779356-68-2Relevant academic research and scientific papers
Spongipyran synthetic studies. Evolution of a scalable total synthesis of (+)-spongistatin 1
Smith III, Amos B.,Sfouggatakis, Chris,Risatti, Christina A.,Sperry, Jeffrey B.,Zhu, Wenyu,Doughty, Victoria A.,Tomioka, Takashi,Gotchev, Dimitar B.,Bennett, Clay S.,Sakamoto, Satoshi,Atasoylu, Onur,Shirakami, Shohei,Bauer, David,Takeuchi, Makoto,Koyanagi, Jyunichi,Sakamoto, Yasuharu
supporting information; experimental part, p. 6489 - 6509 (2011/02/25)
Three syntheses of the architecturally complex, cytotoxic marine macrolide (+)-spongistatin 1 (1) are reported. Highlights of the first-generation synthesis include: use of a dithiane multicomponent linchpin coupling tactic for construction of the AB and CD spiroketals, and their union via a highly selective Evans boron-mediated aldol reaction en route to an ABCD aldehyde; introduction of the C(44)-C(51) side chain via a Lewis acid-mediated ring opening of a glucal epoxide with an allylstannane to assemble the EF subunit; and final fragment union via Wittig coupling of the ABCD and EF subunits to form the C(28)-C(29) olefin, followed by regioselective Yamaguchi macrolactonization and global deprotection. The second- and third-generation syntheses, designed with the goal of accessing 1 g of (+)-spongistatin 1 (1), maintain both the first-generation strategy for the ABCD aldehyde and final fragment union, while incorporating two more efficient approaches for construction of the EF Wittig salt. The latter combine the original chelation-controlled dithiane union of the E- and F-ring progenitors with application of a highly efficient cyanohydrin alkylation to append the F-ring side chain, in conjunction with two independent tactics to access the F-ring pyran. The first F-ring synthesis showcases a Petasis-Ferrier union/rearrangement protocol to access tetrahydropyrans, permitting the preparation of 750 mg of the EF Wittig salt, which in turn was converted to 80 mg of (+)-spongistatin 1, while the second F-ring strategy, incorporates an organocatalytic aldol reaction as the key construct, permitting completion of 1.009 g of totally synthetic (+)-spongistatin 1 (1). A brief analysis of the three syntheses alongside our earlier synthesis of (+)-spongistatin 2 is also presented.
Gram-scale synthesis of (+)-spongistatin 1: Development of an improved, scalable synthesis of the f-ring subunit, fragment union, and final elaboration
Smith III, Amos B.,Tomioka, Takashi,Risatti, Christina A.,Sperry, Jeffrey B.,Sfouggatakis, Chris
supporting information; experimental part, p. 4359 - 4362 (2009/06/06)
(Chemical Equation Presented) In a quest to develop an effective, scalable synthesis of (+)-spongistatin 1 (1), we devised a concise, third-generation scalable synthesis of (+)-7, the requisite F-ring tetrahydropyran aldehyde, employing a proline-catalyzed cross-aldol reaction. Subsequent elaboration to (+)-EF Wittig salt (+)-3, followed by union with advanced ABCD aldehyde (-)-4, macrolactonization and global deprotection permitted access to >1.0 g of totally synthetic (+)-spongistatin 1 (1).
Spongistatin synthetic studies. Evolution of a scalable synthesis for the EF fragment of (+)-spongistatin 1 exploiting a petasis-ferrier union/rearrangement tactic
Smith III, Amos B.,Sfouggatakis, Chris,Gotchev, Dimitar B.,Shirakami, Shohei,Bauer, David,Zhu, Wenyu,Doughty, Victoria A.
, p. 3637 - 3640 (2007/10/03)
(Chemical Equation Presented) An efficient, stereocontrolled, and scalable second-generation synthesis of (+)-3, an advanced EF subtarget for the total synthesis of (+)-spongistatin 1, has been achieved. Highlights of the strategy include preparation of t
