Ketones hindered, reaction with

There are actually three reactions called by the name Schmidt reaction, involving the addition of hydrazoic acid to carboxylic acids, aldehydes and ketones, and alcohols and alkenes. The most common is the reaction with carboxylic acids, illustrated above.Sulfuric acid is the most common catalyst, but Lewis acids have also been used. Good results are obtained for aliphatic R, especially for long chains. When R is aryl, the yields are variable, being best for sterically hindered compounds like mesi-toic acid. This method has the advantage over 18-13 and 18-14 that it is just one laboratory step from the acid to the amine, but conditions are more drastic. Under the acid conditions employed, the isocyanate is virtually never isolated. 

With less hindered hydride donors, particularly NaBH4 and LiAlH4, confor-mationally biased cyclohexanones give predominantly the equatorial alcohol, which is normally the more stable of the two isomers. However, hydride reductions are exothermic reactions with low activation energies. The TS should resemble starting ketone, so product stability should not control the stereoselectivity. A major factor in the preference for the equatorial isomer is the torsional strain that develops in the formation of the axial alcohol.117... 

Unsymmetrical ketones can be made by using either thexylborane or thexylchloroborane.12 Thexylborane works well when one of the desired carbonyl substituents is derived from a moderately hindered alkene. Under these circumstances, a clean monoalkylation of thexylborane can be accomplished, which is then followed by reaction with a second alkene and carbonylation. 

Some remarkable chemistry is observed when silenes react with heteroatom systems, in particular carbonyl compounds (]>C=0) and imines Q>C=N—R). The reaction with ketones was first described by Sommer (203), who postulated formation of an intermediate siloxetane which could not be observed and hence was considered to be unstable even at room temperature, decomposing spontaneously to a silanone (normally isolated as its trimer and other oligomers) and the observed alkene [Eq. (14)]. Many efforts have been made to demonstrate the existence of the siloxetane, but it is only very recently that claims have been advanced for the isolation of this species. In one case (86) an alternative formulation for the product obtained has been advanced (204). In a second case (121) involving reaction of a highly hindered silene with cyclopentadienones,... 

Selective 1,4-reduction of unsaturated aldehydes and ketones by 6 occurs smoothly in THF between —25 °C and room temperature within a few hours (Eq. 5.7). Particularly noteworthy is the realization that phosphines are noticeably absent from the reaction medium. The analogous combination of CuCl/BusSnH in N-methyl-2-pyrrolidinone (NMP) or DMF does not behave identically [22], failing to react with the hindered substrate isophorone, whereas a 72% yield of the corresponding reduced ketone is formed with reagents XCu(H)Li/Bu3SnH. Nonetheless, a form of CuH is being generated in this more polar medium, effectively utilized by Tanaka to arrive at 3-norcephalosporin 8 upon reaction with allenic ester 7 (Scheme 5.3). 

The benzenesulfonyl substituent has also been used in conjunction with the lithiation of an azaindole derivative (86FRP2574406 89FRP26274931), and thus 1-benzenesulfonyl-1//-pyrrolo[3,2-c ]pyridine was able to be successfully lithiated and alkylated with p-methoxybenzaldehyde, although reaction with more hindered ketones could not be achieved (Scheme 19)[91JCS(P1)3I73]. 

Several examples of Bi(OTf)3-catalyzed Mannich-type reactions with various silyl enol ethers are summarized in Table 12. Silyl enol ethers derived from aromatic and aliphatic ketones were reacted with an equimolar mixture of aldehyde and aniline (Scheme 10). The corresponding (3-amino ketones 27 were obtained in good yields (Table 12, entries 1M-) from aromatic-derived silyl enol ethers, except for the more hindered isobutyrophenone derivative. Silyl enol ethers derived from cyclopentanone or cyclohexanone afforded the (3-amino ketones in good yields (Table 12, entries 5 and 6). 

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