Aldol with 1,4-addition

Conjugation of the newly formed double bond with the carbonyl group stabilizes the a p unsaturated aldehyde provides the driving force for the dehydration and controls Its regioselectivity Dehydration can be effected by heating the aldol with acid or base Normally if the a p unsaturated aldehyde is the desired product all that is done is to carry out the base catalyzed aldol addition reaction at elevated temperature Under these conditions once the aldol addition product is formed it rapidly loses water to form the a p unsaturated aldehyde... 

Kelkar and McCarthy (1995) proposed another method to use the feedforward experiments to develop a kinetic model in a CSTR. An initial experimental design is augmented in a stepwise manner with additional experiments until a satisfactory model is developed. For augmenting data, experiments are selected in a way to increase the determinant of the correlation matrix. The method is demonstrated on kinetic model development for the aldol condensation of acetone over a mixed oxide catalyst. 

Addition of metalated, enantiomerically pure a-sulfinyl dimethylhydrazones (e.g., 9) to racemic a-chiral aldehydes 10 proceeds with good to excellent diastereo- and enantioselectivi-ty12. Diastereomeric ratios increase with increasing steric demand of the acetaldehyde substituent R1 compared to the methyl group, and each diastereomer is obtained with high enantiomeric excess. In the aldol-lype addition to 2-phenylpropanal, one of the four possible stereoisomers is formed selectively. The relative (syn) and absolute (R.R) configuration is in accord with Cram s and related rules as well as H-NMR data of closely related compounds. 

The major difference, when compared with simple diastereoselection in aldol-type additions, is the E- and Z-geometrical isomers of the Michael acceptor. Model transition state G shows one of the orientations of the enantiofaces of an (A)-enolate with a (Z)-enone. These additions, again, result in the same. vyn/an/i-adducts, as in the case of an (A)-enone, but the substituent interactions will be different. 

Another anionic/radical one-pot sequence was developed by Guindon and coworkers for the stereoselective synthesis of substituted pentanoates 2-718 (Scheme 2.158) [365]. Such structures are found in polyketides and are, therefore, of great interest. The described approach offers a diastereoselective access to all four possible stereoisomers of 2-718 through a Mukaiyama aldol/radical defunctionalization sequence starting from 2-716 and 2-717 with addition of Bu3SnH after completion of the first step. 

Intermolecular cross aldolization of metallo-aldehyde enolates typically suffers from polyaldolization, product dehydration and competitive Tishchenko-type processes [32]. While such cross-aldolizations have been achieved through amine catalysis and the use of aldehyde-derived enol silanes [33], the use of aldehyde enolates in this capacity is otherwise undeveloped. Under hydrogenation conditions, acrolein and crotonaldehyde serve as metallo-aldehyde enolate precursors, participating in selective cross-aldolization with a-ketoaldehydes [24c]. The resulting/ -hydroxy-y-ketoaldehydes are highly unstable, but may be trapped in situ through the addition of methanolic hydrazine to afford 3,5-disubstituted pyridazines (Table 22.4). 

Abstract Aldehydes obtained from olefins under hydroformylation conditions can be converted to more complex reaction products in one-pot reaction sequences. These involve heterofunctionalization of aldehydes to form acetals, aminals, imines and enamines, including reduction products of the latter in an overall hydroaminomethylation. Furthermore, numerous conversions of oxo aldehydes with additional C.C-bond formation are conceivable such as aldol reactions, allylations, carbonyl olefinations, ene reactions and electrophilic aromatic substitutions, including Fischer indole syntheses. 

The carbene-bound alkyl groups are acidic pX [(CO)5Cr=C(OMe)Me in H2O] 12.3 and can be easily deprotonated and alkylated [45,211,212] or acylated [213] (Figure 2.16). Stereoselective aldol-type additions can be realized with the aid of Fischer-type alkylcarbene complexes [214-216]. In these reactions the metallic fragment can either play the role of a bulky carbonyl group or stabilize a given conformation of the substrate by chelate formation [216,217]. 

As with many aldol reactions, addition is usually followed by elimination of water, generating a conjugated system with the cyano or nitro group. The presence of extended conjugation through aromatic substituents enhances this process. 

A different behavior is exhibited by naphthalene-1,8-dicarbocal-dehyde (73). No m-naphthane derivatives are obtained on reaction with nitromethane, nitroethane or other methylene components. The basic medium, required for aldol type additions, causes the dialdehyde to undergo Cannizzaro reaction to the naphthopyranon (74) via an intramolecular 1,5-hydride shift, which is sterically favoured by the peri-position of the two aldehyde functions 28). 

Yamamoto and coworkers described a highly enantioselective asymmetric domino 0-nitroso aldol-conjugate addition seqnence using cyclic enones 221 and aromatic nitroso compounds 222 as depicted in Scheme 36 [346]. A related reaction with imines was also reported by Cdrdova and coworkers (Scheme 37) [228]. 

It seems unlikely that this reaction could occur in quite the same way as in the laboratoryaldol reaction, because the enolate anion of the donor molecule (dihydroxypropanone) is not expected to be formed in significant amount of the pH of living cell. In fact there is strong evidence that the enzyme behaves as amino (ENH2) compound and reacts with carbonyl group of dihydroxy propanone to form an imine. This implies that the imine form of dihydroxy propanone is a key intermediate in the overall aldol-type addition. 

Ethylhexanol is usually produced by subsequent aldolization of butyraldehyde produced in the oxo reaction followed by hydrogenation of the intermediate unsaturated aldehyde.89 In Esso s Aldox process, however, in situ aldol condensation is effected by suitable promoters.11 Magnesium ethoxide and soluble zinc compounds are recommended to promote controlled aldolization during the oxo reaction. The Shell variant uses potassium hydroxide. Serious disadvantages (mixed aldolization with the branched aldehyde, problems associated with recycling of the additives), however, prevented wider use of the Aldox process. 

Substituted, 2,3-disubstituted, and 2,3-annulated thiophenes can be prepared by reactions of ketone enolates with carbonodithioic acid O-ethyl 5-(2-oxoethyl)ester. Hydrolysis of the resulting aldols, intramolecular addition of thiol group to the carbonyl group, and elimination of two molecules of water lead to the thiophenes (116) (Scheme 38) (92HCA907). 

There are certain difficulties in achieving this type of aldol reaction. First, alkali-induced ester hydrolysis would compete with addition. Second, a Claisen condensation of the ester might intervene, and third, the ester anion is a stronger base than the enolate anions of either aldehydes or ketones, which means reaction could be defeated by proton transfer of the type... 

This reaction is quite special in that it is an aldol-type addition in which a thioester is the donor (nucleophile) and a keto acid is the acceptor (electrophile). From the discussion in Section 18-8E, you will see that reactions of this kind involving an ester as the donor and an aldehyde or ketone as the acceptor can be achieved in the laboratory only under rather special conditions. For the thioester to function as a nucleophile at the a carbon under the restraints imposed by having the reaction occur at the physiological pH, the catalyzing enzyme almost certainly must promote formation of the enol form of the thioester. The enol then could add to the ketone carbonyl with the assistance of a basic group on the enzyme. This kind of catalysis by enzymes is discussed in Section 25-9C. 

This obviously is unlikely for the given example because there is no reason for cyanide ion to have anything other than an exactly equal chance of attacking above or below the plane of the ethanal molecule, producing equal numbers of molecules of the enantiomers, 21 and 22. However, when a chiral center is created through reaction with a dissymmetric (chiral) reagent, we should not expect an exactly 1 1 mixture of the two possible isomers. For example, in an aldol-type addition (Section 18-8E) of a chiral ester to a pro-chiral ketone the two configurations at the new chiral center in the products 23 and 24 are not equally favored. That is to say, asymmetric synthesis is achieved by the influence of one chiral center (R ) on the development of the second ... 

It is not difficult to visualize how sugars such as ribose may be formed. Methanal is known to be converted by bases through a series of aldol-type additions to a mixture of sugarlike molecules called formose. Formation of racemic ribose along with its stereoisomers could occur as follows ... 

Many phenols undergo aldol-like addition reactions with carbonyl compounds in the presence of acids or bases. Thus benzenol reacts with methanal under mild alkaline conditions to form (4-hydroxyphenyl)methanol ... 

As to the mechanism of benzoin formation, cyanide ion adds to the aldehyde to form 12. This anion is in equilibrium with 13, wherein the negative charge can be delocalized over the phenyl and nitrile groups. A subsequent aldol-type addition of 13 to the carbonyl carbon of a second aldehyde molecule gives the addition product 14, and loss of HCN from 14 leads to the benzoin ... 

Ab initio MO methods have been used to predict the stereochemistry of aldol-type addition of boron enolates to imines, with due allowance for the degree and type of substitution, and the geometry (E or Z) of both the enolate and imine reactants.39 Only two important transition states were identified—both cyclic—one chair-like and the other boat-like. The results are compared with the stereo selections reported in various experimental methodologies. 

Selective alkylation of the y position of a,/3-unsaturated esters, aldehydes, or ketones can be achieved if a sterically demanding Lewis acid is used to coordinate to the carbonyl group and inhibit a-alkylation by steric shielding [123, 125, 126] (Scheme 5.11). This method not only results in high regioselectivity but also enables highly stereoselective aldol-type additions to be performed in good yields, even with sensitive substrates, such as a,/3-unsaturated aldehydes [126]. Thus, when two dia-stereotopic y positions are available, the addition of a bulky aluminum phenolate leads to the clean formation of the Z-alkene (second and third examples, Scheme 5.11). 

Substituted prolines - typically with additional chiral centre(s) in the substituent - have been found to be much more enantioselective than proline itself in aldol reactions.113... 

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