Gregory A. Reichard

The design and synthesis of novel NK1/NK2 dual antagonists

Functional probing of the backbone of the Sanofi NK2 antagonist SR 48968 has resulted in the discovery of two new classes of NK1/NK2 dual antagonists: the diamine class and the oxime class. The addition of the amino or the oxime functional group results in the reversal of the stereochemical preference of the NK2 receptor.

Synthesis and structure–activity relationships of oxime neurokinin antagonists: discovery of potent arylamides

The structural modification of the benzylic ether region of oxime 1 has resulted in the identification of several novel aryl amides as selective or dual NK(1)/NK(2) antagonists.

The asymmetric synthesis of (3R)-N-methyl-2-oxo-[1,4′-bipiperidine]-3-acetamide in quantity

Abstract The asymmetric synthesis of the enantiomerically pure bipiperidine core fragment of a potent dual NK 1 /NK 2 antagonist is described. The utilization of a diastereoselective Michael addition employing Evans’ auxiliary as the key step allowed for the preparation of the fragment on a multi-kilogram scale.

Preparation of oxime dual NK1/NK2 antagonists with reduced NK3 affinity

By employing a stereosimplification approach, a thorough SAR exploration of the piperidine region of Sch 206272 was possible through a practical and efficient synthesis of substituted cyclic ureas. This SAR study led to the identification of a benzimidazolinone series of compounds which display single digit nanomolar NK(1)/NK(2) affinity and near micromolar binding for the NK(3) receptor.

Discovery of a novel, potent and orally active series of γ-lactams as selective NK1 antagonists

Strategic replacement of the nitrogen of the lead compound 1 in the original cyclic urea series with a carbon resulted in the discovery of a novel, potent and orally more efficacious gamma-lactam series of selective NK(1) antagonists. Optimization of the lactam series culminated in the identification of compounds with high binding affinity and excellent oral CNS activity.

Isolation of circulating metabolites in drug discovery using high-performance liquid chromatography, and their identification by liquid chromatography coupled with tandem mass spectrometry and nuclear magnetic resonance spectroscopy

One of the major components of modern drug discovery is the structural determination and the assessment of biological activity of plasma metabolites. LC-MS/MS has played a prominent role in the identification of metabolites; however, fragmentation patterns alone may not be sufficient for identification. Consequently, it may be necessary to isolate the metabolites for NMR or LC-NMR analysis. This report describes the isolation and identification of the major plasma metabolites of two lead compounds (SCH X and SCH Y). The major metabolite of SCH X in monkey plasma constituted 65% of total compound-derived materials. incubation of rat liver microsomes with SCH X gave the mono-hydroxylated metabolite found in monkey plasma; however, the yield was low. Incubations with microsomes from rats pre-treated with various cytochrome P450 inducers showed that the highest yield was obtained from pregnenolone 16a-carbonitrile (PCN)-induced animals. For SCH Y, two metabolites were found in bile and plasma of both rats and monkeys. Various in vitro systems did not produce amounts sufficient for isolation. Therefore, the metabolites of SCH X and SCH Y were isolated from PCN-induced rat liver microsomal incubation and rat bile, respectively. The chemical structures of the metabolites were unambiguously determined using LC-NMR analyses.

Structure–Activity relationships of oxime neurokinin antagonists: oxime modifications

A thorough SAR study of the oxime region of the dual NK(1)/NK(2) antagonist 1 revealed several modifications that result in potent dual antagonists. Follow up SAR studies on a second-generation scaffold demonstrate that certain polar groups on the oxime can improve the dual binding affinity to the subnanomolar range.