Lawrence S. Melvin

Behavioral, Biochemical, and Molecular Modeling Evaluations of Cannabinoid Analogs

Numerous cannabinoids have been synthesized that are extremely potent in all of the behavioral assays conducted in our laboratory. An important feature in increasing potency has been the substitution of a dimethylheptyl (DMH) side chain for the pentyl side chain. Our previous studies have shown that (-)-11-OH-delta 8-THC-dimethylheptyl was 80-1150 times more potent than delta 9-THC. Stereospecificity was demonstrated by its (+)-enantiomer which was more than 1400-7500 times less potent. A related series of DMH cannabinoid analogs has recently been synthesized and preliminary evaluations reported here. (-)-11-OH-delta 9-THC-DMH was found to be equipotent with (-)-11-OH-delta 8-THC-DMH. The aldehyde (-)-11-oxo-delta 9-THC-DMH was 15-50 times more potent than delta 9-THC. Surprisingly, (-)-11-carboxy-delta 9-THC-DMH was also active, being slightly more potent than delta 9-THC. In the bicyclic cannabinoid series, the length and bulk of the side chain were found to be equally important. Aminoalkylindoles, which are structurally dissimilar from classical cannabinoids, have been found to exhibit a pharmacological profile similar to delta 9-THC. Though not extremely potent in vivo, they appear to represent an entirely new approach to studying the actions of the cannabinoids. The structural diversity and wide-ranging potencies of the analogs described herein provide the opportunity to develop a pharmacophore for the cannabinoids using molecular modeling techniques.

The cannabinoid receptor: biochemical, anatomical and behavioral characterization

The actions of the active principle of marihuana, delta 9-tetrahydrocannabinol, are mimicked by synthetic cannabinoid agonists showing high potency and enantio-selectivity in behavioral assays. These drugs have been used to characterize cannabinoid receptor binding, biochemistry and pharmacology, leading to a better understanding of the effects of cannabinoids in the CNS of humans and experimental animals.

Selective and potent analgetics derived from cannabinoids.

Abstract: Based on the hypothesis that analgetic activity is a dissociable feature of the cannabinoid molecule, we examined modifications of the side chain, the phenolic moiety, and, most significantly, structures that lack the benzopyran functionality present in THC and (—)‐9‐nor‐9β‐hydroxyhexahydrocannabinol (HHC). A new grouping, the 1‐methyl‐4‐phenylbutyloxy C‐3 side chain, elaborates a unique lipopholic region. Replacement of the phenol substituent produced several derivatives which retain analgetic activity in the codeine potency range. Introduction of a weakly basic nitrogen at C‐5 and deletion of the axial methyl group in the B ring, two structural changes forbidden by traditional cannabinoid SAR, resulted in a unique family of benzoquinolines with potent analgetic activity. The prototype of this series, levonantradol, exhibits potent and stereospecific analgetic and antiemetic activity.

Enhancement of brain [3H]flunitrazepam binding and analgesic activity of synthetic cannabimimetics

Novel, synthetic cannabimimetics and delta 9-tetrahydrocannabinol were found to enhance the binding of [3H]flunitrazepam to mouse brain in vivo. This property, suggestive of facilitation of binding to benzodiazepine receptors, is consistent with the potentiation of the anticonvulsant activity of diazepam against pentylenetetrazol by these compounds. The relative potencies of delta 9-tetrahydrocannabinol and the new cannabimimetics for enhancing [3H]flunitrazepam binding in vivo could also be correlated with their relative analgesic efficacies. Similar pharmacological stereospecificity was displayed for both binding enhancement and analgesic effects. The following order of decreasing potency was observed: N-methyllevonantradol and (-)-CP-55,244 greater than levonantradol, canbisol, CP-42,096 and (-)-CP-55,940 greater than 9-beta-normethyl-9-beta-hydroxyhexahydrocannabinol, nabilone and CP-47,497 greater than delta 9-tetrahydrocannabinol. Dextronantradol, (+)-CP-55,940 and (+)-CP-55,244 were considerably less active than the respective (-)-enantiomers; cannabidiol was inactive. Extensive investigation of structure versus activity led to N-methyllevonantradol and the 3-(2-hydroxyphenyl)cyclohexanols derivative, (-)-CP-55,244, which are approximately 1000-fold more potent than delta 9-tetrahydrocannabinol.

Prototype cannabinoid analgetics, prostaglandins and opiates — A search for points of mechanistic interaction

Abstract While prototype cannabinoid analgetics such as levonantradol do not act at the opiate receptor, their opiate-like properties suggest a proximal site of action. Based on this reasoning we perceived a remarkable structural analogy between levonantradol and prostaglandin E2. We further postulated a three point receptor contact which enabled us to predict the minimum structural features for analgesia. In this report we describe a simple phenyl cyclohexanol ( 1 ) which was found to possess potent analgesia across a battery of analgetic assays and defines three key sites of receptor contact necessary for cannabinoid-like analgetic activity.

Synthesis of 14C isotopic isomers of tenidap—A novel antiinflammatory agent

Two isotopic isomers of tenidap, a novel antiinflammatory agent, were prepared. Compound 6 (specific activity = 10.24 mCi/mmol), having 14 C in the indole ring, was prepared in three steps (52% overall yield) starting from 1H-[ 14 C]indole-2,3-dione. Compound 11 (specific activity = 57.16 mCi/mmol, radiochemical purity = 99.0%), with 14 C in the C-3 methylene, was prepared in two steps (66% overall yield) beginning with 2-thiophenecarboxylic-[14C-carbonyl] acid.