Group 13 sulfides hydride derivatives

Solladie-Cavallo s group used Eliel s oxathiane 1 (derived from pulegone) in asymmetric epoxidation (Scheme 1.3) [1]. This sulfide was initially benzylated to form a single diastereomer of the sulfonium salt 2. Epoxidation was then carried out at low temperature with the aid of sodium hydride to furnish diaryl epoxides 3 with high enantioselectivities, and with recovery of the chiral sulfide 1. 

If one or more of the hydrogen atoms of a non-metal hydride are replaced formally with another group, R—e.g., alkyl residues—then derived compounds of the type R-XHn-i, R-XHn-2-R, etc., are obtained. In this way, alcohols (R-OH) and ethers (R-O-R) are derived from water (H2O) primary amines (R-NH2), secondary amines (R-NH-R) and tertiary amines (R-N-R R") amines are obtained from ammonia (NH3) and thiols (R-SH) and thioethers (R-S-R ) arise from hydrogen sulfide (H2S). Polar groups such as -OH and -NH2 are found as substituents in many organic compounds. As such groups are much more reactive than the hydrocarbon structures to which they are attached, they are referred to as functional groups. 

This modification resulted in a yield improvement for the pentacyclization process from 47 % to 66 %. Treatment of the amino ether 192 with diisobutylaluminum hydride in refluxing toluene accomplished Eschenmoser-Grob fragmentation and reduction of the initially formed immonium ion, to give the unsaturated amino alcohol 193 in 86% yield. It was gratifying to find that 193 was the only product formed in this reaction. In the tetrahydropyran derivative, reduction of 192 to 193 is accompanied by about 15 % simple elimination. Displacement of the tosyl group in 196 gives sulfide 197, which is oxidized to sulfone 198. This material is metallated and coupled with enantiomerically pure aldehyde to secure the codaphniphylline skelton [74]. 

The synthesis of the sulfur-containing intermediate 15 for the preparation of peptides XVI and XVII (77) is shown in Scheme 6. Synthetic intermediate 14 was derived from compound 6 by the reduction of the ester and ring closure after treatment with sodium hydride in dimethylforamide. The primary alcohol in compound 14 was then converted to a leaving group which was displaced by the desired thiol to give the intermediate 15. Oxidation of the resulting sulfide then afforded the corresponding sulfone for incorporation into the desired peptide XVI. 

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