Unexpected carbonate salt formation during isolation of an enantiopure intermediate by supercritical fluid chromatography.

The enantiomers of a chiral building block to be used in pre-clinical manufacturing were separated using supercritical fluid chromatography (SFC). Despite an extensive evaluation of different columns and solvent combinations followed by a careful optimization of the chromatographic method, the preparative separation suffered from low throughput and high solvent consumption. Consequently, additional improvements were necessary. By utilizing stacked injections, the chromatographic run time was almost halved, and the high solvent consumption was reduced by recycling of the two mobile phase components, carbon dioxide and methanol. The carbon dioxide was reprocessed by the SFC instrument, whereas methanol was evaporated and recycled from the fractions collected. Hence, the originally inefficient separation method was turned into a more sustainable one, and the desired enantiopure intermediate was delivered to be used in the following synthesis of the selected candidate drug. Unfortunately, when the intermediate was used in the subsequent amide coupling, a surprisingly poor yield was obtained. This was caused by an unexpected formation of a stable carbonate salt of the intermediate under the chromatographic conditions used. By removal of the carbonate prior to the amide coupling reaction, the manufacturing campaign could be saved, and the candidate drug was successfully delivered in time.

Saccharin Aza Bioisosteres-Synthesis and Preclinical Property Comparisons.

Saccharin is a well-known scaffold in drug discovery. Herein, we report the synthesis and preclinical property comparisons of three bioisosteres of saccharin: aza-pseudosaccharins (cluster B), and two new types of aza-saccharins (clusters C and D). We demonstrate a convenient protocol to selectively synthesize products in cluster C or D when primary amines are used. Preclinical characterization of selected matched-pair products is reported. Through comparison of two diastereomers, we highlight how stereochemistry affects the preclinical properties. Given that saccharin-based derivatives are widely used in many chemistry fields, we foresee that structures exemplified by clusters C and D offer new opportunities for novel drug design, creating a chiral center on the sulfur atom and the option of substitution at two different nitrogens.