Deuterated active pharmaceutical ingredients: A science-based proposal for synthesis, analysis, and control. Part 1: Framing the problem.

The International Consortium for Innovation & Quality (IQ) in Pharmaceutical Development recently established a working group focused on the development of a guidance to address Deuterated Active Pharmaceutical Ingredients. Deuteration of an Active Pharmaceutical Ingredient (API) in some cases can retard and/or alter API metabolism by exploiting the primary kinetic isotope effect. Several deuterated APIs have entered into the clinic, and one has recently been approved. In most cases, it is very difficult to nearly impossible to synthesize a 100% isotopically pure compound. This raises synthetic, analytical, and regulatory questions that warrant a science-based assessment and recommendations for synthetic methods, analytical methods, and specifications. A cross functional team of scientists with expertise in isotope chemistry, process chemistry, analytical chemistry, and drug metabolism and pharmacokinetics have been meeting under the auspices of IQ to define and address these questions. This paper strives to frame chemistry, manufacturing, and controls challenges.

New radical methods for the potential synthesis of carbon-13 and carbon-14 labeled complex products.

The isotopic labeling of molecules for agrichemical and pharmaceutical uses is becoming more challenging as molecules become larger, involve more stereochemistry, and as intellectual property rights become more complex. As such, isotope chemists need to continually add new isotopic methods to their armamentarium to successfully label complex molecules with carbon-13 and carbon-14. Recently, there has been a surge in the use of radicals to form new carbon-carbon bonds and for the incorporation of functional groups which can be used to incorporate isotopically labeled carbons. This review will describe some potential new radical methods for incorporating isotopically labeled carbon into complex molecules or into substrates that can be attached to late stage intermediates to generate labeled products.

The syntheses of [13 C6 ] and [phenyl-14 C(U)]BMS-816336, an inhibitor of 11ß-hydroxysteroid dehydrogenase type 1, for type 2 diabetes.

Type 2 diabetes is a significant worldwide health problem. To support the development of BMS-816336 as an inhibitor of 11ß-hydroxysteroid dehydrogenase type 1 for type 2 diabetes, the synthesis of carbon-14 labeled material was required for use in metabolic profiling. [Phenyl-14 C(U)]BMS-816336 was synthesized in 8 steps and 22% radiochemical yield from commercially available [14 C(U)]bromobenzene. The radiochemical purity of [phenyl-14 C(U)]BMS-816336 was 100% having a specific activity of 84.4 µCi/mg or 28.8 mCi/mmol for a total of 8.9 mCi. It was also necessary to synthesize [13 C6 ]BMS-816336 for use as a liquid chromatography/mass spectrometry standard. [13 C6 ]BMS-816336 was also prepared in 8 labeled steps in 26% yield from [13 C6 ]bromobenzene.

The synthesis of [1-14 C]2-(1H-tetrazol-5-yl)acetic acid.

Tetrazoles are a common heterocyclic functionality in many biologically active molecules. [1-14 C]2-(1H-Tetrazol-5-yl)acetic acid was required as an intermediate in the synthesis of a development candidate as part of a discovery phase program to complete metabolic profiling studies. [1-14 C]2-(1H-Tetrazol-5-yl)acetic acid was prepared in 4 steps overall and in 3 radiochemical steps from K14 CN in an overall 32% radiochemical yield.

The synthesis of [14 C]4-acetylphenylalanine, effect on cell viability, and assessment of protein incorporation in male rat hepatocytes.

PEGylation is a proven approach to prolonging the duration of action and enhancing biophysical solubility and stability of peptides. 4-Acetylphenylalanine is a novel amino acid with a ketone side chain that is uniquely reactive in proteins. The ketone functionality can react with an aminooxy functionalized polyethyleneglycol polymer to form a stable oxime adduct of the protein. One concern with using unnatural amino acids, such as 4-acetylphenylalanine, is the possibility of it being cleaved from the peptide and becoming incorporated into endogenous proteins. To determine whether this occurs, an in vitro experiment to assess the cell viability and amino acid incorporation into endogenous proteins using primary male rat hepatocytes in the presence of [14 C]4-acetylphenylalanine, 4 or [14 C(U)]L-phenylalanine was conducted. [14 C]4-acetylphenylalanine, 4 was prepared in 2 radiochemical steps from [1-14 C]acetyl chloride in an overall 8% radiochemical yield and in 99.9% radiochemical purity. The results showed that there was no evidence of carbon-14 incorporation into hepatocyte endogenous proteins with [14 C]pAcF and there was no difference between it and L-phenylalanine in cell viability assessments at any of the concentrations studied between 0.1 and 1000 µM.

The synthesis and analysis of [phenyl-14 C(U)]BMS-770767 and [13 C6 ]BMS-770767 for use in discovery biotransformation, human ADME and bioanalytical studies.

Type 2 diabetes is a significant worldwide health problem. To support the development of BMS-770767 as an inhibitor of 11ß-hydroxysteroid dehydrogenase type 1 (11ß-HSD1) for type 2 diabetes was required the synthesis of carbon-14-labelled material for use in metabolic profiling and for the human adsorption, distribution, metabolism and excretion (ADME) study. Initially, [phenyl-14 C(U)]BMS-770767 was synthesized in two steps from a late-stage intermediate and [14 C(U)]2-chlorophenol to give the desired final product in 18% yield. Later, the synthesis was completed for the human ADME clinical study using a combination of the discovery and process chemistry routes under cGMP to prepare [phenyl-14 C(U)]BMS-770767. The radiochemical purity of the synthesized [phenyl-14 C(U)]BMS-770767 after dilution with unlabelled clinical grade BMS-770767 was 99.1% having a specific activity of 1.61 µCi/mg. In addition, to support the quantification of BMS-770767 in LC/MS analyses, [13 C6 ]BMT-770767 was prepared in two steps from a late-stage intermediate and [13 C6 ]2-chlorophenol.

The syntheses of [(14) C]BMS-823778 for use in a human ADME clinical study and of [(13) CD3 (13) CD2 ]BMT-094817, a stable-isotope labeled standard of a newly detected human metabolite.

Type 2 diabetes is a significant worldwide health problem. To support the development of BMS-823778 as an inhibitor of 11ß-hydroxysteroid dehydrogenase type 1 for type 2 diabetes, the synthesis of carbon-14-labeled material was required for use in a human adsorption, distribution, metabolism, and excretion (ADME) study. The HCl salt form of [(14) C]BMS-823778 was synthesized in two steps from commercially available [2-(14) C]acetone. The radiochemical purity of the synthesized [(14) C]BMS-823778 after dilution with unlabeled clinical-grade BMS-823778 was 99.5% having a specific activity of 7.379 µCi/mg. One result of the human ADME study was the detection of a new human metabolite, BMT-094817. To support the quantification of BMT-094817 in clinical samples, it was necessary to synthesize [(13) CD3 (13) CD2 ]BMT-094817 for use as a liquid chromatography/mass spectrometry standard. [(13) CD3 (13) CD2 ]BMT-094817 was prepared in five labeled steps from [(13) CD3 ]iodomethane.

The syntheses of isotopically labelled CB-1 antagonists for the treatment of obesity.

BMS-725519, BMS-811064, and BMS-812204 are potent and selective central cannabinoid receptor antagonists that have been investigated for the treatment of human obesity. To further understand their biotransformation profiles, radiolabelled and stable-labelled products were required. This paper describes the utility of [14 C]1,1-carbonyldiimidazole as a radiolabelling reagent for the syntheses of carbonyl-labelled [14 C]BMS-725519, [14 C]BMS-811064, and [14 C]BMS-812204. The syntheses of stable-labelled [13 C6 ]BMS-725519 and [13 CD313 CD2 ]BMS-812204 synthesized from of [13 C6 ]4-chloroacetophenone and [13 CD313 CD2 ]iodoethane, respectively, are also described.

Hydromethylation of Unactivated Olefins.

A solution to the classic unsolved problem of olefin hydromethylation is presented. This highly chemoselective method can tolerate labile and reactive chemical functionalities and uses a simple set of reagents. An array of olefins, including mono-, di-, and trisubstituted olefins, are all smoothly hydromethylated. This mild protocol can be used to simplify the synthesis of a specific target or to directly "edit" complex natural products and other advanced materials. The method is also amenable to the simple installation of radioactive and stable labeled methyl groups.

Synthesis of Biologically Active Piperidine Metabolites of Clopidogrel: Determination of Structure and Analyte Development.

Clopidogrel is a prodrug anticoagulant with active metabolites that irreversibly inhibit the platelet surface GPCR P2Y12 and thus inhibit platelet activation. However, gaining an understanding of patient response has been limited due to imprecise understanding of metabolite activity and stereochemistry, and a lack of acceptable analytes for quantifying in vivo metabolite formation. Methods for the production of all bioactive metabolites of clopidogrel, their stereochemical assignment, and the development of stable analytes via three conceptually orthogonal routes are disclosed.

The synthesis of 14C-labeled N-succinimidyl-3-maleimidopropionate, a linker molecule for PEGylated biologics.

Carbon-14 labeled linker molecule, N-succinimidyl-3-maleimidopropionate was prepared for disposition studies of PEGylated biologics. Our new route started with 100 mCi of carbon-14 labeled Potassium cyanide (KCN) to prepare 55 mCi of [1-(14)C]N-succinimidyl-3-maleimidopropionate, 6 in five steps. This represents a multiple of 5.5× improvement in the yield of the desired labeled product compared with our previous synthesis.

The synthesis of (14)C-labeled, (13)CD2-labeled saxagliptin, and its (13)CD2-labeled 5-hydroxy metabolite.

(14)C-labeled saxagliptin, (13) CD2-labeled saxagliptin, and its (13) CD2-labeled 5-hydroxy metabolite were synthesized to further support development of the compound for biological studies. This paper describes new syntheses leading to the desired compounds. A total of 3.0 mCi of (14)C-labeled saxagliptin was obtained with a specific activity of 53.98 µCi/mg (17.13 mCi/mmol). The radiochemical purity determined by HPLC was 99.29%, and the overall radiochemical yield was 3.0% based upon 100 mCi of [(14)C]CH2 I2 starting material. By following similar synthetic routes, 580.0 mg of (13)CD2-labeled saxagliptin and 153.1 mg of (13)CD2-labeled 5-hydroxysaxagliptin metabolite were prepared.

The synthesis of a carbon-14 labeled pegylated Adnectin™ for placental transfer studies in guinea pigs.

Adnectins™ are novel fibronectin-based proteins containing domains engineered to bind to targets of therapeutic interest. The molecular weights of adnectins are less than conventional monoclonal antibodies but larger than traditional small molecules. Until now, there has been no information on the placental transfer of adnectins. To assess placental permeability to adnectins in pregnant guinea pigs, a radiolabeled adnectin, ATI-1072, bound to polyethylene glycol through a [(14) C]Maleimide linker, was synthesized from [1,4-(14) C]Maleic acid. This publication describes the synthesis and analysis of PEG-[(14) C]Maleimide-adnectin ([(14) C]ATI-1072).

Deuterium in drug discovery: progress, opportunities and challenges.

Substitution of a hydrogen atom with its heavy isotope deuterium entails the addition of one neutron to a molecule. Despite being a subtle change, this structural modification, known as deuteration, may improve the pharmacokinetic and/or toxicity profile of drugs, potentially translating into improvements in efficacy and safety compared with the non-deuterated counterparts. Initially, efforts to exploit this potential primarily led to the development of deuterated analogues of marketed drugs through a 'deuterium switch' approach, such as deutetrabenazine, which became the first deuterated drug to receive FDA approval in 2017. In the past few years, the focus has shifted to applying deuteration in novel drug discovery, and the FDA approved the pioneering de novo deuterated drug deucravacitinib in 2022. In this Review, we highlight key milestones in the field of deuteration in drug discovery and development, emphasizing recent and instructive medicinal chemistry programmes and discussing the opportunities and hurdles for drug developers, as well as the questions that remain to be addressed.

Tissue distribution and elimination of [14C]apixaban in rats.

Apixaban, a potent and highly selective factor Xa inhibitor, is currently under development for treatment of arterial and venous thrombotic diseases. The distribution, metabolism, and elimination of [(14)C]apixaban were investigated in male, female, pregnant, and lactating rats after single oral doses. Tissue distribution of radioactivity in rats was measured using quantitative whole-body autoradiography. After a single oral administration, radioactivity distributed quickly in rats with C(max) at 1 h for most tissues. The elimination t(1/2) of radioactivity in blood was 1.7 to 4.2 h. The blood area under the plasma concentration-time curve of radioactivity was similar between male and female rats and was slightly higher in pregnant rats and lower in lactating rats. The radioactivity concentration in tissues involved in elimination was greater than that in blood with the highest concentration in the gastrointestinal tract, liver, and urinary bladder/contents and lowest level in brains. In pregnant rats, the whole-body autoradiogram showed that low levels of radioactivity were present in fetal blood, liver, and kidney and were much lower than the radioactivity in the respective maternal organs. The fecal route was the major pathway (74% of dose), and the urinary route was the minor pathway (14%) for apixaban elimination. After single oral doses of [(14)C]apixaban to lactating rats, apixaban exhibited extensive lacteal excretion with apixaban as the major component. In summary, tissue distribution of apixaban in rats was extensive but with limited transfer to fetal and brain tissues and extensive secretion into rat milk with the parent drug as the major component. Milk excretion could account for 10% of apixaban dose, which was comparable to urinary elimination in rats. Tissue distribution and drug excretion of apixaban are consistent with those for a moderately permeable drug that is a substrate for P-glycoprotein and breast cancer resistance protein efflux transporters.

In vitro assessment of metabolic drug-drug interaction potential of apixaban through cytochrome P450 phenotyping, inhibition, and induction studies.

Apixaban is an oral, direct, and highly selective factor Xa inhibitor in late-stage clinical development for the prevention and treatment of thromboembolic diseases. The metabolic drug-drug interaction potential of apixaban was evaluated in vitro. The compound did not show cytochrome P450 inhibition (IC(50) values >20 microM) in incubations of human liver microsomes with the probe substrates of CYP1A2, 2B6, 2C8, 2C9, 2C19, 2D6, or 3A4/5. Apixaban did not show any effect at concentrations up to 20 muM on enzyme activities or mRNA levels of selected P450 enzymes (CYP1A2, 2B6, and 3A4/5) that are sensitive to induction in incubations with primary human hepatocytes. Apixaban showed a slow metabolic turnover in incubations of human liver microsomes with formation of O-demethylation (M2) and hydroxylation products (M4 and M7) as prominent in vitro metabolites. Experiments with human cDNA-expressed P450 enzymes and P450 chemical inhibitors and correlation with P450 activities in individual human liver microsomes demonstrated that the oxidative metabolism of apixaban for formation of all metabolites was predominantly catalyzed by CYP3A4/5 with a minor contribution of CYP1A2 and CYP2J2 for formation of M2. The contribution of CYP2C8, 2C9, and 2C19 to metabolism of apixaban was less significant. In addition, a human absorption, distribution, metabolism, and excretion study showed that more than half of the dose was excreted as unchanged parent (f(m CYP) <0.5), thus significantly reducing the overall metabolic drug-drug interaction potential of apixaban. Together with a low clinical efficacious concentration and multiple clearance pathways, these results demonstrate that the metabolic drug-drug interaction potential between apixaban and coadministered drugs is low.

Comparative metabolism of 14C-labeled apixaban in mice, rats, rabbits, dogs, and humans.

The metabolism and disposition of [(14)C]apixaban, a potent, reversible, and direct inhibitor of coagulation factor Xa, were investigated in mice, rats, rabbits, dogs, and humans after a single oral administration and in incubations with hepatocytes. In plasma, the parent compound was the major circulating component in mice, rats, dogs, and humans. O-Demethyl apixaban sulfate (M1) represented approximately 25% of the parent area under the time curve in human plasma. This sulfate metabolite was present, but in lower amounts relative to the parent, in plasma from mice, rats, and dogs. Rabbits showed a plasma metabolite profile distinct from that of other species with apixaban as a minor component and M2 (O-demethyl apixaban) and M14 (O-demethyl apixaban glucuronide) as prominent components. The fecal route was a major elimination pathway, accounting for >54% of the dose in animals and >46% in humans. The urinary route accounted for <15% of the dose in animals and 25 to 28% in humans. Apixaban was the major component in feces of every species and in urine of all species except rabbit. M1 and M2 were common prominent metabolites in urine and feces of all species as well as in bile of rats and humans. In vivo metabolite profiles showed quantitative differences between species and from in vitro metabolite profiles, but all human metabolites were found in animal species. After intravenous administration of [(14)C]apixaban to bile duct-cannulated rats, the significant portion (approximately 22%) of the dose was recovered as parent drug in the feces, suggesting direct excretion of the drug from gastrointestinal tracts of rats. Overall, apixaban was effectively eliminated via multiple elimination pathways in animals and humans, including oxidative metabolism, and direct renal and intestinal excretion.

Discovery of Clinical Candidate BMS-823778 as an Inhibitor of Human 11ß-Hydroxysteroid Dehydrogenase Type 1 (11ß-HSD-1).

BMS-823778 (2), a 1,2,4-triazolopyridinyl-methanol derived analog, was identified as a potent and selective inhibitor of human 11ß-hydroxysteroid dehydrogenase type 1 (11ß-HSD-1) enzyme (IC50 = 2.3 nM) with >10,000-fold selectivity over 11ß-HSD-2. Compound 2 exhibits robust acute pharmacodynamic effects in cynomolgus monkeys (ED50 = 0.6 mg/kg) and in diet-induced obese (DIO) mice (ED50 = 34 mg/kg). Compound 2 also showed excellent inhibition in an ex vivo adipose DIO mouse model (ED50 = 5.2 mg/kg). Oral bioavailability ranges from 44% to 100% in preclinical species. Its favorable development properties, pharmacokinetics, high adipose-to-plasma concentration ratio, and preclinical pharmacology profile have prompted the evaluation of 2 for the treatment of type 2 diabetes and metabolic syndrome in phase 2 clinical trials.