Stereoselectivity second order transformation

If kepi, k-epi are much larger than the rates k, ki of substitution, the enantiomeric ratio Hepi-1 is similar to kxjk (path C, dynamic kinetic resolution . Both mechanisms are performing when the rates of the two steps are similar. Since rates and equilibrium are temperature-dependent, enhancement of stereoselectivities can be achieved by sophisticated protocols (see Section m.E). The equilibrium 6/epi-6 is determined by the difference of free energy A AG. This effective energy difference is enlarged if it can be coupled with a second order transformation such as the selective crystallization of one diastere-omer dynamic thermodynamic resolution ). In fact, this applies to the first successful (—)-sparteine-mediated deprotonation (Section FV.C.l). 

The achiral 14-membered trans-diimine macrocycle (f , S )-102, in the presence of trifluoroacetic acid, rearranges quantitatively into the chiral seven-membered monoimine ( )-103 (Section Ill.C.l.h)". If the rearrangement of (i , S )-102 is carried out in methanol containing a suspension of ( )-(—)-78, an orange solution is obtained from which pure [I ,(Sas,I as)] ( )-1 6 can be isolated by the addition of ammonium hexafluorophosphate. The yield of the complex was ca 50%. The addition of more acid and halide in an attempt to facilitate racemization of the free arsine and thereby promote the further crystallization of the complex by second-order asymmetric transformation was unsuccessful. Nevertheless, this highly stereoselective synthesis of [H,(Sas,IIas)] ( ) 106 is a more expedient route to (R,I )-(—)-102 than the one involving resolution of the benzyl alcohol complex (R, SA.)-(-)-92a. 

In order to apply tartrate ester-modified allyl- and crotylboronates to synthetic problems,23 Roush and Palkowitz undertook the stereoselective synthesis of the C19-C29 fragment 48 of rifamycin S, a well-known member of the ansamycin antibiotic group24 (Scheme 3.1u). The synthesis started with the reaction of (S,S)-43E and the chiral aldehyde (S)-49. This crotylboration provided the homoallylic alcohol 50 as the major component of an 88 11 1 mixture. Compound 50 was transformed smoothly into the aldehyde 51, which served as the substrate for the second crotylboration reaction. The alcohol 52 was obtained in 71% yield and with 98% diastereoselectivity. After a series of standard functional group manipulations, the alcohol 53 was oxidized to the corresponding aldehyde and underwent the third crotylboronate addition, which resulted in a 95 5 mixture... 

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