RESUMEN
We report an improved and scalable synthesis of MIDD0301, a positive GABAA receptor modulator that is under development as oral and inhaled treatments for asthma. In contrast to other benzodiazepines in clinical use, MIDD0301 is a chiral compound that has limited brain absorption. The starting material to generate MIDD0301 is 2-amino-5-bromo-2'-fluorobenzophenone, which has a non-basic nitrogen due to electron withdrawing substituents in the ortho and para positions, reducing its reactivity towards activated carboxylic acids. Investigations of peptide coupling reagents on multigram scale resulted in moderate yields due to incomplete conversions. Secondly, basic conditions used for the formation of the seven-membered 1,4-diazepine ring resulted in racemization of the chiral center. We found that neutral conditions comparable to the pKa of the primary amine were sufficient to support the formation of the intramolecular imine but did not enable the simultaneous removal of the protecting group. Both difficulties were overcome with the application of the N-carboxyanhydride of D-alanine. Activated in the presence of acid, this compound reacted with non-basic 2-amino-5-bromo-2'-fluorobenzophenone and formed the 1,4-diazepine upon neutralization with triethylamine. Carefully designed workup procedures and divergent solubility of the synthetic intermediates in solvents and solvent combinations were utilized to eliminate the need for column chromatography. To improve compatibility with large scale reactors, temperature-controlled slow addition of reagents generated the imidazodiazepine at -20 °C. All intermediates were isolated with a purity of >97% and impurities were identified and quantified. After the final hydrolysis step, MIDD0301 was isolated in a 44% overall yield and purity of 98.9% after recrystallization. The enantiomeric excess was greater than 99.0%.
RESUMEN
Antinociceptive ligand HZ-166 is a GABAA α2/α3 receptor subtype-selective potentiator. It has been shown to exhibit anxiolytic-like effects in rodent and rhesus monkeys, as well as reduced sedative/ataxic liabilities. In order to improve the metabolic stability of HZ-166, the ethyl ester moiety was bioisosterically replaced with 2,4-disubstituted oxazoles and oxazolines. The new analogs of HZ-166 were synthesized, characterized, and evalutated for their biological activity and docked in the human full-length heteromeric α1ß3γ2L GABAA receptor subtype CyroEM structure (6HUO). Importantly no sedation nor ataxia was observed on the rotorod for LKG-I-70 (6) or KPP-III-51 (6c) at 100 and 120 mg/kg, respectively. These was also no loss of righting response for either ligand.