The novel, orally active, delta opioid RWJ-394674 is biotransformed to the potent mu opioid RWJ-413216.

Although the mu opioid receptor is the primary target of marketed opioid analgesics, several studies suggest the advantageous effect of combinations of mu and delta opioids. The novel compound RWJ-394674 [N,N-diethyl-4-[(8-phenethyl-8-azabicyclo]3.2.1]oct-3-ylidene)-phenylmethyl]-benzamide]; bound with high affinity to the delta opioid receptor (0.2 nM) and with weaker affinity to the mu opioid receptor (72 nM). 5'-O-(3-[(35)S]-thio)triphosphate binding assay demonstrated its delta agonist function. Surprisingly given this pharmacologic profile, RWJ-394674 exhibited potent oral antinociception (ED(50) = 10.5 micromol/kg or 5 mg/kg) in the mouse hot-plate (48 degrees C) test and produced a moderate Straub tail. Antagonist studies in the more stringent 55 degrees C hot-plate test demonstrated the antinociception produced by RWJ-394674 to be sensitive to the nonselective opioid antagonist naloxone as well as to the delta- and mu-selective antagonists, naltrindole and beta-funaltrexamine, respectively. In vitro studies demonstrated that RWJ-394674 was metabolized by hepatic microsomes to its N-desethyl analog, RWJ-413216 [N-ethyl-4-[(8-phenethyl-8-azabicyclo[3.2.1]oct-3-ylidene)-phenylmethyl]-benzamide], which, in contrast to RWJ-394674, had a high affinity for the mu rather than the delta opioid receptor and was an agonist at both. Pharmacokinetic studies in the rat revealed that oral administration of RWJ-394674 rapidly gave rise to detectable plasma levels of RWJ-413216, which reached levels equivalent to those of RWJ-394674 by 1 h. RWJ-413216 itself demonstrated a potent oral antinociceptive effect. Thus, RWJ-394674 is a delta opioid receptor agonist that appears to augment its antinociceptive effect through biotransformation to a novel mu opioid receptor-selective agonist.

In vitro metabolism of the analgesic agent, RWJ-37874, in rat and human.

RWJ-37874, an analogue of aroyl(aminoacyl)pyrrole, is a new analgesic agent. The in vitro metabolism of RWJ-37874 was conducted using rat and human hepatic S9 in the presence of an NADPH generating system, and API-ionspray-MS and MS/MS techniques for metabolite profiling and identification. Unchanged RWJ-37874 (66 & 86% of the sample in rat & human, respectively) plus four metabolites were profiled and tentatively identified on the basis of MS data. RWJ-37874 metabolites were formed via the following two metabolic pathways: 1. oxidative N-deethylation, and 2. pyrrole-oxidation. Pathway 1 produced a mayor and a minor metabolites, N-desethyl-RWJ-37874 (M1; 34% in rat; 13% in human) and N,N-didesethyl-RWJ-37874 (M3; <0.5% in both species), respectively. Pathway 2 formed hydroxypyrrole-RWJ-37874 (M2; <0.5% in all species), and in conjunction with step 1, formed hydroxy-M1 (M4; <0.5% in rat). RWJ-37874 is substantially metabolized in rat and human hepatic S9 fractions. However, rat appears to metabolize RWJ-37874 more extensively than human via N-dealkylation forming N-desethyl-RWJ-37874 as a major metabolite.

In vitro biotransformation of the analgesic agent, RWJ-51784, in rat, dog and human.

RWJ-51784, an analogue of phenyl isoindoles, is a new analgesic agent. The in vitro metabolism of RWJ-51784 was conducted using rat, dog and human hepatic S9 in the presence of an NADPH generating system, and API-ionspray-MS and MS/MS techniques for the metabolite profiling and identification. Unchanged RWJ-51784 (82, 80 & 86% of the sample in rat, dog & human, respectively) plus 6 metabolites were profiled and tentatively identified on the basis of MS data. RWJ-51784 metabolites were formed via the following 3 metabolic pathways: 1. N-demethylation, 2. phenylhydroxylation, and 3. isoindole-oxidation. Pathway 1 produced a moderate or minor metabolite, N-desmethyl-RWJ-51784 (M1; 6% in rat; 5% in dog, 2% in human). Pathway 2 formed 4-hydroxyphenyl-RWJ-51784 (M2; 3-6% in all species). Step 3 formed 2 isoindole-oxidized metaboliotes, OH-indole (M3; 7-8% in all species) and oxo-indole (M4; <1% in all species)-RWJ-51784, and in conjunction with pathway 2 produced 2 trace metabolites, OH-phenyl-OH-isoindole (M5) and OH-phenyl-oxo-isoindole (M6) metabolites. RWJ-51784 is not extensively metabolized in rat, dog and human hepatic S9 fractions.

Synthesis and evaluation of 4-(N,N-diarylamino)piperidines with high selectivity to the delta-opioid receptor: a combined 3D-QSAR and ligand docking study.

A series of 4-(N,N-diarylamino)piperidines are synthesized and evaluated for high affinity binding and selectivity to the delta-opioid receptor using a combination of 3D-QSAR and molecular docking techniques. Based on experimental ligand binding data to both mu- and delta- opioid receptors, CoMFA fields are generated and applied to identify potential ligand modifications to further optimize lead compounds. Molecular docking experiments to the delta-receptor are also reported that explain the CoMFA trends predicted as well as the differential binding and selectivity displayed by various compounds in the series. An analysis of the binding site model proposed indicates the piperidines take advantage of 3 key sites or binding domains within the delta-receptor. These include an aromatic pocket (approximately 1/3 into the receptor cavity), an aspartic acid residue (which serves as a docking point for the piperidinyl cationic amine) and a hydrophobic pocket at the extracellular boundary of the receptor cavity. Links are established between ligand modification and amino acid composition at these sites in mu and delta, providing new insight to the structural basis to binding and selectivity across the series and for related piperazines (i.e. SNC80 and BW373U86). Results are also presented that indicate delta- and mu-selectivity may be determined at alternate sites, suggesting opioid receptors may display multiple binding domains. The model is further supported by comparisons with opiate binding modes and site directed mutagenesis studies and is finally applied to suggest new strategies in ligand design.

Synthesis and binding affinities of 4-diarylaminotropanes, a new class of delta opioid agonists.

A series of 4-diarylaminotropanes has been prepared. Both endo and exo diastereomeric forms bound to the delta opioid receptor but the endo isomers were more potent and selective versus the mu opioid receptor than the exo isomers. The most potent delta opioid agonist (14) exhibited a delta opioid Ki of 0.2 nM and was 860-fold selective over mu.

Excretion and metabolism of the antihypertensive agent, RWJ-26240 (McN-5691) in dogs.

The excretion and metabolism of a 2-ethynylbenzenealkanamine analog, antihypertensive RWJ-26240 (McN-5691), in beagle dogs was investigated. Recoveries of total radioactivity in urine and feces in the 7 days after oral administration of 14C-RWJ-26240 (6 mg/kg dose) were 2.8% and 96.8% of the radioactive dose, respectively. Representative plasma, urine, and fecal samples were pooled and purified for metabolite profiling, isolation, and identification. Unchanged RWJ-26240 (<19% of the dose) plus 12 metabolites were isolated and identified from these samples using chromatography (TLC, HPLC), spectroscopy (NMR, MS), and derivatization techniques. Unchanged RWJ-26240 plus identified metabolites accounted for >75% of the sample radioactivity in plasma and feces. The formation of RWJ-26240 metabolites can be depicted by the following proposed pathways: 1) N-demethylation, 2) O-demethylation, 3) phenyl hydroxylation, and 4) N-dealkylation. The first three pathways appeared to be quantitatively important steps which led to the production of four major metabolites (each >5% of the sample radioactivity). RWJ-26240 was extensively metabolized in the dog, and fecal excretion was the major route of elimination of RWJ-26240 and its metabolites.

Aroyl(aminoacyl)pyrroles, a new class of anticonvulsant agents.

2-Aroyl-4-(omega-aminoacyl)- (4) and 4-aroyl-2-(omega-aminoacyl)pyrroles (9) represent a new, structurally novel class of anticonvulsant agents. Compounds of type 4 were prepared by Friedel-Crafts acylation of a 2-aroylpyrrole with an omega-chloroacyl chloride followed by displacement of the chloro group by a primary or secondary amine. Compounds of type 9 were prepared by Friedel-Crafts aroylation of a 2-(omega-chloroacyl)pyrrole followed by displacement by an amine. These compounds were active in the mouse and rat maximal electroshock tests but not in the mouse metrazole test. The lead compound, RWJ-37868, 2-(4-chlorobenzoyl)-4-(1-piperidinyl-acetyl)-1,3,5-trimethylpyrrole++ + (4d), showed potency and therapeutic index comparable to those of phenytoin and carbamazepine and greater than those of sodium valproate. This compound blocked bicuculline induced seizures, did not elevate seizure threshold following iv infusion of metrazole, and blocked influx of Ca2+ ions into cerebellar granule cells induced by K+ or veratridine.

2-Substituted 1-azabicycloalkanes, a new class of non-opiate antinociceptive agents.

2-Substituted 1-azabicycloalkanes (3- and 5-aryloctahydroindolizines 2 and 11, 3-cyclohexyloctahydroindolizine 12, 4-aryloctahydroquinolizines 13, and 3-arylhexahydropyrrolizines 14) constitute a new class of non-opiate antinociceptive agents. These compounds demonstrated activity in the mouse abdominal constriction test and many were active in the mouse tail-flick test. trans-3-(2-Bromophenyl)octahydroindolizine (2a) did not bind to the opiate receptor nor did it affect arachidonate metabolism. 3-Aryloctahydroindolizines were prepared by catalytic hydrogenation of 1-aryl-3-(2-pyridinyl)-2-propen-1-ones. The X-ray crystal structure of (-)-2a was determined and absolute stereochemistry assigned as 3-R,8a-R.

Structurally novel antihypertensive compound, McN-5691, is a calcium channel blocker in vascular smooth muscle.

These studies were conducted to gain greater understanding of the mechanism of action of the chemically novel antihypertensive agent, McN-5691. McN-5691 (1 and 10 microM) prevented 60 mM KCl-induced contraction and calcium uptake and caused concentration-dependent relaxation (EC50 = 190 microM) of 30 mM KCl-contracted aortic rings. At or below 10 microM, McN-5691 had no effects on basal tone or calcium uptake (45Ca) in isolated rings of rabbit thoracic aorta. McN-5691 caused complete high affinity inhibition (Kd = 39.5 nM) of specific diltiazem binding to the benzothiazepine receptor on the voltage-sensitive calcium channel in skeletal muscle microsomal membranes. In contrast to diltiazem, McN-5691 inhibited specific dihydropyridine receptor binding, but the effect was biphasic with high (Kd = 4.7 nM) and low (Kd = 919.8 nM) affinity components. These findings suggest that McN-5691 is a voltage-sensitive calcium channel blocker. Unlike other calcium channel blockers, McN-5691 inhibited norepinephrine (NE)-induced contraction (10 microM) and calcium uptake (1 and 10 microM) and caused concentration-dependent relaxation (EC50 = 159 microM) of 1 microM NE-contracted rings of rabbit thoracic aorta. The vascular relaxant effects of McN-5691 were not related to increased calcium (45Ca) efflux from vascular smooth muscle cells. The effects of McN-5691 on NE-induced contraction were unrelated to intracellular mechanisms because McN-5691 did not affect NE-induced contraction in the absence of extracellular calcium. McN-5691 had weak activity in rat cerebral cortical membrane alpha-1 or alpha-2 adrenergic receptor binding assays. McN-5691-induced vasodilation of phenylephrine-contracted rat aortic strips was not reversible by high potassium, indicating that McN-5691 does not induce relaxation of blood vessels through potassium channel activation. In summary, these studies suggest that the primary vasodilator mechanism of McN-5691 is calcium channel blockade through competitive binding at the diltiazem site on the voltage sensitive calcium channel. McN-5691 may possess an additional vasodilator mechanism of action distinct from alpha adrenergic receptor blockade but involving a cell membrane-related event apparently leading to attenuation of receptor-operated calcium channel activity.

Antinociceptive action of McN-5195 in rodents: a structurally novel (indolizine) analgesic with a nonopioid mechanism of action.

McN-5195 [(+/-)-trans-3-(2-bromophenyl)-octahydroindolizine] inhibited at nontoxic doses the nociceptive response in tail-pinch, tail-flick and 48 degrees C hot-plate tests of mice, with ED50 values of 38.2, 33.9 and 30.9 mg/kg i.p., respectively, and of rats, with ED50 values (i.p.) of 33.2 mg/kg (tail-flick) and 33.3 mg/kg (hot-plate). The compound was p.o. active in the acetylcholine-induced irritant test (ED50 = 20.1 mg/kg) in mice and the air-induced irritant test (ED50 = 33.2 mg/kg) in rats. McN-5195 blocked thalamic activity (multiunit recordings from the ventral posterolateral nucleus) evoked by noxious stimulation of the contralateral hindlimb of anesthetized rats, but did not alter thalamic activity during non-noxious stimulation. The antinociceptive action of McN-5195 was not blocked by naloxone and was not diminished in morphine-tolerant animals. McN-5195 did not affect arachidonate metabolism and was not active against carrageenan-induced paw edema or in an adjuvant arthritis test in rats. McN-5195 did not bind to opiate, serotonin S1 or S2, dopamine D2, alpha-1, alpha-2, beta adrenergic or gamma-aminobutyric acid-A receptors and did not inhibit the synaptic uptake of norepinephrine, serotonin, dopamine or gamma-aminobutyric acid. McN-5195-induced antinociception was not affected by reserpine or phentolamine pretreatment and was not reduced in clonidine-tolerant animals. Ketanserin and yohimbine inhibited McN-5195-induced antinociception by an indirect mechanism. Tolerance did not develop to chronic administration of McN-5195 (120 mg/kg 3 times per day for 10 days). We conclude that McN-5195 is a structurally novel (indolizine) antinociceptive agent that produces its analgesic action via a nonopioid mechanism, not involving products of arachidonate metabolism.