Synthesis, Radiosynthesis and Biological Evaluation of Buprenorphine-Derived Phenylazocarboxamides as Novel µ-Opioid Receptor Ligands.

Targeted structural modifications have led to a novel type of buprenorphine-derived opioid receptor ligand displaying an improved selectivity profile for the µ-OR subtype. On this basis, it is shown that phenylazocarboxamides may serve as useful bioisosteric replacements for the widely occurring cinnamide units, without loss of OR binding affinity or subtype selectivity. This study further includes functional experiments pointing to weak partial agonist properties of the novel µ-OR ligands, as well as docking and metabolism experiments. Finally, the unique bifunctional character of phenylazocarboxylates, herein serving as precursors for the azocarboxamide subunit, was exploited to demonstrate the accessibility of an 18 F-fluorinated analogue.

Synthesis and evaluation of three structurally related ¹8F-labeled orvinols of different intrinsic activities: 6-O-[¹8F]fluoroethyl-diprenorphine ([¹8F]FDPN), 6-O-[¹8F]fluoroethyl-buprenorphine ([¹8F]FBPN), and 6-O-[¹8F]fluoroethyl-phenethyl-orvinol ([¹8F]FPEO).

We report the synthesis and biological evaluation of a triplet of 6-O-(18)F-fluoroethylated derivatives of structurally related orvinols that span across the full range of intrinsic activities, the antagonist diprenorphine, the partial agonist buprenorphine, and the full agonist phenethyl-orvinol. [(18)F]fluoroethyl-diprenorphine, [(18)F]fluoroethyl-buprenorphine, and [(18)F]fluoroethyl-phenethyl-orvinol were prepared in high yields and quality from their 6-O-desmethyl-precursors. The results indicate suitable properties of the three 6-O-(18)F-fluoroethylated derivatives as functional analogues to the native carbon-11 labeled versions with similar pharmacological properties.

Structural determinants of opioid and NOP receptor activity in derivatives of buprenorphine.

The unique pharmacological profile of buprenorphine has led to its considerable success as an analgesic and as a treatment agent for drug abuse. Activation of nociceptin/orphanin FQ peptide (NOP) receptors has been postulated to account for certain aspects of buprenorphine's behavioral profile. In order to investigate the role of NOP activation further, a series of buprenorphine analogues has been synthesized with the aim of increasing affinity for the NOP receptor. Binding and functional assay data on these new compounds indicate that the area around C20 in the orvinols is key to NOP receptor activity, with several compounds displaying higher affinity than buprenorphine. One compound, 1b, was found to be a mu opioid receptor partial agonist of comparable efficacy to buprenorphine but with higher efficacy at NOP receptors.

Synthesis of buprenorphine from oripavine via N-demethylation of oripavine quaternary salts.

Buprenorphine was synthesized from oripavine by a sequence involving the conversion of oripavine into its cyclopropylmethyl quaternary salt, N-demethylation with thiolate to N-cyclopropylmethyl nororipavine, and conversion of this material to the title compound by previously available methods. The new synthesis avoids toxic reagents used previously, is shorter, and proceeds in comparable yields. Experimental and spectral data are provided for all new compounds.

Chemical and enzyme-assisted syntheses of norbuprenorphine-3-ß-D-glucuronide.

Norbuprenorphine-3-ß-d-glucuronide (nBPN-3-ß-d-G, 1) is a major phase II metabolite of buprenorphine, a pharmaceutical used for the treatment of opioid addiction. The pharmacological activity of compound 1 is not clear because investigations have been limited by the lack of chemically pure, well characterized 1 in sufficient quantities for in vitro and in vivo experiments. This work describes two concise, new methods of synthesis of 1, a chemical and an enzyme-assisted synthesis. The chemical synthesis used a strategy based on a combination of Koenig-Knorr coupling and amino-silyl protection. The enzyme-assisted synthesis used dog liver to convert the substrate norbuprenorphine (nBPN, 2) to 1. Both methods provided 1, characterized by (1)H NMR and tandem mass spectrometry, with purity >96%. The fractional yield of the enzyme-assisted synthesis was greater than that of the chemical synthesis (67% vs 5.3%), but due to larger reaction volumes, the chemical synthesis afforded greater amounts of total 1.

Energy-dependent collision-induced dissociation study of buprenorphine and its synthetic precursors.

The collision-induced dissociation (CID) of protonated buprenorphine ([M+H](+) ) and four related compounds was studied by electrospray quadrupole/time-of-flight mass spectrometry (ESI-QTOF MS). The fragmentation pathways were investigated by using energy-dependent CID and pseudo-MS(3) (in-source CID combined with tandem mass spectrometry (MS/MS)) methods. The first steps of the fragmentation are the parallel losses of the substituents from the non-aromatic ring moieties. Depending on the applied collision energies, a large number of further fragment ions arising from the cross-ring cleavages of the core-ring structure were observed. Based on the experimental results, a generalized fragmentation scheme was developed for the five buprenorphine derivatives highlighting the differences for the alternatively substituted compounds. The collision-energy-dependent fragmentation profile of buprenorphine is visualized in a two-dimensional plot to aid its fingerprint identification.

A highly selective kappa-opioid receptor agonist with low addictive potential and dependence liability.

Buprenorphine analogs have been synthesized. In the studies of analgesic and addictive effects in mice and [(35)S]GTPgammaS binding assay in human brain tissue, an analog of buprenorphine where the tert-butyl is replaced by a cyclobutyl moiety (16) has been identified as a selective kappa-partial agonist which gives antinociceptive effects, but has low abuse potential. The results may lead to lower degrees of dysphoria than full kappa-agonists.

An esterification method for synthesizing prodrugs of buprenorphine.

BACKGROUND: Buprenorphine is a potent analgesic. Extending its duration of action would make buprenorphine more valuable for clinical use. The depot formulation with prodrug design is a method used to prolong the duration of a short-acting drug. The aim of this study was to design and develop an esterification method to synthesize the prodrugs of buprenorphine and also to find out the detailed chemical characteristics of these prodrugs. METHODS: A method of esterification was used. Buprenorphine prodrugs were synthesized by esterizing buprenorphine with various fatty acids and then purified by silica-gel column chromatography. The chemical structures of the prodrugs were affirmed by infrared, nuclear magnetic resonance and gas chromatography/mass spectrometries. RESULTS: Six ester-type prodrugs of buprenorphine were successfully synthesized: buprenorphine propionate, pivalate, benzoate, valerate, enanthate, and decanoate. CONCLUSIONS: A proper method for esterification of buprenorphine was developed. Six ester-type prodrugs of buprenorphine were successfully synthesized and the detailed chemical characteristics of these prodrugs were put forward.

No-carrier-added (NCA) N-(3-[18F]fluoropropyl)-N-norbuprenorphine and N-(3-[18F]fluoropropyl)-N-nordiprenorphine--synthesis, anatomical distribution in mice and rats, and tomographic studies in a baboon.

N-(3-Fluoropropyl)-N-norbuprenorphine (3a) and N-(3-fluoropropyl)-N-nordiprenorphine (4a) were synthesized by N-alkylation of norbuprenorphine (1) and nordiprenorphine (2) with 1-bromo-3-fluoropropane. The corresponding no-carrier-added (NCA) N-(3-[18F]fluoropropyl)-N-norbuprenorphine (3b) and N-(3-[18F]fluoropropyl)-N-nordiprenorphine (4b) were synthesized by N-alkylation of 1 and 2 with NCA 1-[18F]fluoro-3-iodopropane in a synthesis time of approximately 100 min from end of bombardment (EOB) with an overall radiochemical yield of approximately 15% (EOB) and a mass of 2-3 nmol. In vitro studies indicate that in the absence of sodium chloride, compounds 3a, 4a, N-propyl-N-norbuprenorphine (5), buprenorphine and diprenorphine are reasonably comparable in binding affinity for opioid receptors. In the presence of 100 mM sodium chloride, however, compounds 3a, 4a and 5, are clearly less potent than buprenorphine and diprenorphine. The anatomical distribution study of compound 3b in mice shows radioactivity accumulating in bone, indicating that in vivo defluorination may have occurred. Rat studies of both compounds 3b and 4b indicate the specific distribution of these two radioligands within certain cortical and subcortical regions of rat brain. However, the absolute uptake of compound 4b in rat brain was only half that of compound 3b. PET studies of 3b in a baboon revealed specific binding of compound 3b in striatum and cerebellum. At 1 h after injection, ratios of specific/non-specific binding of 3b in striatum and cerebellum of a baboon were 1.9 and 1.7 respectively.

Radioimmunoassay of buprenorphine with iodine label: analysis of buprenorphine and metabolites in human plasma.

Quantitative analysis of potent opiate drugs in plasma by radioimmunoassay is potentially inaccurate because of the occurrence of cross-reacting metabolites. This paper describes the chemical synthesis of buprenorphine-3-O-glucuronide, a metabolite of buprenorphine, and an extraction procedure coupled with radioimmunoassay which allows the sensitive and specific measurement of buprenorphine using an iodinated buprenorphine derivative. The measurement of extracted and unextracted samples using two different antisera allowed investigation of the metabolism of buprenorphine. In four patients who had taken sublingual buprenorphine for at least one month, N-dealkyl buprenorphine was present in similar concentrations to those of buprenorphine, while buprenorphine-3-O-glucuronide was present in two to three times those concentrations.