Boronate homologated aldehyde

Aldehydes from alkylhoronic esters, RB(OR1)2. This reagent reacts with al-kylboronic esters (2) to provide an ate complex (a). Addition of HgCl2 induces alkyl migration from boron to carbon to give 3, which is oxidized to a homologated aldehyde 4.1... 

Perlmutter used an oxymercuration/demercuration of a y-hydroxy alkene as the key transformation in an enantioselective synthesis of the C(8 ) epimeric smaller fragment of lb (and many more pamamycin homologs cf. Fig. 1) [36]. Preparation of substrate 164 for the crucial cyclization event commenced with silylation and reduction of hydroxy ester 158 (85-89% ee) [37] to give aldehyde 159, which was converted to alkenal 162 by (Z)-selective olefination with ylide 160 (dr=89 l 1) and another diisobutylaluminum hydride reduction (Scheme 22). An Oppolzer aldol reaction with boron enolate 163 then provided 164 as the major product. Upon successive treatment of 164 with mercury(II) acetate and sodium chloride, organomercurial compound 165 and a second minor diastereomer (dr=6 l) were formed, which could be easily separated. Reductive demercuration, hydrolytic cleavage of the chiral auxiliary, methyl ester formation, and desilylation eventually led to 166, the C(8 ) epimer of the... 

An efficient process for one-carbon homologation to aldehydes is based on cyclic boronate esters.17 These can be prepared by hydroboration of an alkene with dibromobor-ane, followed by conversion of the dibromoborane to the cyclic ester. The homologation step is carried out by addition of methoxy(phenylthio)methyllithium to the boronate ester. The migration step is induced by mercuric ion. Use of enantioenriched boranes and boronates leads to products containing the groups of retained configuration.18... 

Brown and co-workers developed a novel homoallenyl boronate reagent 169 based on diisopropyl tartrate for the stereoselective homoallenylation of aldehydes 170. The reagent 169 was prepared via homologation of the corresponding allenyl boronate or the alkylation of halomethyl boronate with allenyl Grignard similar to those reported in Scheme 26. The allyl boronate 169 upon reaction with aldehydes furnished the dienyl alcohols 172 with high ee (Scheme 28) <1996JOC100>. 

Chloromethylation of 2-alkyl-1,3,2-dioxaborinancs with dichloromethyllithium followed by reduction with potassium triisopropoxyborohydride yields one-carbon-homologated boronic esters. The homologation can be repeated and the homologated esters transformed into the corresponding at-, j7- or -/-chiral alcohols, aldehydes and acids13. 

A second three-carbon homologation procedure for conversion of a saturated aldehyde into an a/8-unsaturated aldehyde involves initial reaction with cyclo-propylmagnesium bromide, followed by heating the cyclopropyl derivative in dimethyl sulphoxide containing a trace amount of boron trifluoride (Scheme 54). ... 

The 1,5-anti-aldol reaction was performed with chiral boron enolate of 325 and aldehyde 327, prepared by Evans asymmetric alkylation, cross metathesis, and Wittig homologation (Scheme 72), to afford 324 with a 96 4 diastereoselectivity. Stereoselective reduction of C9-ketone provided the 5y -l,3-diol, which was exposed to catalytic f-BuOK to give 2,6-cis-tetrahyderopyran 333 via an intramolecular Michael reaction. Finally, methyl etherification, deprotection, hydrolysis of ester, and Yamaguchi macrolac-tonization yielded the leucascandrolide macrolide 201 (Scheme 73). 

By reacting 1,4-butane diol with paraformaldehyde in the presence of sulfuric acid at 150-180" , the seven-membered 1,3-dioxepane is prepared. With other aldehydes, homologous 2-alkyl-substituted 1,3-dioxepanes have also been prepared using a cationic ion exchange resin instead of sulfuric acid. This latter technique was introduced by Astle [42]. The dioxepanes have been converted to polymers in methylene dichloride or in 1,2-dichloro-ethylene. The initiator used was boron trifluoride etherate the reaction temperatures ranged from -10° to +10°. The reactions were carried out under anhydrous conditions by techniques suitable for reaction kinetics studies. The work indicated that, at least for this class of compounds, the polymerization propagation step involves linear alkoxycarbenium ions [47]. 

Boron-stabilized anions have again been put to use in C—C bond-forming processes, an example of which is provided by the reaction of the anion (74) with electrophiles. Alkyl halides give substituted boronic esters, whereas aldehydes are converted to predominantly ci5-alkeneboronic esters, in contrast to the condensation of diborylmethide ions with aldehydes (mainly trans-). A useful homologation of carbonyl compounds to aldehydes involves reaction with the anion (75), to give alkeneboronic esters (76), followed by oxidation. ... 

A large variety of propionic acid esters and higher homologs having a chiral alcohol moiety have been used in additions to aldehydes [56, 57]. It turned out, however, that the lithium enolates result in only moderate simple diastereoselectivity and induced stereoselectivity, in contrast with the corresponding boron, titanium, tin, or zirconium enolates and silyl ketene acetals, with which stereoselectivity is excellent. The same feature has been observed in enolates derived from chiral amides and oxazolidinones, as... 

An efficient process for one-carbon homologation to aldehydes is based on cyclic boronate esters. These can be prepared by hydroboration of an alkene with dibromoborane, followed by displacement of the labile bromines. The homologation... 

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