John A. Easter

Multiplexed LC-MS/MS method for the simultaneous quantitation of three novel hepatitis C antivirals, daclatasvir, asunaprevir, and beclabuvir in human plasma

Dual or triple combination regimens of novel hepatitis C direct-acting antivirals (DAA, daclatasvir, asunaprevir, or beclabuvir) provide high sustained virological response rates and reduced frequency of resistance compared to clinical monotherapy. To support pharmacokinetic (PK) assessments in clinical studies, a multiplexed liquid chromatography-tandem mass spectrometry (LC-MS/MS) method for the simultaneous quantitation of daclatasvir, asunaprevir, beclabuvir (BMS-791325) and its active metabolite (BMS-794712) in human plasma was developed and validated. Human plasma samples were extracted with methyl-t-butyl ether followed by an LC-MS/MS analysis, which was conducted in a multiple reaction monitoring (MRM) mode. The lower limits of quantitation (LLOQ) were 1 ng/mL for daclatasvir, asunaprevir, and BMS-794712, and 2 ng/mL for beclabuvir. Intra-run precision (≤4.5% CV), inter-run precision (≤2.9% CV), and accuracy (±5.3% deviation) based on different concentration levels (low, geometric mean, mid and high) of the quality control samples (QCs) provided evidence of the methods accuracy and precision. Selectivity and matrix effect on LC-MS/MS detection, stability in plasma, and potential interference of coadministered drugs (ribavirin and interferon) were all evaluated and the results were acceptable. Method reproducibility was demonstrated by the reanalysis of a portion of study samples. The cross-validation results for QCs demonstrated the equivalency between this method and two single-analyte methods which were previously validated for quantitation of daclatasvir in human plasma. This approach of using a multiplexed LC-MS/MS method for the simultaneous quantitation of three DAAs is time- and cost-effective, and can maintain good data quality in sample analysis.

Practical and Efficient Strategy for Evaluating Oral Absolute Bioavailability with an Intravenous Microdose of a Stable Isotopically-Labeled Drug Using a Selected Reaction Monitoring Mass Spectrometry Assay

A strategy of using selected reaction monitoring (SRM) mass spectrometry for evaluating oral absolute bioavailability with concurrent intravenous (i.v.) microdosing a stable isotopically labeled (SIL) drug was developed and validated. First, the isotopic contribution to SRM (ICSRM) of the proposed SIL drug and SIL internal standard (IS) was theoretically calculated to guide their chemical synthesis. Second, the lack of an isotope effect on drug exposure was evaluated in a monkey study by i.v. dosing a mixture of the SIL and the unlabeled drugs. Third, after the SIL drug (100 μg) was concurrently i.v. dosed to humans, at T(max) of an oral therapeutic dose of the unlabeled drug, both drugs in plasma specimens were simultaneously quantified by a sensitive and accurate SRM assay. This strategy significantly improves bioanalytical data quality and saves time, costs, and resources by avoiding a traditional absolute bioavailability study or the newer approach of microdoses of a radio-microtracer measured by accelerator mass spectrometry.

Calculation and Mitigation of Isotopic Interferences in Liquid Chromatography–Mass Spectrometry/Mass Spectrometry Assays and Its Application in Supporting Microdose Absolute Bioavailability Studies

A methodology for the accurate calculation and mitigation of isotopic interferences in liquid chromatography-mass spectrometry/mass spectrometry (LC-MS/MS) assays and its application in supporting microdose absolute bioavailability studies are reported for the first time. For simplicity, this calculation methodology and the strategy to minimize the isotopic interference are demonstrated using a simple molecule entity, then applied to actual development drugs. The exact isotopic interferences calculated with this methodology were often much less than the traditionally used, overestimated isotopic interferences simply based on the molecular isotope abundance. One application of the methodology is the selection of a stable isotopically labeled internal standard (SIL-IS) for an LC-MS/MS bioanalytical assay. The second application is the selection of an SIL analogue for use in intravenous (i.v.) microdosing for the determination of absolute bioavailability. In the case of microdosing, the traditional approach of calculating isotopic interferences can result in selecting a labeling scheme that overlabels the i.v.-dosed drug or leads to incorrect conclusions on the feasibility of using an SIL drug and analysis by LC-MS/MS. The methodology presented here can guide the synthesis by accurately calculating the isotopic interferences when labeling at different positions, using different selective reaction monitoring (SRM) transitions or adding more labeling positions. This methodology has been successfully applied to the selection of the labeled i.v.-dosed drugs for use in two microdose absolute bioavailability studies, before initiating the chemical synthesis. With this methodology, significant time and cost saving can be achieved in supporting microdose absolute bioavailability studies with stable labeled drugs.

Challenges in Accurate Quantitation of Lysophosphatidic Acids in Human Biofluids

Lysophosphatidic acids (LPAs) are biologically active signaling molecules involved in the regulation of many cellular processes and have been implicated as potential mediators of fibroblast recruitment to the pulmonary airspace, pointing to possible involvement of LPA in the pathology of pulmonary fibrosis. LPAs have been measured in various biological matrices and many challenges involved with their analyses have been documented. However, little published information is available describing LPA levels in human bronchoalveolar lavage fluid (BALF). We therefore conducted detailed investigations into the effects of extensive sample handling and sample preparation conditions on LPA levels in human BALF. Further, targeted lipid profiling of human BALF and plasma identified the most abundant lysophospholipids likely to interfere with LPA measurements. We present the findings from these investigations, highlighting the importance of well-controlled sample handling for the accurate quantitation of LPA. Further, we show that chromatographic separation of individual LPA species from their corresponding lysophospholipid species is critical to avoid reporting artificially elevated levels. The optimized sample preparation and LC/MS/MS method was qualified using a stable isotope-labeled LPA as a surrogate calibrant and used to determine LPA levels in human BALF and plasma from a Phase 0 clinical study comparing idiopathic pulmonary fibrosis patients to healthy controls.

An asymmetric synthesis of (R)‐5‐(methylamino)‐5,6‐dihydro‐4H‐imidazo‐[4,5,1‐ij]quinolin‐2(1H)‐one (1) and its [2‐14C]‐ and [6,7‐3H2]‐labeled forms

(R)-5-(Methylamino)-5,6-dihydro-4H-imidazo[4,5,1-ij]quinolin-2(1H)-one (1) is a dopamine agonist which shows selectivity for the D2 receptor subtype, and is of interest as a potential drug for the treatment of Parkinsons disease. An asymmetric epoxidation approach has been used to prepare 1 in eleven steps (15% overall yield) from 8-nitroquinoline. An advanced intermediate in this synthesis, tert-butyl (R)-methyl(8-amino-1,2,3,4-tetrahydro-3-quinolinyl)carbamate (10), has been reacted with [ 14 C]phosgene to provide a two-step synthesis of 1 labeled with carbon-14 at the C-2 position (236 μCi/mg). Bromination of 1 gave the dibromo analogue 12b which was reduced in the presence of tritium gas to give 1 labeled with tritium at the C-6 and C-7 positions (28.5 Ci/mmol). In addition to providing syntheses for labeled forms of the drug which are useful in drug disposition and receptor binding studies, this approach also provides a convenient synthesis for the unlabeled form of drug

Application of In-Line Liquid Chromatography-Accurate Radioisotope Counting-Mass Spectrometry (LC-ARC-MS) to Evaluate Metabolic Profile of [3H]-Mefenamic Acid in Rat Plasma

Profiling of rat plasma using a highly sensitive LC-ARC-MS technique showed that [(3)H] mefenamic acid was metabolized to several products, including a sulfate conjugate and a hydroxylated analogue as major metabolites. This technique of detecting low levels of radioactivity in plasma was superior to previously used methods, such as beta-RAM detectors.

Characterization of ADME properties of [(14)C]asunaprevir (BMS-650032) in humans.

Abstract 1. Asunaprevir (ASV, BMS-650032), a highly selective and potent NS3 protease inhibitor, is currently under development for the treatment of chronic hepatic C virus infection. This study describes in vivo biotransformation in humans and the identification of metabolic enzymes of ASV. 2. Following a single oral dose of [14C]ASV to humans, the majority of radioactivity (>73% of the dose) was excreted in feces with <1% of the dose recovered in urine. Drug-related radioactivity readily appeared in circulation and the plasma radioactivity was mainly attributed to ASV. A few minor metabolites were observed in human plasma and are not expected to contribute to the pharmacological activity because of low levels. The area under the curve (AUC) values of each circulating metabolite in humans were well below their levels in animals used in the long-term toxicological studies. In bile and feces, intact ASV was a prominent radioactive peak suggesting that both metabolism and direct excretion played important roles in ASV clearance. 3. The primary metabolic pathways of ASV were hydroxylation, sulfonamide hydrolysis and the loss of isoquinoline. In vitro studies with human cDNA expressed CYP enzymes and with human liver microsomes (HLM) in the presence of selective chemical inhibitors demonstrated that ASV was primarily catalyzed by CYP3A4 and CYP3A5.

Synthesis of isotopically labeled daclatasvir for use in human clinical studies

Daclatasvir is a novel hepatitis C virus NS5A inhibitor developed by Bristol-Myers Squibb and marketed as Daklinza®. The need to support the development of daclatasvir required the synthesis of carbon-14 labeled material for use in human absorption, distribution, metabolism, and excretion studies. A total of 7.53 mCi of [(14) C]-daclatasvir was synthesized in eight steps from commercially available [(14) C]-copper cyanide. The radiochemical purity was 99.6%, and specific activity was 3.86 μCi/mg. To support a human absolute bioavailability study, 5.56 g of [(13) C2 , (15) N4 ]-daclatasvir was synthesized in four steps.

Biotransformation of Daclatasvir In Vitro and in Nonclinical Species: Formation of the Main Metabolite by Pyrrolidine δ-Oxidation and Rearrangement

Daclatasvir is a first-in-class, potent, and selective inhibitor of the hepatitis C virus nonstructural protein 5A replication complex. In support of nonclinical studies during discovery and exploratory development, liquid chromatography–tandem mass spectrometry and nuclear magnetic resonance were used in connection with synthetic and radiosynthetic approaches to investigate the biotransformation of daclatasvir in vitro and in cynomolgus monkeys, dogs, mice, and rats. The results of these studies indicated that disposition of daclatasvir was accomplished mainly by the release of unchanged daclatasvir into bile and feces and, secondarily, by oxidative metabolism. Cytochrome P450s were the main enzymes involved in the metabolism of daclatasvir. Oxidative pathways included δ-oxidation of the pyrrolidine moiety, resulting in ring opening to an aminoaldehyde intermediate followed by an intramolecular reaction between the aldehyde and the proximal imidazole nitrogen atom. Despite robust formation of the resulting metabolite in multiple systems, rates of covalent binding to protein associated with metabolism of daclatasvir were modest (55.2–67.8 pmol/mg/h) in nicotinamide adenine dinucleotide phosphate (reduced form)–supplemented liver microsomes (human, monkey, rat), suggesting that intramolecular rearrangement was favored over intermolecular binding in the formation of this metabolite. This biotransformation profile supported the continued development of daclatasvir, which is now marketed for the treatment of chronic hepatitis C virus infection.

Synthesis of carbon-14 and stable isotope labeled Avagacestat: a novel gamma secretase inhibitor for the treatment of Alzheimer's disease

Bristol-Myers Squibb and others are developing drugs that target novel mechanisms to combat Alzheimers disease. γ-Secretase inhibitors are one class of potential therapies that have received considerable attention. (R)-2-(4-Chloro-N-(2-fluoro-4-(1,2,4-oxadiazol-3-yl)benzyl)phenylsulfonamido)-5,5,5-trifluoropentanamide (Avagacestat) is a γ-secretase-inhibiting drug that has been investigated by Bristol-Myers Squibb in preclinical and clinical studies. An important step in the development process was the synthesis of a carbon-14-labeled analog for use in a human absorption, distribution, metabolism, and excretion study and a stable isotope labeled analog for use as a standard in bioanalytical assays to accurately quantify the concentration of the drug in biological samples. Carbon-14 labeled Avagacestat was synthesized in seven steps in a 33% overall yield from carbon-14 labeled potassium cyanide. A total of 5.95 mCi was prepared with a specific activity of 0.81 μCi/mg and a radiochemical purity of 99.9%. (13) C6 -Labeled Avagacestat was synthesized in three steps in a 15% overall yield from 4-chloro[(13) C6 ]aniline. A total of 585 mg was prepared with a ultraviolet purity of 99.9%.