Aldol condensation aldehyde reaction with enolates

Recently, Trost et al. reported the vanadium-catalyzed addition reaction of 2,3-allenols [180], Here the oxygen in 401 served as an intramolecular nucleophile to attack the center carbon atom of allene to form a vanadium enolate 402. Aldol condensation of 402 with an aldehyde afforded (2-hydroxy)alkyl vinylic ketones 403. 

Other structural features may influence the stereoselectivity of aldol condensations. One such factor is chelation by a donor substituent.68 69 Several /i-alkoxyaldchydcs show a preference for vyw-aldol products on reaction with Z-enolates. A chelated transition state can account for the observed stereochemistry.70 The chelated aldehyde is most easily... 

In the aldol condensation, an enolate anion acts as a carbon nucleophile and adds to a carbonyl group to form a new carbon-carbon bond. Thus, the a-carbon of one aldehyde molecule becomes bonded to the carbonyl carbon of another aldehyde molecule to form an aldol (a 3-hydroxyaldehyde). In the mixed aldol condensation, the reactant with an a-hydrogen supplies the enolate anion, and the other reactant, usually without an a-hydrogen, supplies the carbonyl group to which the enolate ion adds. The aldol reaction is used commercially and also occurs in nature. 

Carbonyl activation and deactivation.1 Aldehydes, but not ketones, undergo aldol condensation with silyl enol ethers at —78° in the presence of dibutyltin bistriflate. In contrast, the dimethyl acetals of ketones, but not of aldehydes, can undergo this condensation (Mukaiyama reaction) with silyl enol ethers at -78° with almost complete discrimination, which is not observed with the usual Lewis-acid catalysts. Thus dibutyltin bistriflate activates aldehydes, but deactivates acetals of... 

In 1992 Ghosh and co-workers provided the first example of the utility of rigid cis-1 -amino-2-indanol-derived oxazolidinone 36 as the chiral auxiliary in the asymmetric. vv//-aldol reaction.60-61 Aldol condensation of the boron enolate of 37 with various aldehydes proceeded with complete diastereofacial selectivity. Effective removal and recovery of the chiral auxiliary was carried out under mild hydrolysis conditions (Scheme 24.6). As both enantiomers of the chiral auxiliary were readily available, both enantiomers of the. yyn-aldol could be prepared with equal asymmetric induction. 

Stereoselective aldol condensation. Heathcock and Buse have previously employed 2-methyl-2-trimethylsiloxy-3-pentanone (1) in a highly stereoselective route to 3-hydroxy-2-methylcarboxylic acids (8, 295). Aldol condensation of the lithium enolate derived from 1 with a chiral aldehyde yields ery//iro-aldols, which are cleaved with periodic acid to -hydroxy carboxylic acids. However, when 1 is condensed with a chiral aldehyde such as 2, two eryt/iro-products (3 and 4) are produced. Heathcock and co-workers now report that the 1,2-diastereoselectivity of these aldol condensations can be enhanced by use of the ketone 5. Reaction of racemic 5 with racemic aldehyde 2 furnishes a single (racemic) adduct 6. 

The synthesis of methyl ketone 281 began with the reaction between the tetra-substituted allylborane 279 and 2,3-0-isopropylidene-D-glyceraldehyde 48. The resulting homoallylic alcohol 280, obtained in 73% yield and excellent selectivity (exact ratio not defined) [231], was converted in two steps to the methyl ketone 281. Aldol condensation between the lithium enolate of 281 and aldehyde 278 (structure shown in Scheme 11-12) gave, after protection of the initial adduct, the Felkin diastereomer 282 as the only reported product in 54% yield. This adduct... 

Aldol condensation of the tin enolates with aldehydes often takes place spontaneously at room temperature, but Lewis acids (e.g. TiCL, BF3.OEt2, ZnCl2, CuCl2) or PdCl2[(o-C6H4)3P]2 can be used as catalysts, and enantioselective addition can be achieved with an (/ )-BINAP-AgOTf catalyst.101 The stereoselectivity is dependent on the reaction conditions, and the high threo selectivity at low temperature is ascribed to the presence of a cyclic transition state 14-20.104... 

Aldol and Michael reactions. (C6F5)jB is an air-stable and water-tolerant catalyst for these reactions. Thus the aldol condensation between a silyl enol ether and an aldehyde can be conducted at -78°C. Aqueous HCHO can be used as electrophile. The analogous condensation with imines provides a route to j8-amino esters. ... 

When an aldehyde or ketone and its enolate are both present in solution they can react with each other in what is called an aldol condensation. Such reactions are an important part of this chapter. The aldol condensation will be discussed in Sections 20.3 and 20.4. 

The aldol condensation of the lithium enolate of methyl 3,3-dimethylbutanoate with aromatic aldehydes gives (the reaction is carried out by mixing freshly ground mixture of the lithium enolate and powdered aldehyde in vacuum for 3 days at room temperature) a 8 92 mixture of the syn and anti products in 70% yield (Scheme 12). 

The enols and enolates are capable of undergoing many reactions at the a position, among them exchange, racemization, halogenation, alkylation, addition to ketones or aldehydes, and addition to esters. The aldol condensation involves reaction of the enolate, a strong nucleophile, with the electrophilic carbonyl compound, or of the less strongly nucleophilic enol with the powerful electrophile, the protonated carbonyl. 

The decarboxylation of allyl /3-keto carboxylates generates 7r-allylpalladium enolates. Aldol condensation and Michael addition are typical reactions for metal enolates. Actually Pd enolates undergo intramolecular aldol condensation and Michael addition. When an aldehyde group is present in the allyl fi-keto ester 738, intramolecular aldol condensation takes place yielding the cyclic aldol 739 as a main product[463]. At the same time, the diketone 740 is formed as a minor product by /3-eIimination. This is Pd-catalyzed aldol condensation under neutral conditions. The reaction proceeds even in the presence of water, showing that the Pd enolate is not decomposed with water. The spiro-aldol 742 is obtained from 741. Allyl acetates with other EWGs such as allyl malonate, cyanoacetate 743, and sulfonylacetate undergo similar aldol-type cycliza-tions[464]. 

In practice this reaction is difficult to carry out with simple aldehydes and ketones because aldol condensation competes with alkylation Furthermore it is not always possi ble to limit the reaction to the introduction of a single alkyl group The most successful alkylation procedures use p diketones as starting materials Because they are relatively acidic p diketones can be converted quantitatively to their enolate ions by weak bases and do not self condense Ideally the alkyl halide should be a methyl or primary alkyl halide... 

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)... 

An alternate scheme for preparing these compounds starts with a prefabricated pyrimidone ring. Aldol condensation of that compound (95), which contains an eneamide function, with pyridine-3-aldehyde (80), gives the product 96. Catalytic hydrogenation gives the product of 1,4 reduction. The resulting pyrimidinedione, of course exists in the usual tautomeric keto (97a) and enol (97b) forms. Reaction with phosphorus oxyxchloride leads to the chloro derivative 98. Displacement with methoxide gives 99. Reaction of this last intermediate with the furylalkylamine derivative 92 leads to the H-2 blocker lupitidine (100) [22]. 

The mixed Claisen condensation of two different esters is similar to the mixed aldol condensation of two different aldehydes or ketones (Section 23.5). Mixed Claisen reactions are successful only when one of the two ester components has no a hydrogens and thus can t form an enolate ion. For example, ethyl benzoate and ethyl formate can t form enolate ions and thus can t serve as donors. They can, however, act as the electrophilic acceptor components in reactions with other ester anions to give mixed /3-keto ester products. 

A key step in the synthesis of the spiroketal subunit is the convergent union of intermediates 8 and 9 through an Evans asymmetric aldol reaction (see Scheme 2). Coupling of aldehyde 9 with the boron enolate derived from imide 8 through an asymmetric aldol condensation is followed by transamination with an excess of aluminum amide reagent to afford intermediate 38 in an overall yield of 85 % (see Scheme 7). During the course of the asymmetric aldol condensation... 

The coupling of a secondary alcohol 1 with a primary alcohol 2 is achieved by the temporary removal of from each substrate which generates the ketone 3 and aldehyde 4 intermediates. A crossed aldol condensation occurs under the reaction conditions by the enolate derived from ketone 3 undergoing nucleophilic addition... 

The intermediate enolate or enol ether from the initial reduction of an enone may be alkylated in situ (Eq. 281).455 / -Substituted cyclopentenones may be asymmetrically reduced and alkylated459 (see section on asymmetric reductions of enones). Enolates may also be trapped with an aldehyde in a reductive aldol condensation of an enone with an aldehyde,455 permitting a regioselective aldol condensation to be carried out as shown in Eq. 282.455 This class of reductive aldol condensation reactions can also occur in a cyclic manner (Eq. 283).460... 

In the reductive aldol condensation of an ,/J-unsaturated ester and an aldehyde shown in Eq. 291, the initial step is believed to be the addition of an in situ formed rhodium hydride to the a,/Tunsaturated ester, followed by reaction of the resulting rhodium enolate with the aldehyde.470 The reaction has been carried out both inter-470 and intramolecularly471,472 as well as in an asymmetric fashion (Eq. 291). 

Silyloxy)alkenes were first reported by Mukaiyama as the requisite latent enolate equivalent to react with aldehydes in the presence of Lewis acid activators. This process is now referred to as the Mukaiyama aldol reaction (Scheme 3-12). In the presence of Lewis acid, anti-aldol condensation products can be obtained in most cases via the reaction of aldehydes and silyl ketene acetals generated from propionates under kinetic control. 

Our second approach involved condensation of the lithium enolate of acetate 32 with aldehyde 28. In the event, the aldol reaction afforded an 85 % yield of a ca. 5 1 mixture of C3 epimers with the desired diastereomer (35) comprising the major product. 

Three tactical approaches were surveyed in the evolution of our program. As outlined in Scheme 2.7, initially the aldol reaction (Path A) was performed direcdy between aldehyde 63 and the dianion derived from tricarbonyl 58. In this way, it was indeed possible to generate the Z-lithium enolate of 58 as shown in Scheme 2.7 which underwent successful aldol condensation. However, the resultant C7 P-hydroxyl functionality tended to cyclize to the C3 carbonyl group, thereby affording a rather unmanageable mixture of hydroxy ketone 59a and lactol 59b products. Lac-tol formation could be reversed following treatment of the crude aldol product under the conditions shown (Scheme 2.7) however, under these conditions an inseparable 4 1 mixture of diastereomeric products, 60 (a or b) 61 (a or b) [30], was obtained. This avenue was further impeded when it became apparent that neither the acetate nor TES groups were compatible with the remainder of the synthesis. 

Traditional models for diastereoface selectivity were first advanced by Cram and later by Felkin for predicting the stereochemical outcome of aldol reactions occurring between an enolate and a chiral aldehyde. [37] During our investigations directed toward a practical synthesis of dEpoB, we were pleased to discover an unanticipated bias in the relative diastereoface selectivity observed in the aldol condensation between the Z-lithium enolate B and aldehyde C, Scheme 2.6. The aldol reaction proceeds with the expected simple diastereoselectivity with the major product displaying the C6-C7 syn relationship shown in Scheme 2.7 (by ul addition) however, the C7-C8 relationship of the principal product was anti (by Ik addition). [38] Thus, the observed symanti relationship between C6-C7 C7-C8 in the aldol reaction between the Z-lithium enolate of 62 and aldehyde 63 was wholly unanticipated. These fortuitous results prompted us to investigate the cause for this unanticipated but fortunate occurrence. 

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... 

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