Stereoretentive Etherification of an α-Aryl-ß-amino Alcohol Using a Selective Aziridinium Ring Opening for the Synthesis of AZD7594.

A selective aziridinium ring-opening was used to etherify an α-aryl-ß-amino alcohol with stereochemical retention. This transformation was achieved in a biphasic system to address phenoxide solubility and the formation of a sulfonate ester impurity. The protecting group strategy was directed by a stability study of the activated α-aryl-ß-amino alcohol in this system. Process analytical techniques were used to establish reaction understanding, and mixing on large scale was modeled in silico. The process provided a selective and efficient method of preparing the nonsteroidal, inhaled selective glucocorticoid receptor modulator AZD7594.

Understanding the Alkylation of a Phenol by 1-(3-Chloropropyl)pyrrolidine: Evidence for the Intermediacy of an Azetidinium Ion.

The final synthetic step in the synthesis of cediranib, AZD2171, 1, is the alkylation of a phenol with an alkyl halide to generate an ether. Our need to understand and control the formation of synthetic impurities generated in this step of the synthesis led us to investigate the kinetics and mechanism of the alkylation of indolphenol, 2, 4-[(4-fluoro-2-methyl-1 H-indol-5-yl)oxy]-6-methoxyquinazolin-7-ol, by chloropyrrolidine, 3, 1-(3-chloropropyl)pyrrolidine. Studies in 1-methyl-2-pyrrolidinone (NMP) established that the active alkylating agent is the azetidinium ion, 4, 4-azoniaspiro[3.4]octane, formed via a slow intramolecular cyclization reaction of chloropyrrolidine, 3. The azetidinium ion was isolated as its tetraphenylborate salt from water by heating 3 in the presence of aqueous potassium tetraphenyl borate, and its competence as an intermediate was demonstrated by its fast reaction with 2 to yield cediranib, 1.

POCl3 chlorination of 4-quinazolones.

The reaction of quinazolones with POCl(3) to form the corresponding chloroquinazolines occurs in two distinct stages, which can be separated through appropriate temperature control. An initial phosphorylation reaction occurs readily under basic conditions (R(3)N, aq pK(a) > 9) at t < 25 °C to give a variety of phosphorylated intermediates. Pseudodimer formation, arising from reaction between phosphorylated intermediates and unreacted quinazolone, is completely suppressed at these temperatures, provided the system remains basic throughout the POCl(3)addition. Clean turnover of phosphorylated quinazolones to the corresponding chloroquinazoline is then achieved by heating to 70-90 °C. (N)- and (O)-phosphorylated intermediates, involving multiple substitution at phosphorus, have been identified and their reactions monitored using a combination of (1)H, (31)P, and (19)F NMR. Kinetic analysis of the reaction profiles suggest that the various intermediates react with both Cl(-) and Cl(2)P(O)O(-), but product formation arises exclusively from reaction of (O)-phosphorylated intermediates with Cl(-). (O)- and (N)-phosphorylated intermediates equilibrate rapidly on the time scale of the reaction. A minimum of 1 molar equiv of POCl(3) is required for efficient conversion of the intermediates to product.

Kinetics of amide formation through carbodiimide/N-hydroxybenzotriazole (HOBt) couplings.

The kinetics of formation of amide, 4, from the corresponding carboxylic acid by reaction with the isopropyl ester of methionine (MIPE), mediated by carbodiimide EDCI, 1, and HOBt, 2, have been studied in 1-methyl-2-pyrrolidinone (NMP) using reaction calorimetry. The reaction rates have been found to be independent of the concentration of HOBt, showing that the rate-determining step is the reaction between the carboxylic acid and EDCI to give the corresponding O-acylisourea. The pH dependence of the observed rate constants for O-acylisourea formation is consistent with a second-order reaction between doubly protonated EDCI (EDCIH2(2+), 6) and the carboxylate group. The observed rate constants fall sharply at high pH, as the fraction of EDCI as EDCIH2(2+) continues to fall strongly, whereas the carboxylic acid group is already fully ionized. The rate constant, kP, for reaction between the carboxylate group of acid, 3, and EDCIH2(2+) has a value of kP = 4.1 x 10(4) M(-1) s(-1) at 20 degrees C, some 10(5) times higher than similar rate constants measured in water. The subsequent catalytic cycle, involving reaction of O-acylisourea with HOBt to give HOBt ester, which then reacts with the amine to give the amide with regeneration of HOBt, determines the product distribution. In the case of the amino acid, 3, reaction of the O-acylisourea with MIPE to give amide, 4, is increasingly favored at higher pH values over that with the less basic internal aromatic amine of 3 to give the diamide 5.