Johan Bylund

Practical use of the regression offset approach for the prediction of in vivo intrinsic clearance from hepatocytes

Systematic under-prediction of clearance is frequently associated with in vitro kinetic data when extrapolated using physiological scaling factors, appropriate binding parameters and the well-stirred model. The present study describes a method of removing this systematic bias through application of empirical correction factors derived from regression analyses applied to the in vitro and in vivo data for a defined set of reference compounds. Linear regression lines were established with in vivo intrinsic clearance (CLint), derived from in vivo clearance data and scaled in vitro intrinsic clearance from isolated hepatocyte incubations. The scaled CLint was empirically corrected to a predicted in vivo CLint using the slope and intercept from a uniform weighted linear regression applied to the in vitro to in vivo extrapolation. Cross validation of human data demonstrated that 66% of the reference compounds had a predicted in vivo CLint within two-fold of the observed value. The average absolute fold error (AAFE) for the in vivo CLint predictions was 1.90. For rat, 54% of the compounds had a predicted value within two-fold of the observed and the AAFE was 1.98. Three AstraZeneca projects are used to exemplify how a two-sided prediction interval, applied to the rat regression corrected reference data, can form the basis for assessing the likelihood that, for a given chemical series, the in vitro kinetic data is predictive of in vivo clearance and is therefore appropriate to guide optimisation of compound metabolic stability.

The Impact of Solute Carrier (SLC) Drug Uptake Transporter Loss in Human and Rat Cryopreserved Hepatocytes on Clearance Predictions

Cryopreserved hepatocytes are often used as a convenient tool in studies of hepatic drug metabolism and disposition. In this study, the expression and activity of drug transporters in human and rat fresh and cryopreserved hepatocytes was investigated. In human cryopreserved hepatocytes, Western blot analysis indicated that protein expression of the drug uptake transporters [human Na+-taurocholate cotransporting polypeptide (NTCP), human organic anion transporting polypeptides (OATPs), human organic anion transporters, and human organic cation transporters (OCTs)] was considerably reduced compared with liver tissue. In rat cryopreserved cells, the same trend was observed but to a lesser extent. Several rat transporters were reduced as a result of both isolation and cryopreservation procedures. Immunofluorescence showed that a large portion of remaining human OATP1B1 and OATP1B3 transporters were internalized in human cryopreserved hepatocytes. Measuring uptake activity using known substrates of OATPs, OCTs, and NTCP showed decreased activity in cryopreserved as compared with fresh hepatocytes in both species. The reduced uptake in cryopreserved hepatocytes limited the in vitro metabolism of several AstraZeneca compounds. A retrospective analysis of clearance predictions of AstraZeneca compounds suggested systematic lower clearance predicted using metabolic stability data from human cryopreserved hepatocytes compared with human liver microsomes. This observation is consistent with a loss of drug uptake transporters in cryopreserved hepatocytes. In contrast, the predicted metabolic clearance from fresh rat hepatocytes was consistently higher than those predicted from liver microsomes, consistent with retention of uptake transporters. The uptake transporters, which are decreased in cryopreserved hepatocytes, may be rate-limiting for the metabolism of the compounds and thus be one explanation for underpredictions of in vivo metabolic clearance from cryopreserved hepatocytes.

Rat poorly predicts the combined non-absorbed and presystemically metabolized fractions in the human.

Abstract 1. Intestinal loss, 1 − (Fobs/fH), is the missing fraction of the dose that is unexplained by systemic clearance. Here, we investigated whether intestinal loss in rat is predictive for human, and whether intestinal metabolism explained observed differences between rat and human. 2. For 81 marketed drugs, human and rat intestinal loss values were calculated from the literature and in-house sources. To examine the contribution of intestinal cytochrome P450-mediated metabolism to the high observed intestinal loss in the rat, metabolism was determined in rat and human intestinal microsomes for 15 compounds. 3. Oral bioavailability poorly correlated between rat and human. Twenty-two compounds in the human and 47 compounds in the rat showed an intestinal loss of more than 20%. The intestinal availability for many compounds was higher in human than in rat. Selected compounds, however, were more stable in rat than in human intestinal microsomes. 4. The rat poorly predicts the risk for intestinal loss in human; many compounds in rat had lower bioavailability than anticipated based on the hepatic clearance, but demonstrated little intestinal loss in human. This discrepancy appeared not to be caused by a higher cytochrome P450-mediated intestinal metabolism in the rat.

Discovery of novel pyrrolopyridazine scaffolds as transient receptor potential vanilloid (TRPV1) antagonists.

A novel indolizine class of compounds was identified as TRPV1 antagonist from an HTS campaign. However, this indolizine class proved to be unstable and reacted readily with glutathione when exposed to light and oxygen. Reactivity was reduced by the introduction of a nitrogen atom alpha to the indolizine nitrogen. The pyrrolopyridazine core obtained proved to be inert to the action of light and oxygen. The synthesis route followed the one used for the indolizine compounds, and the potency and ADMET profile proved to be similar.

Phenyl isoxazole voltage-gated sodium channel blockers: structure and activity relationship.

Blocking of certain sodium channels is considered to be an attractive mechanism to treat chronic pain conditions. Phenyl isoxazole carbamate 1 was identified as a potent and selective Na(V)1.7 blocker. Structural analogues of 1, both carbamates, ureas and amides, were proven to be useful in establishing the structure-activity relationship and improving ADME related properties. Amide 24 showed a good overall in vitro profile, that translated well to rat in vivo PK.

Amide Hydrolysis of a Novel Chemical Series of Microsomal Prostaglandin E Synthase-1 Inhibitors Induces Kidney Toxicity in the Rat

A novel microsomal prostaglandin E synthase 1 (mPGES-1) inhibitor induced kidney injury at exposures representing less than 4 times the anticipated efficacious exposure in man during a 7-day toxicity study in rats. The findings consisted mainly of tubular lesions and the presence of crystalline material and increases in plasma urea and creatinine. In vitro and in vivo metabolic profiling generated a working hypothesis that a bis-sulfonamide metabolite (determined M1) formed by amide hydrolysis caused this toxicity. To test this hypothesis, rats were subjected to a 7-day study and were administered the suspected metabolite and two low-potency mPGES-1 inhibitor analogs, where amide hydrolysis was undetectable in rat hepatocyte experiments. The results suggested that compounds with a reduced propensity to undergo amide hydrolysis, thus having less ability to form M1, reduced the risk of inducing kidney toxicity. Rats treated with M1 alone showed no histopathologic change in the kidney, which was likely related to underexposure to M1. To circumvent rat kidney toxicity, we identified a potent mPGES-1 inhibitor with a low propensity for amide hydrolysis and superior rat pharmacokinetic properties. A subsequent 14-day rat toxicity study showed that this compound was associated with kidney toxicity at 42, but not 21, times the anticipated efficacious exposure in humans. In conclusion, by including metabolic profiling and exploratory rat toxicity studies, a new and active mPGES-1 inhibitor with improved margins to chemically induced kidney toxicity in rats has been identified.

Exploration and Pharmacokinetic Profiling of Phenylalanine Based Carbamates as Novel Substance P 1–7 Analogues

The bioactive metabolite of Substance P, the heptapeptide SP1-7 (H-Arg-Pro-Lys-Pro-Gln-Gln-Phe-OH), has been shown to attenuate signs of hyperalgesia in diabetic mice, which indicate a possible use of compounds targeting the SP1-7 binding site as analgesics for neuropathic pain. Aiming at the development of drug-like SP1-7 peptidomimetics we have previously reported on the discovery of H-Phe-Phe-NH2 as a high affinity lead compound. Unfortunately, the pharmacophore of this compound was accompanied by a poor pharmacokinetic (PK) profile. Herein, further lead optimization of H-Phe-Phe-NH2 by substituting the N-terminal phenylalanine for a benzylcarbamate group giving a new type of SP1-7 analogues with good binding affinities is reported. Extensive in vitro as well as in vivo PK characterization is presented for this compound. Evaluation of different C-terminal functional groups, i.e., hydroxamic acid, acyl sulfonamide, acyl cyanamide, acyl hydrazine, and oxadiazole, suggested hydroxamic acid as a bioisosteric replacement for the original primary amide.

Metabolic profiling of TRPV1 antagonists of the benzothiazole amide series: implications for in vitro genotoxicity assessment.

1. In vitro metabolic profiling and in vitro genotoxicity assessment are important aspects of the drug discovery program as they eliminate harmful compounds from further development. In standard in vitro genotoxicity testing, induced rat liver S9 is used as an exogenous bio-activation system for detecting promutagens. In this study we show that rat liver S9 is an insufficient system regarding the conversion of TRPV1 antagonists of the benzothiazole amide series into relevant in vivo metabolites. 2. Human and rat hepatocyte experiments demonstrated generation of an aryl amine metabolite that was subsequently N-acetylated. The hydrolyzed metabolites as well as the parent compound were also metabolized into glutathione (GSH) conjugates. Rat liver S9 exhibited a very low amide hydrolysis capacity and no formation of GSH conjugates when supplemented with NADPH and GSH. 3. The discrepancy in metabolic capability between hepatocytes and rat liver S9 led to confounding results in in vitro genotoxicity assessment for this chemical class as judged by the results of Ames test, mouse lymphoma assay, SOS/umu test and Comet assay in rat hepatocytes. 4. This study highlights the pivotal role that understanding the mechanism of metabolite formation has in interpreting as well as designing reliable and relevant in vitro genotoxicity experiments.

Potent and orally efficacious benzothiazole amides as TRPV1 antagonists.

Benzothiazole amides were identified as TRPV1 antagonists from high throughput screening using recombinant human TRPV1 receptor and structure-activity relationships were explored to pinpoint key pharmacophore interactions. By increasing aqueous solubility, through the attachment of polar groups to the benzothiazole core, and enhancing metabolic stability, by blocking metabolic sites, the drug-like properties and pharmokinetic profiles of benzothiazole compounds were sufficiently optimized such that their therapeutic potential could be verified in rat pharmacological models of pain.

Novel bioactivation mechanism of reactive metabolite formation from phenyl methyl-isoxazoles

Recently, we described a series of phenyl methyl-isoxazole derivatives as novel, potent, and selective inhibitors of the voltage-gated sodium channel type 1.7 (Bioorg Med Chem Lett 21:3871–3876, 2011). The lead compound, 2-chloro-6-fluorobenzyl [3-(2,6-dichlorophenyl)-5-methylisoxazol-4-yl]carbamate, showed unprecedented GSH and cysteine reactivity associated with NADPH-dependent metabolism in trapping studies using human liver microsomes. Additional trapping experiments with close analogs and mass spectra and NMR analyses suggested that the conjugates were attached directly to the 5′-methyl on the isoxazole moiety. We propose a mechanism of bioactivation via an initial oxidation of the 5′-methyl generating a stabilized enimine intermediate and a subsequent GSH attack on the 5′-methylene. Efforts to ameliorate reactive metabolite generation were undertaken to minimize the potential risk of toxicity. Formation of reactive metabolites could be significantly reduced or prevented by removing the 5′-methyl, by N-methylation of the carbamate; by replacing the nitrogen with a carbon or removing the nitrogen to obtain a carboxylate; or by inserting an isomeric 5′-methyl isoxazole. The effectiveness of these various chemical modifications in reducing GSH adduct formation is in line with the proposed mechanism. In conclusion, we have identified a novel mechanism of bioactivation of phenyl 5-methyl-isoxazol-4-yl-amines. The reactivity was attenuated by several modifications aimed to prevent the emergence of an enimine intermediate. Whether 5′-methyl isoxazoles should be considered a structural alert for potential formation of reactive metabolites is dependent on their context, i.e., 4′-nitrogen.