393827-07-1Relevant articles and documents
Synthesis of an optically pure synthetic intermediate of aloperine from a yeast-reductive product
Yamauchi, Satoshi,Omi, Yasushi
, p. 1589 - 1594 (2005)
Optically pure (S)- and (R)-vinylpiperidine 2 and (S)-and (A)-(hydroxyethyl)piperidine 3, which were key intermediates for the synthesis of aloperine, were synthesized from yeast-reductive products.
A strategy for complex dimer formation when biomimicry fails: Total synthesis of ten coccinellid alkaloids
Sherwood, Trevor C.,Trotta, Adam H.,Snyder, Scott A.
supporting information, p. 9743 - 9753 (2014/07/22)
Although dimeric natural products can often be synthesized in the laboratory by directly merging advanced monomers, these approaches sometimes fail, leading instead to non-natural architectures via incorrect unions. Such a situation arose during our studies of the coccinellid alkaloids, when attempts to directly dimerize Natures presumed monomeric precursors in a putative biomimetic sequence afforded only a non-natural analogue through improper regiocontrol. Herein, we outline a unique strategy for dimer formation that obviates these difficulties, one which rapidly constructs the coccinellid dimers psylloborine A and isopsylloborine A through a terminating sequence of two reaction cascades that generate five bonds, five rings, and four stereocenters. In addition, a common synthetic intermediate is identified which allows for the rapid, asymmetric formal or complete total syntheses of eight monomeric members of the class.
A concise diastereoselective approach to (+)-dexoxadrol, (-)-epi-dexoxadrol, (-)-conhydrine and (+)-lentiginosine from (-)-pipecolinic acid
Bhat, Chinmay,Tilve, Santosh G.
, p. 10876 - 10883 (2014/01/06)
A new diastereoselective pathway for the total synthesis of (+)-dexoxadrol, first asymmetric synthesis of (-)-epi-dexoxadrol and formal synthesis of conhydrine and (+)-lentiginosine is presented using commercially available (-)-pipecolinic acid. The key reactions utilized are Sharpless asymmetric dihydroxylation and Wittig reaction. The paper further describes the study of effect of protecting groups on dihydroxylation of a terminal olefin in piperidine ring system.