Novel Pirkle-type quinine 3,5-dinitrophenylcarbamate chiral stationary phase implementing click chemistry.

A new Pirkle-anion exchange hybrid-type chiral stationary phase (CSP-1) has been synthesized by immobilizing 10,11-didehydroquinine 3,5-dinitrophenylcarbamate onto 3-azidopropyl silica gel using click chemistry (1,3-dipolar Huisgen cycloaddition). This chiral selector and CSP contain a strong π-accepting 3,5-dinitrophenyl residue besides the π-basic quinoline group and an ionizable tertiary amino group. In concert with ion pairing it offers π-donor-π-acceptor interactions resulting in an enhancement of the selectivity toward specific π-donating analytes such as aryloxypropionic acids and profens. A representative set of these analytes has been investigated under various chromatographic conditions (polar-organic, reversed- and normal-phase) leading to base-line enantioseparations with selectivity (α) values up to 1.8. Control experiments with related quinine tert-butylcarbamate phase grafted onto the surface either by thioether (Chiralpak QN-AX) or 1,2,3-triazole linker revealed the impact of the additional aromatic moiety in the chiral selector motif.

Triazolo-linked cinchona alkaloid carbamate anion exchange-type chiral stationary phases: Synthesis by click chemistry and evaluation.

Immobilization strategy based on Huisgen 1,3-dipolar cycloaddition (click chemistry) of 10,11-didehydrocinchona tert-butylcarbamates to azido-grafted silica gels has been evaluated for preparation of novel chiral stationary phases (CSP 1-3). The resultant 1,2,3-triazole-linked CSPs were tested under various mobile phase conditions (polar organic and reversed phase mode) with a representative set of structurally diverse racemic acids including N-protected aminoacids, aromatic and aryloxycarboxylic acids as well as binaphthol phosphate. The chiral recognition performance of the C3-triazole-linked CSPs was found to mirror largely that of the known C3-thioether-linked CSP in terms of elution order, enantioselectivity and retention behavior. In an effort to assess the non-specific binding expressed as retention increment of these triazole-linked CSPs, the parent azidopropyl- and triazole-modified silica materials (thus not containing the chiral head ligand) were studied independently. Compared with the corresponding CSPs, the analyte retention on the azidopropyl control column was very low, and practically negligible on the corresponding triazole-modified reference column. Only minor losses in analyte retention behavior (<5%) were observed with triazole-linked CSPs after two month of continuous use with polar-organic and reversed-phase-type mobile phases, highlighting the excellent stability of the 1,2,3-triazole linker.

An improved synthesis of 10,11-didehydro Cinchona alkaloids.

A revised procedure for the conversion of the four major Cinchona alkaloids (quinine, quinidine, cinchonidine, and cinchonine) into their respective 10,11-didehydro derivatives is described. The reported protocol offers several advantages over a recently published synthetic route. These include (i) enhanced robustness (ii) ready scalability (iii) reduced operational complexity and number of steps (iv) chromatography-free work-up. In addition, toxic solvents were replaced by environmentally less problematic alternatives.