Heteroatom analogues of hydrocodone: synthesis and biological activity.

Heteroatom analogues of hydrocodone, in which the N-methyl functionality was replaced with oxygen, sulfur, sulfoxide, and sulfone, were prepared by a short sequence from the ethylene glycol ketal of hydrocodone; a carbocyclic analogue of bisnorhydrocodone was also prepared. The compounds were tested for receptor binding and revealed moderate levels of activity for the sulfone analogue of hydrocodone.

Enantioselective synthesis of (-)-dihydrocodeinone: a short formal synthesis of (-)-morphine.

[reaction: see text] The radical cyclization approach to the morphine alkaloids has been applied in an asymmetric synthesis of (-)-dihydrocodeinone. A chiral cyclohexenol (R-32), from the CBS reduction of the enone, is the source of chirality. The first key step, tandem closure in which stereochemistry is controlled by geometric constraints, (-)-15b --> (+)-16, was followed by an unprecedented reductive hydroamination, completing the synthesis of (-)-dihydroisocodeine ((-)-17) in 13 steps from commercially available materials.

Nitrocinnamoyl and chlorocinnamoyl derivatives of dihydrocodeinone: in vivo and in vitro characterization of mu-selective agonist and antagonist activity.

Two 14beta-p-nitrocinnamoyl derivatives of dihydrocodeinone, 14beta-(p-nitrocinnamoylamino)-7,8-dihydrocodeinone (CACO) and N-cyclopropylmethylnor-14beta-(p-nitrocinnamoylamino)- 7, 8-dihydrocodeinone (N-CPM-CACO), and the corresponding chlorocinnamoylamino analogs, 14beta-(p-chlorocinnamoylamino)-7, 8-dihydrocodeinone (CAM) and N-cyclopropylmethylnor-14beta-(p-chlorocinnamoylamino) -7, 8-dihydrocodeinone (MC-CAM), were tested in opioid receptor binding assays and the mouse tail-flick test to characterize the opioid affinity, selectivity, and antinociceptive properties of these compounds. In competition binding assays, all four compounds bound to the mu opioid receptor with high affinity. When bovine striatal membranes were incubated with any of the four dihydrocodeinones, binding to the mu receptor was inhibited in a concentration-dependent, wash-resistant manner. Saturation binding experiments demonstrated that the wash-resistant inhibition of mu binding was due to a decrease in the Bmax value for the binding of the mu-selective peptide [3H][D-Ala2, MePhe4,Gly(ol)5] enkephalin and not a change in the Kd value, suggesting an irreversible interaction of the compounds with the mu receptor. In the mouse 55 degrees C warm water tail-flick test, both CACO and N-CPM-CACO acted as short-term mu-selective agonists when administered by i. c.v. injection, whereas CAM and MC-CAM produced no measurable antinociception at doses up to 30 nmol. Pretreatment of mice for 24 h with any of the four dihydrocodeinone derivatives produced a dose-dependent antagonism of antinociception mediated by the mu but not the delta or kappa receptors. Long-term antagonism of morphine-induced antinociception lasted for at least 48 h after i.c. v. administration. Finally, shifts in the morphine dose-response lines after 24-h pretreatment with the four dihydrocodeinone compounds suggest that the nitrocinnamoylamino derivatives may produce a greater magnitude long-term antagonism of morphine-induced antinociception than the chlorocinnamoylamino analogs.

Analgesic narcotic antagonists. 8. 7 alpha-Alkyl-4,5 alpha-epoxymorphinan-6-ones.

The preparation of a series of 7 alpha-alkylated dihydrocodeinones is described. N-(Cyclopropylmethyl) (P series) or N-(cyclobutylmethyl) (B series) 7 alpha-methyl (a series) or 7 alpha, 8 beta-dimethyl (b series) substituted dihydronorcodeinones (7) were prepared from the appropriately substituted N-(cycloalkylmethyl)-4-hydroxymorphinan-6-ones (5) by dibromination, 4,5-epoxy ring closure, and catalytic debromination. Treatment of 7 with BBr3 gave low yields of the corresponding 3-phenols 8. Alternatively, reaction of dihydrocodeinone (10) with dimethylformamide dimethyl acetal gave the 7-[(dimethylamino)methylene] adduct 11, which was hydrogenated to 7 alpha-methyl- (12) or 7 alpha-(hydroxymethyl)dihydrocodeinone (13). Treatment of 11 with lithium reagents, followed by hydrogenation, gave a mixture of 7 alpha-alkyl (15c-f) compounds and the corresponding 4,5-epoxy-cleaved products 16. Reaction of 11 with alpha-ethoxyvinyllithium gave intermediate 17, which on hydrolysis and hydrogenation yielded the 6,7-furyl (18) or pyrroyl (19) derivative. N-(Cycloalkylmethyl)-14-hydroxydihydronorcodeinones 23P,B reacted with dimethylformamide dimethyl acetal to give 25P,B, which were hydrogenated to the 7 alpha-methyl compounds 26P,B and O-demethylated to give 27P,B. The 7 alpha-methyl-N-methyl compounds were about equipotent with dihydrocodeinone. Derivatives with larger alkyl groups were less potent. Corresponding N-(cycloalkylmethyl) compounds did not show strong mixed agonist-narcotic antagonist activity.

Analgesic narcotic antagonists. 6. 7 beta, 8 beta-Methano- and 7 beta, 8 beta-epoxydihydrocodeinone.

Reaction of codeinone (2) with CH2N2 in the presence of Pd(OAc)2 yielded mixtures of starting material and (2) and 7 beta, 8 beta-methanodihydrocodeinone (3). Initial resolution of this mixture was achieved via carbonyl reduction followed by chromatography to give pure 7 beta, 8 beta-methanodihydrocodeine (4), which was oxidized to 3. Reaction of the mixture containing 2 and 3 with mercaptoethanol and NaOH [2 leads to 8 beta-[(hydroxyethyl)thio]dihydrocodeinone (5)] allowed selective crystallization of 3. The beta configuration of the cyclopropane ring in 3 was established by cleavage with aqueous HCl to give the 8 beta-(chloromethyl) compound 6, followed by carbonyl reduction and dehalogenation to 8 beta-methyldihydrocodeine (8). Reaction of the N-(cycloalkylmethyl) derivatives (13 and 18) of 2 with CH2N2/Pd(OA)2 gave potential mixed agonist-antagonists and 14 and 19, which were purified by reduction-oxidation (14) or mercaptoethanol-base treatment (19). Compound 2, on oxidation with alkaline peroxide, gave the previously reported 7 beta, 8 beta-epoxydihydrocodeinone (22) as the hemimethanol ketal (21). Compound 3 was about ninefold more potent an agonist than dihydrocodeine, and the N-(cyclopropylmethyl)-7 beta, 8 beta-methano compound 19 had moderately potent mixed agonist-narcotic antagonist properties.

Analgesic narcotic antagonists. 1. 8 beta-Alkyl-, 8 beta-acyl-, and 8 beta-(tertiary alcohol)dihydrocodeinones and -dihydromorphinones.

Conjugate addition of lithium dialkyl cuprates to codeinone (3) gave as the major product a series of 8 beta-alkyldihydrocodeinones 4a-m. A low yield of the 8 alpha-isomer 6 was isolated in several cases. 8 beta-Acyldihydrocodeinones 10 were prepared by the addition of acyl carbanion equivalents (protected cyanohydrin method or lithium bis(alpha-ethoxyvinyl)cuprate) to 3 followed by hydrolysis. 8 beta-Acetyldihydrocodeine (12) was reacted with MeLi or n-BuLi to give tertiary alcohols 13, which were oxidized to target dihydrocodeinones 14. The 8 beta-substituted compounds with unsaturated (4c,f,m), branched (4d,g,i-k), or large straight-chain (4h,l) alkyl groups, as well as the acyl (10a-d) and tertiary alcohol (14a,b) derivatives, were less active than dihydrocodeinone (4n) in the mouse writhing and rat tail-flick analgesic assays. The analgesically active 8 beta-methyl (4a) and 8 beta-ethyl (4b) compounds were converted to N-(cyclopropylmethyl)- and N-(cyclobutylmethyl)dihydronorcodeinones (17 and 18) and -dihydronormorphinones (19 and 20). Some of these compounds had mixed agonist-antagonist profiles of action. One of these compounds, N-(cyclopropylmethyl)-8 beta-ethyldihydronorcodeinone (17b), has been selected for further study in man.