Aldol condensations with aldehydes

In contrast, fluorinated ketones have been used as both nucleophilic and electrophilic reaction constituents The (Z)-lithium enolate of 1 fluoro 3,3-di-methylbutanone can be selectively prepared and undergoes highly diastereoselec-tive aldol condensations with aldehydes [7] (equation 8) (Table 4)... 

Earlier studies had demonstrated that such enolates would participate in aldol condensations with aldehydes however, the stereochemical aspects of the reaction were not investigated (68). For the cases summarized in Table 25, the zirconium enolates were prepared from the corresponding lithium enolates (eq. [54]). Control experiments indicated that no alteration in enolate geometry accompanies this ligand exchange process, and that the product ratio is kinetically controlled (35). From the cases illustrated, both ( )-enolates (entries A-E) and (Z)-enolates (entries F-H) exhibit predominant kinetic erythro diastereoselection. Although a detailed explanation of these observations is clearly speculative, certain aspects of a probable... 

Stereoselective aldol-type condensation.1 Enol silyl ethers do not undergo aldol condensation with aldehydes or ketones in the presence of this triflate,. but the reaction occurs at —78° (4-12 hours) with the corresponding acetals or ketals (and certain orthoesters). Moreover the erythro-aldol is formed with high stereoselectivity. 

Aldol condensation with aldehydes and ketones gives hydroxy compounds (265 — 267) which usually spontaneously lose water (by a reverse Michael addition) to give unsaturated compounds (268). 

Diethyl 2-oxobutanedioate undergoes an aldol condensation with aldehydes to yield the substituted dione which after hydrolysis and decarboxylation affords the 2,6-dicarboxylic acid (Scheme 16). The cyclization of this acid provides a useful synthesis of 4//-pyran-2,6-dicarboxylic acids (74ACS(B)517). It is unfortunate that attempted decarboxylation to the simple pyran fails, resulting in extensive decomposition. An earlier report (710PP243) summarizes previous work in this area and gives preparative details for the dicarboxylic acids. 

Support-bound quinazolin-2,4-diones can be N-alkylated, either with alkyl halides under basic conditions or with aliphatic alcohols by means of the Mitsunobu reaction (Entries 12-14, Table 15.29). The methyl group of a 2-methylquinazolin-4-one is sufficiently acidic to undergo aldol condensations with aldehydes [343]. Aminations of chloroquinazolines are discussed in Section 10.1.2. 

Conjugate addition-aldol reactions. A novel synthesis of a-substituted a,(3-enones involves conjugate addition of 1 to an a,p-enone the resulting 0-phenyl-selenoboron enolate undergoes aldol condensation with aldehydes. The adduct on oxidative elimination furnishes unsaturated p-hydroxy ketones.1 Example ... 

Aldol condensation. With aldehydes, successful with either acid or base catalysis. m With ketones, conditions (strong acid or strong base catalysis) under which dehydration occurs are usually used to shift equilibrium toward the product.. ... 

Further transformations of the intermediate alkenyloxydialkylboranes (46), as shown in Scheme 10, include aqueous hydrolysis to the homologated aldehydes or ketones 30 electrophilic additions to afford the corresponding a-dialkylaminomethyl aldehydes and ketones (47),31 and a-halogenated (48)32 or a-arylselenylated aldehydes or ketones (49) 33 transmetallation-alkylation to afford a-substituted aldehydes or ketones (50) 34 and aldol condensations with aldehydes (51).35 These reagents offer the equivalent of the tandem 1,4-conjugate addition-electrophile-trapping protocol. A prototypical prosta-... 

Enanantioselective aldol reactions. Divalent tin enolates of aldehydes and aryl ketones generated with tin(II) triflate undergo aldol condensation with aldehydes to form aldols.2 The reaction is highly enantioselective if conducted in the presence of chiral diamines derived from (S)-proline, such as l.3... 

Aldol reactions of methyl ketones. The optically active 1,3-oxazolidine (1) formed from a methyl ketone and ( — (-norephedrine aftir conversion to the tin(ll) enolate undergoes enantioselective aldol condensation with aldehydes. The enantioselectivity is partic-... 

Anions formed from group 6 and manganese Fischer carbene complexes undergo aldol condensations with aldehydes and ketones. Allylic carbenes exclusively react in the y position with aldehydes affording dienyl-substituted carbenes. For alkoxy-substituted carbenes, the presence of an excess Lewis acid see Lewis Acids Bases), such as boron trifluoride etherate, titanium tetrachloride, or tin tetrachloride is required for the reaction to proceed in reasonable yield. The initial aldol product can be isolated without elimination (Scheme 12). ... 

Sitro-aldol reaction fl-amino alcohols. Primary nitro compounds form silyl nitronates (1) when treated in sequence with LDA (THF, -78°) and then a silylating reagent. These silyl nitronates undergo aldol condensation with aldehydes in the presence of tetra-n -butylammonium fluoride (there is no reaction in the absence of the catalyst). The products 2 are reduced to /3-amino alcohols (3) in good yield by lithium aluminum hydride (equation 1). Secondary nitroalkanes undergo the same reaction sequence, but the silyl nitronates are less stable and are obtained in only... 

Enolates obtained from conjugate addition of either homocuprates or copper-catalyzed Grignard reagents undergo aldol condensation with aldehydes in the presence of ZnCl2 to give stereoisomeric mixtures of aldol products A ... 

Enoxysilacyclobutanes. These compounds can be prepared by Wurtz coupling of 3-chloropropyltrichlorosiIane with Mg in ether. Introduction of one alkyl group is accomplished by reaction with an organolithium reagent, and the silyl chloride can then be used for the formation of silyl enol ethers. Such 0-silyl ketene acetals are extremely reactive in aldol condensations with aldehydes without catalysts. The reaction is syn-selective. An asymmetric version uses silyl ketene acetals bearing a chiral Si-alkoxy (e.g., 8-phenylmenthoxy) group instead of an alkyl substituent. 

Aldol condensations with aldehydes and ketones proceed smoothly at temperatures below — 60 °C and usually give high yields [3]. 

The pyrimidine system shows side-chain reactivity typical of azines. CH3 groups at the 2-, 4- or 6-position undergo aldol condensations (with aldehydes in the presence of Lewis acids) or Claisen condensations (with esters in the presence of strong bases) with marked preference at C-4, e.g. ... 

Silyl nitronates undergo aldol condensation with aldehydes in the presence of a catalytic amount of anhydrous TBAF to form highly diastereoselective erythro products, which can be elaborated to give synthetically useful 1,2-amino alcohols (eq 22). A one-pot procedure has been developed for direct aldol condensation of nitroalkanes with aldehydes by using TBAF trihydrate with Triethylamine and tert-ButyldimethylchlorosilaneP It appears that silyl nitronates are not reactive intermediates in this case, and the reactions proceed by a different mechanism... 

Lewis acid promoted reactions of silicon enolates, /.e., silyl enol ethers and ketene silyl acetals with various electrophiles have yielded a wealth of novel and selective synthetic methods. This combination of reagents has been used in the past to perform such reactions as aldol-condensations with aldehydes and acetals, imine-condensations, conjugate additions to a,P-enones, alkylations, electrophilic aminations, and Diels-Alder/cyclocondensations. Our own interest in this field has involved the use of titanium tetrachloride to promote the reaction of ketene silyl acetals with non-activated imines as an efficient route to P-lactams. This reaction has been applied to the asymmetric synthesis of P-lactams via a chiral imine-titanium tetrachloride template. We have also found that both ketene silyl acetals and vinylketene silyl acetals oxidativelly dimerize or cross-couple, in the presence of titanium tetrachloride to conveniently yield various diesters . Our present study concerns reactions of vinylketene silyl acetals with non-activated imines and vinylimines promoted by titanium and zirconium tetrachlorides. 

Silyl enol ethers have been known to undergo aldol condensations with aldehydes in the presence of Lewis acids [260, 261]. When a silyl group occupies the... 

---