18422-53-2Relevant articles and documents
Concise stereoselective total synthesis of (+)-muricatacin and (+)-epi-muricatacin
Dong, Hong-Bo,Yang, Ming-Yan,Liu, Bin,Wang, Ming-An
, p. 847 - 853,7 (2014)
Efficient stereoselective total synthesis of (+)-muricatacin (1) and (+)-epi-muricatacin (8) was accomplished from commercially available chemical pent-4-ynoic acid via Shi's asymmetric epoxidation and Mitsunobu reaction as the key steps in 17.8% and 26.9
A convenient synthesis of L-ribose from D-fructose
Perali, Ramu Sridhar,Mandava, Suresh,Bandi, Ramakrishna
, p. 4031 - 4035 (2011)
An efficient method for the stereoselective synthesis of L-ribose was accomplished starting from commercially inexpensive D-fructose. The intermediates in the process can serve as versatile precursors for the preparation of L-nucleoside analogues.
Binkley
, p. C1 (1976)
Mc Donald
, p. 106 (1967)
Studies on asymmetric total synthesis of (?)-β-hydrastineviaa chiral epoxide ring-opening cascade cyclization strategy
Cheng, Maosheng,Li, Jihui,Liu, Yongxiang,Meng, Jiaxin,Qin, Qiaohua,Song, Xinjing,Wu, Tianxiao,Zhao, Dongmei,Zheng, Yang
, p. 18953 - 18958 (2020/06/08)
Herein, facile and enantioselective approaches to synthesize the core phthalide tetrahydroisoquinoline scaffold of (?)-β-hydrastineviaboth a CF3COOH-catalyzed (86% ee) and KHMDS-catalyzed (78% ee) epoxide ring-opening/transesterification cascade cyclization from chiral epoxide under very mild conditions are described. The key elements include a highly enantioselective epoxidation using the Shi ketone catalyst and an intramolecular CF3COOH-catalyzed cascade cyclization in one pot, and a late-stage C-3′ epimerization under MeOK/MeOH conditions as the key steps to achieve the first total synthesis of (?)-β-hydrastine (up to 81% ee).
Safe and Scalable Aerobic Oxidation by 2-Azaadamantan-2-ol (AZADOL)/NOx Catalysis: Large-Scale Preparation of Shi's Catalyst
Sasano, Yusuke,Sato, Hikaru,Tadokoro, Shinsuke,Kozawa, Masami,Iwabuchi, Yoshiharu
, p. 571 - 577 (2019/03/19)
A method for safe and scalable aerobic alcohol oxidation using 2-azaadamantan-2-ol (AZADOL), an azaadamantane-type hydroxylamine catalyst, with a NOx cocatalyst in a conventional batch reactor has been developed. The use of 2 mol % AZADOL and 10 mol % NaNO2 was determined to promote aerobic alcohol oxidation quantitatively within a reasonable time (8 h). Safety is ensured by controlling the reaction temperature below the flash point of the acetic acid solvent. The robustness of the developed method is demonstrated by the 500 g scale oxidation of diacetone fructose into Shi's catalyst for asymmetric epoxidation.
An alkoxyamine compound, alkoxy alcohol oxidation catalyst and method of using the alcohol oxidation
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Paragraph 0096; 0099-0100, (2017/02/02)
PROBLEM TO BE SOLVED: To provide a novel alkoxyamine compound which can be easily manufactured and applied suitably as an alcohol oxidation catalyst capable of exerting sufficiently high catalytic activity in oxidation of primary and secondary alcohols.SOLUTION: There is provided an alkoxyamine compound with a homoadamantane skeleton represented by the general formula (1) in the figure. [In the formula (1), Rand Rare each independently any one selected from the group consisting of a hydrogen atom and alkyl groups that may be substituted.