interestingly, the ammonium ion present in the solution of glucose 6-phosphate dehydrogenase was found to inhibit MDZ metabolism. The addition of MgCl2 up to 50 mM and CaCl2 (5-30 mM) had no affect or inhibited MDZ metabolism, respectively. Formation of MDZ 1'-OH by microsomes from adult and fetal liver and expressed CYP3A4 was regioselectively stimulated by aNF (10 microM). In human hepatocytes, aNF stimulated MDZ 1'-OH formation (up to 100%). Terfenadine (20 microM) regioselectively stimulated MDZ 1'-OH formation in Tris (1-200 mM) and PO4 (1-10 mM) buffers by up to 159%. Surprisingly, with expressed CYP3A4, terfenadine (20 microM) inhibited MDZ 1'-OH formation. Terfenadine (20 microM) had little effect on MDZ 1'-OH formation by fetal liver microsomes. Testosterone (10 and 100 microM) regioselectively stimulated (up to 269%) MDZ 4-OH formation by adult liver microsomes and expressed CYP3A4. Testosterone (100 microM) inhibited (> 40%) MDZ 1'-OH and MDZ 4-OH formation by fetal liver microsomes. With adult liver microsomes, aNF and terfenadine had little effect on the Km for MDZ 1'-OH formation. However, the Km for MDZ 4-OH formation was decreased (up to 94%) by 100 microM testosterone. In the presence of CUOOH, no stimulation of MDZ metabolism was observed by aNF, terfenadine or testosterone in adult liver microsomes. These studies indicate that because assay conditions can substantially alter the catalytic activity of CYP3A, caution should be exerted when extrapolating results between in vitro and in vivo, and when results from different laboratories are compared. Further, these results suggest that the stimulation of CYP3A4 may also occur in vivo and, consequently, may have clinical importance.

Three and four dimensional-quantitative structure activity relationship (3D/4D-QSAR) analyses of CYP2D6 inhibitors.

Three- and four-dimensional quantitative structure activity relationship (3D/4D-QSAR) pharmacophore models of competitive inhibitors of CYP2D6 were constructed using data from our laboratory or the literature. The 3D-QSAR pharmacophore models of the common structural features of CYP2D6 inhibitors were built using the program Catalyst (Molecular Simulations, San Diego, CA, USA). These 3D-QSAR models were compared with 3D and 4D-QSAR partial least squares (PLS) models which were constructed using molecular surface-weighted holistic invariant molecular (MS-WHIM) descriptors of size and shape of inhibitors. The first Catalyst model was generated from multiple conformers of competitive inhibitors (n = 20) of CYP2D6 mediated bufurolol 1'-hydroxylation. This model demonstrated a correlation of observed and predicted Ki (apparent) values of r = 0.75. A second Catalyst model was constructed from literature derived Ki (apparent) values (n = 31) for the inhibition of CYP2D6. This model provided a correlation of observed and predicted inhibition for CYP2D6 of r = 0.91. Both Catalyst Ki pharmacophores were then validated by predicting the Ki (apparent) of a test set of known CYP2D6 inhibitors (n = 15). Ten out of 15 of these Ki (apparent) values were predicted to be within one log residual of the observed value using our CYP2D6 inhibitor model, while the literature model predicted nine out of 15 values. Similarly, 3D- and 4D-QSARs derived from PLS MS-WHIM for our dataset yielded predictable models as assessed using cross-validation. The corresponding cross-validated PLS MS-WHIM model for the literature dataset yielded a comparable 3D-QSAR and improved 4D-QSAR value. Such computational models will aid in future prediction of drug-drug interactions.

Chronic effects of fractionated renal irradiation on the pharmacokinetics of intravenous methotrexate.

the chronic effects of renal irradiation on the pharmacology of methotrexate was studied in a rat model. Unanesthetized rats received 2 doses of bilateral fractionated kidney irradiation (16.2 Gy or 19.8 Gy in 9 fractions). Alterations in renal function were first seen at 3 months in the 19.8 Gy group and 12 months in the 16.2 Gy groups. Life table analysis showed a shift in the survival curve of about 3 months between the 2 radiation doses. The pharmacokinetics of i.v. methotrexate showed an increase in the area under the plasma curve beginning at 9 months in the 19.8 Gy group and at 15 months in the 16.2 Gy group. The volume of distribution of methotrexate was smaller in the irradiated rats than in unirradiated controls. Multiple linear regression models showed significant correlations between parameters of methotrexate clearance and certain renal function tests. Nevertheless, no set of renal function tests consistently predicted alteration in methotrexate clearance in the 2 radiation groups. Furthermore, time after irradiation remained a highly significant variable indicating that renal irradiation causes time dependent change in methotrexate pharmacokinetics that can not be accounted for by the usual tests of renal function.

Present and future in vitro approaches for drug metabolism.

The 1980s through 1990s witnessed the widespread incorporation of in vitro absorption, distribution, metabolism, and excretion (ADME) approaches into drug development by drug companies. This has been exemplified by the integration of the basic science of cytochrome P450s (CYPs) into most drug metabolism departments so that information on the metabolic pathways of drugs and drug-drug interactions (DDIs) is no longer an academic exercise, but essential for regulatory submission. This has come about due to the application of a variety of new technologies and in vitro models. For example, subcellular fractions have been widely used in metabolism studies since the 1960s. The last two decades has seen the increased use of hepatocytes as the reproducibility of cell isolations improved. The 1990s saw the rejuvenation of liver slices (as new slicers were developed) and the utilization of cDNA expressed enzymes as these technologies matured. In addition, there has been considerable interest in extrapolating in vitro data to in vivo for parameters such as absorption, clearance and DDIs. The current philosophy of drug development is moving to a 'fail early--fail cheaply' paradigm. Therefore, in vitro ADME approaches are being applied to drug candidates earlier in development since they are essential for identifying compounds likely to present ADME challenges in the latter stages of drug development. These in vitro tools are also being used earlier in lead optimization biology, in parallel with approaches for optimizing target structure activity relationships, as well as identification of DDI and the involvement of metabolic pathways that demonstrate genetic polymorphisms. This would suggest that the line between discovery and development drug metabolism has blurred. In vitro approaches to ADME are increasingly being linked with high-throughput automation and analysis. Further, if we think of perhaps the fastest available way to screen for successful drugs with optimal ADME characteristics, then we arrive at predictive computational algorithms, which are only now being generated and validated in parallel with in vitro and in vivo methods. In addition, as we increase the number of ADME parameters determined early, the overall amount of data generated for both discovery and development will increase. This will present challenges for the efficient and fast interpretation of such data, as well as incorporation and communication to chemistry, biology, and clinical colleagues. This review will focus on and assess the nature of present in vitro metabolism approaches and indicate how they are likely to develop in the future.

A novel testosterone 6 beta-hydroxylase activity assay for the study of CYP3A-mediated metabolism, inhibition, and induction in vitro.

INTRODUCTION: In order to examine CYP3A-mediated metabolism in vitro, a unique analytical assay was developed to detect the formation of 63-hydroxytestosterone (63-OHT). This assay has been determined to be useful for the study of both inhibition- and induction-related drug-drug interactions in vitro and involves simple incubation and sample handling procedures. METHODS: A primary and three backup sets of analytical conditions were developed to detect interference between a test compound and either 6beta-OHT or the internal standard. RESULTS: The primary set of conditions was validated with a three-batch validation, and the remaining sets of conditions were validated with one-batch validations, all in human liver microsomes. The primary assay was also validated with a single batch for CYP3A induction studies in primary human hepatocytes. Enzyme kinetic parameters of 6beta-OHT formation (Km, Vmax) were determined to be reproducible in human liver microsomes. DISCUSSION: Utility of the assay in inhibition studies and induction studies, respectively, was confirmed with the test compounds ketoconazole and rifampicin. In addition, superiority to existing methods was demonstrated in three areas: ease of sample preparation, short run times, and low detection limits.

Computed temperature distributions around ectatic capillaries exposed to yellow (578 nm) laser light.

We have numerically modelled the thermal effects of yellow (577 or 578 nm) light illumination on the ectatic blood vessels of port wine stains. We investigated the effect of the laser treatment parameters of light irradiance and illumination time on the extent of coagulation (coagulation thickness) of the endothelial cells of the ectatic vessels. We assumed that this coagulation is dependent on heating the cells to a critical temperature (coagulation temperature). We iteratively adjusted the treatment parameters so that the model vessels had a maximum temperature that did not exceed the boiling point of blood. Given the likely range of variation of coagulation temperature, coagulation thickness and vessel size, coagulation temperature was found to have the greatest effect on the treatment parameters. Variations in coagulation thickness had less influence, and the diameter of the ectatic vessel (typically in the 30-80 microns diameter range) had the least effect. The treatment parameters that have been shown clinically to cause purpura (e.g. 6-7 cm-2 in 360 microseconds) were also studied. The purpura seen by some workers using pulsed dye lasers is most likely to be the result of vaporisation of blood leading to the rupture of the vessel. We conclude that, in order to achieve coagulation with these short laser pulses, the choice of irradiance is critical.

Autoactivation and activation of the cytochrome P450s.

OBJECTIVE: In order to reliably predict in vivo pharmacokinetic parameters from in vitro data, we must thoroughly understand the systems we currently use to determine enzyme kinetic parameters. There have been a number of reports of atypical Michaelis-Menten kinetics for cytochrome- (CYP) P4503A mediated metabolism in vitro but little discussion of its clinical relevance. In this manuscript, we examined the scope of CYP autoactivation and confirmed that CYP1A2 demonstrates atypical Michaelis-Menten kinetics in vitro. MATERIALS: Human liver microsomes, baculovirus-expressed CYP1A2, CYP1A2 in the RECO format, and E. coli expressed CYP1A2 were utilized. METHODS: Enzyme kinetics were performed using the various human CYP1A2 sources and ethoxyresorufin O-deethylation as a prototypical biotransformation. The data were fit to various models of enzyme kinetics. In some cases the data best fit the Hill equation, which was used to empirically model allosteric-type autoactivation kinetics. RESULTS: RECO CYP1A2 and E. coli expressed CYPIA2 both demonstrated autoactivation kinetics for ethoxyresorufin O-deethylation. When the data were fit to the Hill equation, n (the slope factor) was found to be 1.4 and 1.8 for RECO and E. coli expressed CYP1A2, respectively. Human liver microsomal and insect expressed sources of CYP1A2 illustrated classical Michaelis-Menten kinetics for the O-deethylation of ethoxyresorufin. CONCLUSION: Data generated in the current study and previous work suggest many CYPs, not only CYP3A, appear to behave as allosteric enzymes. We would argue that this is not necessarily a classical allosteric mechanism because n is frequently a non-integer. This autoactivation appears to be a function of several factors including substrate physicochemical characteristics, specific interactions of the substrates (activators) with the enzyme active site, and presence of other enzyme modulators. These factors interact to increase the catalytic activity of CYP and thus the complexity of predicting enzyme kinetic parameters or drug interactions.

The lack of effects of alkylating agents on mammalian cell membranes.

The importance of cell membrane components as target sites for the action of 2,3,5-tris(ethyleneimino)-benzoquinone (Trenimon), mechlorethamine hydrochloride (HN2) and tris(2-chloroethyl) amine hydrochloride (HN3) was investigated. Uptake of 2-aminoisobutyric acid (AIBA) was studied under nonsaturating conditions where the transport system was rate-limiting for the uptake. Uptake of AIBA into L5178Y leukaemic cells was either inhibited or stimulated, depending on the type of the drug, the drug concentration and the length of incubation. Treatment of human erythrocytes with 10(-3) M HN3 produced new high-molecular-weight protein bands on SDS-polyacrylamide gel electrophoresis. Conversely, HN3 had no effect on L5178Y cell membrane proteins. Neither HN2 nor Trenimon produced any detectable changes in membrane proteins of L5178Y cells or human erythrocytes. None of the three drugs at concentrations and incubation conditions which inhibited cell replication changed the stoichiometry or dissociation constant of concanavalin A (Con A) binding sites on L5178Y cells. Trenimon at highly toxic concentrations had no effect on the fluidity of phospholipid membranes or of membranes of Ehrlich ascites tumour cells as analysed by ESR spin-label methods. The results presented here do not support the hypothesis that cell membranes are the primary target sites for alkylating drugs.

Thermal profiles of blood vessels heated by a laser.

Thermal profiles of ectatic capillaries, modelled on those found in port wine stain birthmarks, are calculated by a method of finite differences. Yellow 578nm light is assumed to illuminate these vessels. The coagulation of endothelial cells is assumed to occur when the cells are heated to at least 70 degrees C. We model this by asking that a point 6 microns above the top of the vessel lumen attains a temperature of 70 degrees C. We constrain the parameters to prevent heating of blood above 100 degrees C, so as to avoid vapourisation. The treatment parameters of dose and illumination time are varied until they produce thermal profiles that show the model's coagulation conditions. being treated and are rather longer than the thermal relaxation time of the vessel and also much longer than the pulses of pulsed dye lasers.

The use of in vitro metabolism techniques in the planning and interpretation of drug safety studies.

An important issue in toxicology is the suitability of the data obtained with experimental animals for human risk assessment. Because it is not possible to use humans in long-term toxicological studies, the use of animals will continue. However, the data obtained in animal studies can be better extrapolated to the patient by utilizing bridging studies with in vitro models of human drug metabolism. There are 2 basic categories of in vitro methods for the examination of human liver drug metabolism. The first group of in vitro methods consists of the cellular models, which include primary hepatocytes, liver slices, and cell lines. The second group is the use of preparations of the drug-metabolizing enzymes such as tissue homogenates, subcellular fractions, and isolated enzymes. Studies modeling both the human and experimental animal metabolism of a drug are useful in the design of toxicological studies. In vitro studies can identify metabolites, species-specific metabolic routes, and the experimental animal model that best reflects the potential human exposure to the drug and its metabolites. This information can also be useful in the design of the clinical studies by identifying human metabolites, the enzymes responsible for the metabolic clearance of the drug, the effects of genetics and other host factors on the metabolism of the drug, and potential drug-drug interactions. An example of how such information is generated and interpreted is presented.

Transfer of 2,4,5,2',4',5'-hexachlorobiphenyl across the in situ perfused guinea pig placenta.

The transplacental crossover of 14C-2,4,5,2',4',5'-hexachlorobiphenyl (6-CB) from the maternal circulation to the fetal side of the placenta was examined in intact fetuses and following the in situ perfusion of the guinea pig placenta. Fetal, late pregnant, and nonpregnant female guinea pig lipoprotein profiles and the association of 6-CB with these plasma constituents were also determined in vivo. Very low density lipoprotein (VLDL) concentrations were 10-fold higher in fetal than in maternal plasma, and the great majority of 6-CB which was transferred to intact fetuses became associated with this plasma fraction. 6-CB was found primarily in association with low density lipoproteins (LDL) in nonpregnant animals. In the late pregnant guinea pig, 6-CB became primarily associated with plasma protein in spite of circulating protein concentrations lower than those seen in the nonpregnant state. No differences in the levels of the three plasma lipoprotein classes were observed between pregnant and nonpregnant animals. It was found that an amount of 6-CB similar to that found in intact litter mates crossed the perfused placenta over the same time period. Despite the much higher VLDL concentrations on the fetal side of the placenta and the association of 6-CB with VLDL in intact fetuses, addition of 1,000 mg/dl VLDL to the 5.4% bovine serum albumin perfusion medium failed to influence the magnitude of 6-CB crossover. 6-CB crossover was influenced by protein concentration in the perfusion media in a concentration-dependent fashion. It is hypothesized that 6-CB and free fatty acids traverse the placenta and are retained by the fetus via similar mechanisms.

Influence of lipolysis on the mobilization of 2,4,5,2'4',5'-hexachlorobiphenyl from adipocytes in vitro.

Epididymal adipocytes, isolated from rats pretreated with [14C]-2,4,5,2',4',5'-hexachlorobiphenyl (6-CB), were utilized to examine the relationship between the mobilization of lipid and 6-CB and to determine whether 6-CB was differentially associated with subcellular organelles over time as has been demonstrated for newly synthesized lipid. Lipolysis, induced by the presence of 8 X 10(-7) M isoproterenol (ISO) for 50 min, depleted approximately 1% of total cellular triacylglycerols (TG) regardless of time from treatment with 6-CB. The percentage of cellular 6-CB released from adipocytes to incubation buffer infranatants was not correlated with the magnitude of lipolysis produced over the 50-min incubation period; nor was the percentage of 6-CB released to the buffers correlated with the length of the incubation period, regardless of the presence of ISO. Although adipocytes responded similarly to lipolytic stimuli independent of time (days) since 6-CB treatment, significant decreases were found in the percentage of 6-CB released from adipocytes over time. The in vitro labeling of this newly synthesized TG in fat cells with [U-14C]glucose or [1-14C]palmitate demonstrated that TG was differentially distributed among adipocyte organelles. Newly synthesized TG was also the first to be mobilized under lipolytic stimulus. 6-CB was not released in a similar fashion, since radioactivity associated with the chemical levels of [14C]-6-CB and glucose-derived 14C in buffers were not correlated over time. 6-CB was found to redistribute to all available lipid pools during the subcellular fractionation procedure and thus did not resemble TG. However, it is possible that 6-CB may exist in equilibrium among organelle fractions and that it becomes sequestered within the nonsoluble lipid compartment with time, thus decreasing its appearance in the soluble buffer infranatants over the experimental time course.

The human drug metabolizing cytochromes P450.

The superfamily of heme-thiolate proteins known as the cytochromes P450 is responsible for the oxidative metabolism of the majority of drugs. Thus, the phenotypes of individuals with respect to their levels of catalytically active cytochromes P450 determines to a large part the substantial interindividual variation observed in the metabolic clearance of drugs. Over the past 10 years 15 different human cytochromes P450 involved in drug metabolism have been isolated and characterized to varying degrees. This brief review discusses the characterization of these cytochromes P450 and how this knowledge has been used by the pharmaceutical industry to aid in the development of new drugs.

The influence of time of maternal exposure to 2,4,5,2',4',5'-hexachlorobiphenyl on its accumulation in their nursing offspring.

2,4,5,2',4',5'-Hexachlorobiphenyl (6-CB) is mobilized from rodent tissues during the lipid depletion associated with food restriction or lactation, the latter condition resulting in the substantial elimination of the maternal body burden of the chemical to nursing offspring. The present study was undertaken to determine whether the rate and/or magnitude of accumulation of 6-CB in nursing offspring differed with time following PCB administration to the maternal animal. Female ICR mice were administered two doses of 6-CB. Group I animals received [14C]-6-CB as weanlings (15-20 g) followed by unlabeled 6-CB 5 weeks later, after mating, on Day 1 of gestation. Group II received unlabeled 6-CB as weanlings and [14C]-6-CB on Day 1 of gestation. Thus, 14C identified the mobilization and elimination of either the first or the second dose of 6-CB in the treatment groups (I = [14C]-6-CB, 6-CB; II = 6-CB, [14C]-6-CB). Both groups of animals retained approximately 80% of the administered radiolabeled dose. The tissue distribution of [14C]-6-CB in group II as a percentage of the body burden was not different from that in group I as determined from maternal tissue concentrations on Day 14 of gestation. The percentage of the maternal body burden of [14C]-6-CB accumulated in suckling offspring of group II mothers was significantly greater than that in group I offspring on Day 1 (I, 2.2 +/- 0.5%; II, 3.5 +/- 0.4%), Day 3 (I, 14.8 +/- 1.9%; II, 24.6 +/- 2.7%), Day 5 (I, 16.8 +/- 1.4%; II, 24.8 +/- 0.8%), and Day 12 (I, 32.3 +/- 0.5%; II, 45.5 +/- 1.7%) postpartum. This differential elimination was reflected in the t1/2 of elimination of the radiolabeled dose from parametrial fat during lactation, which was significantly longer in group I (14 days) than group II maternal animals (9 days). The observations that the last dose of 6-CB administered was the first to be mobilized from the whole animal, and that this was reflected in 6-CB release from parametrial fat, suggest that this highly lipophilic chemical is not homogeneously distributed within storage depots.

Effect of fluoxetine, norfluoxetine, sertraline and desmethyl sertraline on human CYP3A catalyzed 1'-hydroxy midazolam formation in vitro.

The ability of fluoxetine, norfluoxetine, sertraline and desmethyl sertraline to inhibit the CYP3A subfamily of cytochromes P450 was examined in vitro, using the formation of 1'-hydroxy midazolam as a probe for CYP3A catalytic activity. The inhibition observed with these four compounds was modeled using competitive, noncompetitive, uncompetitive and mixed competitive/noncompetitive relationships by nonlinear regression analysis. The best fit model of the inhibition of CYP3A-mediated 1'-hydroxy midazolam formation by all four compounds examined was determined to be mixed inhibition. The calculated Ki values were 65.7 +/- 12.0 microM for fluoxetine, 19.1 +/- 1.9 microM for norfluoxetine, 64.4 +/- 11.6 microM for sertraline and 48.1 +/- 11.6 microM for desmethyl sertraline. Steady-state plasma levels of fluoxetine and norfluoxetine can approach a concentration of 1 microM (approximately 350 ng/ml of plasma). Assuming an inhibitor concentration of 1 microM and a concentration of the substrate substantially below its Km (at least 10-fold lower), the results reported predict that fluoxetine and norfluoxetine together would inhibit CYP3A catalytic activity by less than 7% (less than 0.7% if the unbound plasma concentration of fluoxetine is considered). By using the same assumptions and concentrations for sertraline and desmethyl sertraline, these agents together would be predicted to inhibit the metabolic clearance of a coadministered CYP3A metabolized drug by less than 4%. The observations reported here suggest that fluoxetine and sertraline would have little effect on CYP3A-mediated clearance of coadministered drugs.