1004540-33-3

Upstream product

• 77287-11-7 methyl (S)-2-(benzyloxy)propanoate 
• 33106-32-0 (S)-2-(benzyloxy)propanoic acid 
• 100-39-0 benzyl bromide 
• 1004540-03-7 C₂₀H₃₂O₃Si 
• 406940-46-3 (-)-(S)-2-(benzyloxy)-N-methoxy-N-methylpropanamide 
• 1004539-85-8 C₂₀H₃₄O₂Si 

Relevant academic research and scientific papers

Acyclic 1,4-Stereocontrol via the Allylic Diazene Rearrangement: Development, Applications, and the Essential Role of Kinetic e Stereoselectivity in Tosylhydrazone Formation

We report full details of a method for 1,3-reductive transposition of α-alkoxy-α,β-unsaturated hydrazones to provide E-alkenes with high 1,4-stereocontrol between the two respective allylic stereocenters. The process couples a chelation-controlled reduction of the hydrazone with an in situ allylic strain controlled retro-ene reaction of an allyl diazene, i.e., an allylic diazene rearrangement. Such stereotriads are frequently observed motifs in natural products. We observed a fortuitous kinetic preference for the E-hydrazone geometry during the hydrazonation reaction, as only the E-isomers could undergo chelation-controlled reduction.

Acyclic 1,4-stereocontrol via reductive 1,3-transpositions

(Chemical Equation Presented) One-pot reduction/allylic diazene rearrangement of lactic acid- and mandelic acid-derived α,β- unsaturated tosyl hydrazones leads to 1,4-syn-or 1,4-anti-E-2-alkenyl arrays in high yield and diastereoselectivity. Either the syn or the anti diastereomer can be prepared by choosing the appropriate alkene stereoisomer of the hydrazone. The E-alkenes led to the 1,4-syn isomers, while the Z-alkenes led to the 1,4-anti isomers, both with ≥20:1 diastereoselectivity.