The synthesis and analgesic testing of 3-[4-(1,1-dimethylheptyl)-2-hydroxyphenyl]cyclohexanol (1) are described. Prior (SAR) studies led us to conclude that the pyran ring of 9-nor-9 beta-hydroxyhexahydrocannabinol (HHC) was not necessary for the expression of biological activity in this series of cannabinoids. Analysis of models and the use of molecular mechanics calculations suggested that a simpler compound, such as 1, would possess the biological activity of HHC. Compound 1 was prepared in nine steps from [3-(benzyloxy)phenyl]acetonitrile (2). Biological testing in five models of pain shows that compound 1 and morphine are equally potent as analgesics and demonstrates that the pyran ring of HHC is not necessary for biological activity. Further simplification of 1 was pursued by the synthesis of 4-[4-(1,1-dimethylheptyl)-2-hydroxyphenyl]-2-pentanol (17), but this derivative exhibits significantly reduced analgesic activity.
The Research Analysis and Utilization System (RAUS) is designed to serve four functions: Collect and systematically classify the findings of all intramural and extramural research supported by the National Institute on Drug Abuse (NIDA); Evaluate the findings in selected areas of particular interest and formulate a state-of-the-art review by a panel of scientific peers; Disseminate findings to researchers in the field and to administrators, planners, instructors, and other interested persons; Provide a feedback mechanism to NIDA staff and planners so that the administration and monitoring of the NIDA research program reflect the very latest knowledge gleaned from research in the field. Since the number of research topics that can be intensively reviewed annually is limited, four subject areas are chosen each year to undergo a thorough examination. Distinguished scientists are invited to participate. Each scientist is provided reports from NIDA-funded research and asked to add information derived from the literature and his or her own research and to prepare a comprehensive, state-of-the-art review paper on an assigned topic. These papers, together with a summary of the discussions which take place at the review meeting, make up a RAUS Review Report in the NIDA Research Monograph series. In recent years a large number of reviews and books have appeared summarizing research advances in the chemistry, pharmacology, toxicology, metabolism, and distribution of cannabinoids and their synthetic analogs. Yet the volume of research on structure-activity relationships of cannabinoids appears to have decreased. In order to evaluate NIDA's current research program on cannabinoids, to rekindle interest in this critical area, and to focus attention on profitable avenues for future research, NIDA found it timely to bring together experts on the structure-activity relationships of cannabinoids for a comprehensive review. v
A series of (aminoalkyl)indole compounds, naphthalene analogs of pravadoline (1), has been shown to exhibit cannabinoid agonist activities such as antinociception in animals, inhibition of adenylate cyclase in brain membranes, and binding to the cannabinoid receptor. These pravadoline analogs were selected for the preparation of potential electrophilic affinity ligands based on the synthesis of isothiocyanate derivatives. One isothiocyanatonaphthalene derivative (8) displaced [3H]CP-55940 binding to a rat brain P2 membrane preparation with an IC50 of 690 nM, which was 10-fold less potent than the parent molecule (IC50 = 73 nM). Isothiocyanate substitution at various positions on the naphthalene moiety of the desmethyl analog 10 gave compounds that displaced [3H]CP-55940 with IC50 values between 400 and 1000 nM, compared with 46 nM for the parent compound 10. However, 6-isothiocyanato substitution on the indole ring of the desmethyl analog provided isothiocyanate 12 that displaced [3H]CP-55940 binding with an IC50 and 160 nM. After pretreatment of brain membranes with this high-affinity isothiocyanato ligand followed by washing out the ligand, the membranes were depleted of 90% of the cannabinoid receptor binding capacity. Loss of receptor binding capacity was half-maximal at 300 nM of the derivative under standard assay conditions. As a control, pretreatment with the parent compound at concentrations that were 20 times the Kd failed to alter subsequent binding activity. This study demonstrates that an isothiocyanato (aminoalkyl)-indole (12) can behave as an affinity ligand which binds irreversibly to the cannabinoid receptor in brain and which precludes subsequent binding of the cannabinoid ligand [3H]CP-55940.
The aim of this work was to assess the use of a sustained-release formulation of somatuline, a long-acting analogue of somatostatin, in the treatment of acromegaly. Fifteen patients with active acromegaly, as defined by random growth hormone (GH) levels greater than 10 mU/l, which fail to be suppressed to less than 5 mU/l following an oral glucose load, were studied. Somatuline was administered as an intramuscular injection in two regimens: eight patients were given a single injection of the sustained-release formulation and blood samples taken over the next month for the measurement of both basal levels of GH and the GH response to thyrotrophin-releasing hormone; and eight patients were given injections of the sustained-release formulation at 2-week intervals over a 6-month period and basal plasma GH levels and the GH response to both an oral glucose load and to thyrotrophin-releasing hormone was assessed. Following a single intramuscular dose of the sustained-release preparation, random GH levels were reduced to below 10 mU/l in five patients and by greater than 50% of basal levels in the remainder. The insulin-like growth factor I (IGF-I) levels fell to within the normal range in three patients. In the long-term efficacy study. GH levels were reduced to < 10 mU/l in 7/8 patients. The IGF-I levels were normalized in four patients. Five of the eight patients experienced diarrhoea, two of mild and three of moderate severity; none of the patients withdrew from the study.(ABSTRACT TRUNCATED AT 250 WORDS)
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