Laykea Tafesse

Pharmacological and pharmacokinetic characterization of the cannabinoid receptor 2 agonist, GW405833, utilizing rodent models of acute and chronic pain, anxiety, ataxia and catalepsy

To date, two cannabinoid receptors have been identified, CB1 and CB2. Activation of these receptors with non-selective cannabinoid receptor agonists reduces pain sensitivity in animals and humans. However, activation of CB1 receptors is also associated with central side effects, including ataxia and catalepsy. More recently, a role for selective CB2 agonists in pain modification has been demonstrated. GW405833, a selective CB2 agonist, was recently reported to partially reverse the inflammation and hyperalgesia in a rat model of acute inflammation. In the current report, we extend the characterization and therapeutic potential of this compound. For the first time, we show that GW405833 selectively binds both rat and human CB2 receptors with high affinity, where it acts as a partial agonist (approximately 50% reduction of forskolin-mediated cAMP production compared to the full cannabinoid agonist, CP55,940). We also report for the first time that intraperitoneal administration of GW405833 (0.3-100 mg/kg) to rats shows linear, dose-dependent increases in plasma levels and substantial penetration into the central nervous system. In addition, GW405833 (up to 30 mg/kg) elicits potent and efficacious antihyperalgesic effects in rodent models of neuropathic, incisional and chronic inflammatory pain, the first description of this compound in these models. In contrast, analgesia, sedation and catalepsy were not observed in this dose range, but were apparent at 100 mg/kg. Additionally, GW405833 was not antihyperalgesic against chronic inflammatory pain in CB2 knockout mice. These data support the tenet that selective CB2 receptor agonists have the potential to treat pain without eliciting the centrally-mediated side effects associated with non-selective cannabinoid agonists, and highlight the utility of GW405833 for the investigation of CB2 physiology.

4-(2-pyridyl)piperazine-1-carboxamides: potent vanilloid receptor 1 antagonists.

A series of 4-(2-pyridyl)piperazine-1-carboxamide analogues based on the lead compound 1 was synthesized and evaluated for VR1 antagonist activity in capsaicin-induced (CAP) and pH (5.5)-induced (pH) FLIPR assays in a rat VR1-expressing HEK293 cell line. Potent VR1 antagonists were identified through SAR studies. From these studies, 18 was found to be very potent in the in vitro assay [IC(50)=4.8 nM (pH) and 35 nM (CAP)] and orally available in rat (F%=15.1).

TRPV1 antagonists: a survey of the patent literature

The recent cloning of vanilloid receptor 1 (TRPV1) from multiple species, together with published results showing efficacy of TRPV1 antagonists in animal models of pain, has led to substantial patenting activity by several major pharmaceutical companies and academic institutions. This review is focused on the patent literature related to non-peptidic small molecule TRPV1 antagonists. A total of 105 published patent applications claiming TRPV1 antagonists are reviewed during 2002 – 2005. Human clinical trials using TRPV1 antagonists are in the earliest stages and interest in this approach toward the treatment of various pain conditions appears to be growing annually.

Structure-activity relationship studies and discovery of a potent transient receptor potential vanilloid (TRPV1) antagonist 4-[3-chloro-5-[(1S)-1,2-dihydroxyethyl]-2-pyridyl]-N-[5-(trifluoromethyl)-2-pyridyl]-3,6-dihydro-2H-pyridine-1-carboxamide (V116517) as a clinical candidate for pain management.

A series of novel tetrahydropyridinecarboxamide TRPV1 antagonists were prepared and evaluated in an effort to optimize properties of previously described lead compounds from piperazinecarboxamide series. The compounds were evaluated for their ability to block capsaicin and acid-induced calcium influx in CHO cells expressing human TRPV1. The most potent of these TRPV1 antagonists were further characterized in pharmacokinetic, efficacy, and body temperature studies. On the basis of its pharmacokinetic, in vivo efficacy, safety, and toxicological properties, compound 37 was selected for further evaluation in human clinical trials.

An efficient parallel synthesis of capsazepine and capsazepine analogs.

Capsazepine (CPZ, 1) is a well-known vanilloid receptor (VR1) antagonist that has been cited widely used in the literature. However the current synthetic methods used for the total synthesis of CPZ are lengthy, involve multiple purification steps, and produce low yields. Here we describe a new and highly efficient synthesis of benzazepine 3, a synthetic precursor of CPZ, in only two steps and 59% overall yield from a commercially available tetralone 2 via a Schmidt reaction as a key step. Moreover, we apply parallel synthesis techniques to prepare CPZ and CPZ analogs. Our approach enables the possibility of preparing larger, and more diverse libraries of CPZ analogs.

N-Aryl azacycles as novel sodium channel blockers

We have identified a new series of N-aryl azacycles as sodium channel blockers, which showed good potency on Nav1.7 in FLIPR-based and electrophysiological functional assays. Analogs from this series possessed selectivity over hERG, reasonable oral exposure in rat PK studies and are predicted to have limited CNS penetration.

Parallel Synthesis of a Biased Library of Thiazolidinones as Novel Sodium Channel Antagonists

A biased chemical library containing 91 differentially substituted thiazolidinones was prepared in an effort to improve the pharmacology of a known anticonvulsant agent V102862. The collection was prepared in a single step multi-component condensation reaction that produced good yields and very high crude purity (75%-85%). Seven compounds, identified within the library were shown to be more potent than V102862, our parent reference compound, in an electrophysiological assay measuring sodium channel antagonism. The most potent compound, 3-(2-piperidinylethyl)-2-(3-(3-trifluoromethylphenoxy)phenyl)thiazolidinone, has a Ki of 90 nM.