The influence of esters and carboxylic acids as the N-substituent of opioids. Part 1: Benzomorphans.

To investigate the effects of carboxylic ester and acid moieties as the N-substituent of opioids, a short series of racemic N-substituted normetazocines was prepared. The introduction of both groups as the normetazocine N-substituent produced compounds which displayed low potency in vitro and in vivo, with the esters displaying the greater activity. The pharmacology of the compounds is discussed with implications resulting from potential in vivo metabolic hydrolysis.

Probes for narcotic receptor mediated phenomena. 34. Synthesis and structure-activity relationships of a potent mu-agonist delta-antagonist and an exceedingly potent antinociceptive in the enantiomeric C9-substituted 5-(3-hydroxyphenyl)-N-phenylethylmorphan series.

Both of the enantiomers of 5-(3-hydroxyphenyl)-N-phenylethylmorphan with C9alpha-methyl, C9-methylene, C9-keto, and C9alpha- and C9beta-hydroxy substituents were synthesized and pharmacologically evaluated. Three of the 10 compounds, (1R,5R,9S)-(-)-9-hydroxy-5-(3-hydroxyphenyl-2-phenylethyl-2-azabicyclo[3.3.1]nonane ((1R,5R,9S)-(-)-10), (1R,5S)-(+)-5-(3-hydroxyphenyl)-9-methylene-2-phenethyl-2-azabicyclo[3.3.1]nonane ((1R,5S)-(+)-14), and (1R,5S,9R)-(-)-5-(3-hydroxyphenyl)-9-methyl-2-phenethyl-2-azabicyclo[3.3.1]nonane ((1R,5S,9R)-(+)-15) had subnanomolar affinity at mu-opioid receptors (Ki = 0.19, 0.19, and 0.63 nM, respectively). The (1R,5S)-(+)-14 was found to be a mu-opioid agonist and a mu-, delta-, and kappa-antagonist in [35S]GTP-gamma-S assays and was approximately 50 times more potent than morphine in a number of acute and subchronic pain assays, including thermal and visceral models of nociception. The (1R,5R,9S)-(-)-10 compound with a C9-hydroxy substituent axially oriented to the piperidine ring (C9beta-hydroxy) was a mu-agonist about 500 times more potent than morphine. In the single-dose suppression assay, it was greater than 1000 times more potent than morphine. It is the most potent known phenylmorphan antinociceptive. The molecular structures of these compounds were energy minimized with density functional theory at the B3LYP/6-31G* level and then overlaid onto (1R,5R,9S)-(-)-10 using the heavy atoms in the morphan moiety as a common docking point. Based on modeling, the spatial arrangement of the protonated nitrogen atom and the 9beta-OH substituent in (1R,5R,9S)-(-)-10 may facilitate the alignment of a putative water chain enabling proton transfer to a nearby proton acceptor group in the mu-opioid receptor.

Pharmacological studies with a nonpeptidic, delta-opioid (-)-(1R,5R,9R)-5,9-dimethyl-2'-hydroxy-2-(6-hydroxyhexyl)-6,7-benzomorphan hydrochloride ((-)-NIH 11082).

In the search for a selective delta-opioid receptor agonist, (-)-(1R,5R,9R)-5,9-dimethyl-2'-hydroxy-2-(6-hydroxyhexyl)-6,7-benzomorphan hydrochloride ((-)-NIH 11082) and the (+)-enantiomer were synthesized and tested. (-)-NIH 11082 displayed antinociceptive activity in the paraphenylquinone test (PPQ test) in male ICR mice [ED50=1.9 (0.7-5.3) mg/kg, s.c.] and showed little, if any, activity in the tail-flick and hot-plate assays. The (+)-enantiomer was essentially inactive indicating stereoselectivity. Opioid receptor subtype characterization studies indicated that naltrindole, a delta-opioid receptor antagonist, was potent versus the ED80 of (-)-NIH 11082 in the PPQ test [AD50=0.75 (0.26-2.20) mg/kg, s.c]. beta-Funaltrexamine and nor-binaltorphimine, selective mu- and kappa-receptor antagonists, respectively, were inactive versus the ED80 of (-)-NIH 11082. In rats with inflammation-induced pain, (-)-NIH 11082 produced antihyperalgesic effects that were attenuated by naltrindole. In morphine-dependent rhesus monkeys of both sexes, (-)-NIH 11082 neither substituted for morphine nor exacerbated withdrawal signs in the dose range of 4.0 to 32.0 mg/kg, s.c. Neither convulsions nor other overt behavioral signs were observed in any of the species tested. The results indicate that (-)-NIH 11082 has delta-opioid receptor properties.

Opioid ligands with mixed properties from substituted enantiomeric N-phenethyl-5-phenylmorphans. Synthesis of a micro-agonist delta-antagonist and delta-inverse agonists.

Enantiomeric N-phenethyl-m-hydroxyphenylmorphans with various substituents in the ortho, meta or para positions of the aromatic ring in the phenethylamine side-chain (chloro, hydroxy, methoxy, nitro, methyl), as well as a pyridylethyl and a indolylethyl moiety on the nitrogen atom, were synthesized and their binding affinity to the mu-, delta-, and kappa-opioid receptors was examined. The higher affinity ligands were further examined in the [(35)S]GTPgammaS assay to study their function and efficacy. 3-((1R,5S)-(-)-2-(4-Nitrophenethyl)-2-aza-bicyclo[3.3.1]nonan-5-yl)phenol ((-)-) was found to be a mu-agonist and delta-antagonist in that functional assay and was about 50 fold more potent than morphine in vivo. 3-((1R,5S)-(-)-2-(4-Chlorophenethyl)-2-aza-bicyclo[3.3.1]nonan-5-yl)phenol ((-)-) and several other ligands displayed inverse agonist activity at the delta-opioid receptor. The absolute configuration of all of the reported compounds was established by chemical conversion of (-)- to 1R,5S-(-)-.HBr.

Activation of G-proteins by morphine and codeine congeners: insights to the relevance of O- and N-demethylated metabolites at mu- and delta-opioid receptors.

Phenotypic differences in analgesic sensitivity to codeine (3-methoxymorphine) results from polymorphisms in cytochrome P450-2D6, which catalyzes O-demethylation of codeine to morphine. However, O-demethylation reportedly is not required for analgesic activity of the 7,8-saturated codeine congeners dihydrocodeine, hydrocodone, and oxycodone. This study determined the potency and efficacy of these compounds and their demethylated derivatives to stimulate mu- and delta-opioid receptor-mediated G-protein activation using agonist-stimulated guanosine 5'-O-(3-[(35)S]thio)triphosphate ([(35)S]GTP gamma S) binding. Results showed that 7,8-saturated codeine congeners were more efficacious than codeine in activating mu-receptors, but only dihydrocodeine was more efficacious at delta-receptors. Hydrocodone and oxycodone were approximately 10-fold more potent than codeine and dihydrocodeine at either receptor. Morphine-like compounds with a 3-hydroxy group were approximately 30- to 100-fold more potent than their 3-methoxy analogs at the mu-receptor, and these compounds generally exhibited greater efficacy (e.g., morphine produced 2-fold greater maximal stimulation than codeine). Removal of the N-methyl group did not affect efficacy or potency of codeine congeners to activate mu-receptors, whereas this modification generally increased efficacy but decreased potency of morphine congeners. At the delta receptor, morphine congeners showed greater potency and structure-dependent differences in efficacy compared with codeine congeners, whereas removal of the N-methyl group had effects similar to those observed at the mu-receptor. These results demonstrate that 7,8-saturated codeine congeners are more efficacious than codeine, which may explain their lack of requirement for 3-O-demethylation in vivo. Nonetheless, because all 7,8-saturated codeine congeners were significantly less potent than their morphine derivatives, further research is needed to understand the relationship between metabolism and in vivo activity of these compounds.

N-(trifluoromethyl)benzyl substituted N-normetazocines and N-norketobemidones.

To further investigate the unusual profile of N-benzyl substituted opioids, N-trifluoromethylbenzyl normetazocines and norketobemidones were prepared. The introduction of trifluoromethyl substituents on the benzyl group of the (-)-metazocines reduced affinity at all three receptors, with the greatest loss at kappa receptors. Surprisingly, some of the (+)-normetazocines actually possessed higher affinity than the corresponding (-)-isomers. In the ketobemidone series, the effects were different-the 4-trifluoromethyl substituted ketobemidone actually possessed 3-fold higher mu affinity than the unsubstituted parent to give a ligand with good mu affinity. In functional in vitro assays, this compound was a weak antagonists, but in apparent contradiction it was inactive in in vivo assays.

Heroin discriminative stimulus effects of methadone, LAAM and other isomers of acetylmethadol in rats.

RATIONALE: LAAM (alpha- l-acetylmethadol) is a derivative of the synthetic mu-opiate agonist methadone and is one of the four isomers of acetylmethadol. Methadone and LAAM have similar pharmacological properties and both are approved medications for the treatment of heroin dependency disorders. Few studies have reported on the pharmacology of acetylmethadol's other isomers and most of these have focused on their potential analgesic activity. OBJECTIVES: The purpose of the present investigation was to examine the discriminative stimulus effects of LAAM, the other isomers of acetylmethadol, and methadone in rats trained to discriminate heroin from water, and to compare the duration of the discriminative stimulus effects of heroin, methadone, and LAAM. METHODS: Long-Evans rats were trained to discriminate 0.3 mg/kg heroin from water under a fixed ratio 10 (FR10) schedule of food reinforcement. Dose-response functions for heroin, methadone, LAAM, three other isomers of acetylmethadol: alpha- d-acetylmethadol, beta- d-acetylmethadol, beta- l-acetylmethadol, and its precursor, beta- l-methadol were examined. Additionally, the time course effects for heroin, methadone, and LAAM were examined. RESULTS: LAAM and methadone dose-dependently occasioned heroin-like discriminative stimulus effects. Two of acetylmethadol's isomers, alpha- d-acetylmethadol and beta- d-acetylmethadol, were more potent than LAAM in producing heroin-like effects. The beta- l-methadol precursor and beta- l-acetylmethadol did not fully substitute for heroin's discriminative stimulus. LAAM elicited heroin-like discriminative stimulus effects for at least 6 h and generated partial generalization up to 36 h following administration. CONCLUSIONS: Methadone, LAAM, beta- d-acetylmethadol and alpha- d-acetylmethadol, but not beta- l-acetylmethadol and beta- l-methadol evoke heroin-like discriminative stimulus effects.