Arylhydrazines 4 and 1,3-dicarbonyl compounds 5 react to form pyrazoles by loss of water via hydrazone isomer pairs 6 and 7 which give rise to two possible regio-isomers. Occasionally, 3-hydroxy-3,4-dihydropyrazoles or hydroxy-pyrazolines 9 and 9 are observed as stable isolatable intermediates that can be fully characterized prior to loss of the second molecule of water that gives rise to pyrazoles 10 and 11. Fully characterized examples of intermediates of type 8 and 9 are relatively rare. We studied the reaction series where R = CH3, CHF2 and CF3 and Ar = Ph and 5-methanesulfonylpyridin-2-yl, (Scheme 2), and observed differences in properties between kinetic behavior and regio-isomerism depending on the degree of electron-withdrawing capability of the R and Ar substituents. The reaction conditions that caused cyclization to pyrazoles varied from direct condensation of the hydrazine and 1,3-dicarbonyl compounds, to reactions requiring catalytic quantities of sulfuric acid to sulfuric acid in excess. Unexpected regio-selectivity was observed in the case of R = CF3 that depended upon the reaction conditions.
Many years ago anidulafungin 1 was identified as a potentially useful medicine for the treatment of fungal infections. Its chemical and physical properties as a relatively high molecular weight semisynthetic derived from echinocandin B proved to be a significant hurdle to its final presentation as a useful medicine. It has recently been approved as an intravenous treatment for invasive candidaisis, an increasingly common health hazard that is potentially life-threatening. The development and commercialization of this API, which is presented as a molecular mixture of anidulafungin and D-fructose is described. This includes, single crystal X-ray structures of the starting materials, the echinocandin B cyclic-peptide nucleus (ECBN • HCl) and the active ester 1-({[4′′-(pentyloxy)-1,1′:4′,1′′-terphenyl-4-yl]carbonyl}oxy)-1H-1,2,3-benzotriazole (TOBt). Details of the structure and properties of starting materials, scale-up chemistry and unusual crystallization phenomena associated with the API formation are discussed.
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