Investigation of Ocular Bioactivation Potential and the Role of Cytochrome P450 2D Enzymes in Rat.

BACKGROUND: Timolol is clinically administered topically (ocular) to reduce intraocular pressure and treat open-angle glaucoma. Ocular administration of timolol in low doses (0.5% w/v in the form of eye drops) has led to challenges for in vivo metabolite identification. An understanding of drug metabolism in the eye is important for clinical ocular therapeutics and potential drug candidates. METHODS: We aimed to investigate the metabolism of timolol in rat ocular and liver S9 fractions, as well as rat ocular tissue and plasma following a 0.5% topical (ocular) dose of timolol. We explored the potential in vitro metabolic bioactivation in the eye/liver by conducting trapping studies for putative aldehyde and iminium ion intermediates that may arise from the morpholine functionality. RESULTS: Oxidative metabolism of timolol to its major metabolite (M4) in ocular S9 and recombinant rat cytochrome P450 (CYP) isoforms supports the possible role of rat ocular CYP2D2, 2D4, and/or 2D18. Observation of N-acetyl-timolol (M5) is suggestive that the ocular N-acetyltransferases may also play a larger role in ocular disposition of timolol, a previously unreported finding. This research is the first comprehensive report of in vitro ocular metabolism of timolol in rat. CONCLUSION: This study also indicates that in vitro hepatic metabolism is over-predictive of ocular metabolism following topically ocular dosed timolol. The research, herein, highlights the eye as an organ capable of first pass metabolism for topical drugs. Thus, new ophthalmologic considerations for studying and designing long term topical therapies in preclinical species are needed in drug discovery.

Ocular non-P450 oxidative, reductive, hydrolytic, and conjugative drug metabolizing enzymes.

Metabolism in the eye for any species, laboratory animals or human, is gaining rapid interest as pharmaceutical scientists aim to treat a wide range of so-called incurable ocular diseases. Over a period of decades, reports of metabolic activity toward various drugs and biochemical markers have emerged in select ocular tissues of animals and humans. Ocular cytochrome P450 (P450) enzymes and transporters have been recently reviewed. However, there is a dearth of collated information on non-P450 drug metabolizing enzymes in eyes of various preclinical species and humans in health and disease. In an effort to complement ocular P450s and transporters, which have been well reviewed in the literature, this review is aimed at presenting collective information on non-P450 oxidative, hydrolytic, and conjugative ocular drug metabolizing enzymes. Herein, we also present a list of xenobiotics or drugs that have been reported to be metabolized in the eye.

Do We Need to Study Metabolism and Distribution in the Eye: Why, When, and Are We There Yet?

The liver is known to be the principal site of drug metabolism. Depending on the route of administration, especially in cases of topical and local delivery, evaluation of local drug metabolism in extrahepatic tissues is vital to assess fraction of the drug metabolized. This parameter becomes important from the point of view of drug availability or the contribution to overall clearance. Examples include fraction metabolized in the gut for oral drugs and contribution of pulmonary or renal clearance to total clearance of a drug. Diseases of the eye represent a rising unmet medical need and a number of therapeutics are currently being developed in the form of small molecules and biologics. Treatment of ocular diseases has expanded to explore various topical formulations and local short- and long-term therapies by ocular routes of administration. Until recently, metabolism in the eye for any species, including human, was not well documented, but this topic is gaining wide interest. Many in vitro-ex vivo models, each with separate pros and cons, are being used for studying ocular metabolism. This review is aimed at providing a perspective on the relevance and application of ocular metabolism, melanin binding, and the use of tissue- and cell-derived ocular models in discovery and preclinical development.

In vitro ocular metabolism and bioactivation of ketoconazole in rat, rabbit and human.

Oral ketoconazole is clinically administered for treatment of severe cases for fungal keratitis. Pharmacodynamics and efficacy of oral and topical (ocular) ketoconazole have been explored in rabbit. However, metabolism of ketoconazole in the eye in any species is not well explored in any preclinical species or human. An understanding of ocular drug metabolism in the eye is crucial for ocular therapeutics to facilitate the risk assessment and development of potential drug candidates for the clinic. We aimed to investigate the metabolism of ketoconazole in rat, rabbit and human ocular S9 fractions. Metabolism in liver S9 fractions was also studied for a direct comparison. Eleven putative metabolites were identified in the in vitro incubations. Of these metabolites, six were present in rat ocular S9 whereas eight were present in rabbit and human ocular matrices. Metabolic pathways in rabbit and human ocular fractions suggested the formation of reactive intermediates in rabbit and human liver and ocular S9 incubations, which was confirmed with trapping studies. Herein, we report eight human ocular metabolites of ketoconazole for the first time. To the best of our knowledge, this is the first report of ocular metabolic pathways and ocular bioactivation of ketoconazole in preclinical species and human.

Synthesis and Biochemical Evaluation of Biotinylated Conjugates of Largazole Analogues: Selective Class I Histone Deacetylase Inhibitors.

The synthesis of biotinylated conjugates of synthetic analogues of the potent and selective histone deacetylase (HDAC) inhibitor largazole is reported. The thiazole moiety of the parent compound's cap group was derivatized to allow the chemical conjugation to biotin. The derivatized largazole analogues were assayed across a panel of HDACs 1-9 and retained potent and selective inhibitory activity towards the class I HDAC isoforms. The biotinylated conjugate was further shown to pull down HDACs 1, 2, and 3.

Ocular Metabolism of Levobunolol: Historic and Emerging Metabolic Pathways.

Although ocular transport and delivery have been well studied, metabolism in the eye is not well documented, even for clinically available medications such as levobunolol, a potent and nonselective ß-adrenergic receptor antagonist. Recently, we reported an in vitro methodology that could be used to evaluate ocular metabolism across preclinical species and humans. The current investigation provides detailed in vitro ocular and liver metabolism of levobunolol in rat, rabbit, and human S9 fractions, including the formation of equipotent active metabolite, dihydrolevobunolol, with the help of high-resolution mass spectrometry. 11 of the 16 metabolites of levobunolol identified herein, including a direct acetyl conjugate of levobunolol observed in all ocular and liver fractions, have not been reported in the literature. The study documents the identification of six human ocular metabolites that have never been reported. The current investigation presents evidence for ocular and hepatic metabolism of levobunolol via non-cytochrome P450 pathways, which have not been comprehensively investigated to date. Our results indicated that rat liver S9 and human ocular S9 fractions formed the most metabolites. Furthermore, liver was a poor in vitro surrogate for eye, and rat and rabbit were poor surrogates for human in terms of the rate and extent of levobunolol metabolism.

An in vitro approach to investigate ocular metabolism of a topical, selective ß1-adrenergic blocking agent, betaxolol.

1. Topical glaucoma treatments have often been limited by poor absorption and bioavailability. Betaxolol, a selective ß1-blocker, has been well studied for its pharmacokinetics and disposition. Limited ocular, betaxolol metabolism data is available despite a growing number of novel ocular treatments. 2. In vitro ocular fractions indicated the formation of an active metabolite, across rat, rabbit and human, which was only observed historically in the liver. 3. Ocular metabolic profiles of preclinical toxicology species, rat and rabbit, were not predictive of human in vitro ocular data. M1 was specific to human and only captured by the liver data. 4. Liver S9 over predicted the extent of ocular metabolism compared to ocular fractions. Rabbit liver S9 fractions demonstrated extensive glucuronidation and higher parent turn-over in 1 h as compared to other matrices. 5. This research assesses in vitro species and organ differences across preclinical species and human. The complex data set highlights the need for an in vitro ocular system to explore poorly documented ocular metabolism.

Identification of saturated and unsaturated fatty acids released during microsomal incubations.

1. In vitro clearance in liver microsomes is routinely measured in drug discovery and development for new chemical entities. Literature reports indicate that long chain fatty acids such as arachidonic, linoleic and oleic acids may be released over a period of time during microsomal incubations. Some fatty acids have been shown to interfere with oxidative and conjugative reactions in microsomes, thus potentially inhibiting microsomal clearance of compounds. 2. The present study was aimed at deciphering the fatty acids present or released from microsomes. Analytical methods were developed to characterize and quantitatively assess the fatty acids without chemical derivatization in rat, monkey and human liver microsomes. Additionally, incubations with uridine-5'-diphosphoglucuronic acid (UDPGA) were utilized to trap the released fatty acids as their glucuronate esters, which were characterized and confirmed by high-resolution LC-MS/MS. 3. Our results indicate for the first time that timnodonic, trans-eicosenoic, gondoic, behenic, and nervonic acid were released during microsomal incubations. Additionally, α- and γ-linolenic, timnodonic, palmitoleic, linoleic, arachidonic, palmitic, oleic, and stearic acid were identified as their corresponding acyl-glucuronides in rat, monkey and human liver microsomes, providing the first direct evidence that the released fatty acids are capable of forming glucuronides under incubation conditions.

Metabolism of bromopride in mouse, rat, rabbit, dog, monkey, and human hepatocytes.

Bromopride (BRP) has been utilized clinically for treatment of nausea, vomiting and gastro-intestinal motility disorders. The pharmacokinetics of BRP have been characterized in dogs and humans; however, the metabolic profile of BRP has not been well studied. The present study was aimed at better understanding BRP metabolism across species. We investigated biotransformation of BRP in mouse, rat, rabbit, dog, monkey, and human hepatocytes with the help of LC-MS(n) and accurate mass measurement. Mice, rats, dogs, and monkeys are relevant in drug discovery and development as pre-clinical species to be compared with humans, whereas rabbits were efficacy models for BRP. Overall, twenty metabolites of BRP were identified across hepatocytes from the six species. Monkeys offered the most coverage for humans, in terms of number of metabolites identified. Interestingly, M14, an N-sulfate metabolite of BRP, was identified as a human-specific metabolite. BRP metabolism had only been reported in dog plasma and urine, historically. Our investigation is the first documentation of in vitro metabolism of BRP in the six species reported here. Metabolites M1, M2, M4-M10, M12, M13, and M15-M20 have not been previously reported. In summary, this report documents seventeen metabolites of BRP for the first time, thus providing a deeper insight into the biotransformation of BRP.