Aldol condensation model

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. 

The issue of stereochemistry, on the other hand, is more ambiguous. A priori, an aldol condensation between compounds 3 and 4 could proceed with little or no selectivity for a particular aldol dia-stereoisomer. For the desired C-7 epimer (compound 2) to be produced preferentially, the crucial aldol condensation between compounds 3 and 4 would have to exhibit Cram-Felkin-Anh selectivity22 23 (see 3 + 4 - 2, Scheme 9). In light of observations made during the course of Kishi s lasalocid A synthesis,12 there was good reason to believe that the preferred stereochemical course for the projected aldol reaction between intermediates 3 and 4 would be consistent with a Cram-Felkin-Anh model. Thus, on the basis of the lasalocid A precedent, it was anticipated that compound 2 would emerge as the major product from an aldol coupling of intermediates 3 and 4. 

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. 

Detailed investigations indicate that the enolization process (LDA, THF) affords enolates 37 and 38 with at/east 97% (Z)-stereoselection. Related observations have recently been reported on the stereoselective enolization of dialkylthioamides (38). In this latter study, the Ireland-Claisen strategy (34) was employed to assign enolate geometry. Table 10 summarizes the enolization stereo selection that has been observed for both esters and amides with LDA. Complementary kinetic enolization ratios for ketonic substrates are included in Table 7. Recent studies on the role of base structure and solvent are now beginning to appear in the literature (39,40), and the Ireland enolization model for lithium amide bases has been widely accepted, A tabular survey of the influence of the ester moiety (ORj) on a range of aldol condensations via the lithium enolates is provided in Table 11 (eq. [24]). Enolate ratios for some of the condensations illustrated may be found in Table 10. It is apparent from these data that ( )-enolates derived from alkyl propionates (Rj = CH3, t-C4H9) exhibit low aldol stereoselectivity. In contrast, the enolates derived from alkoxyalkyl esters (Rj = CHjOR ) exhibit 10 1 threo diastereo-... 

The first chapter in this volume is a particularly timely one given the recent surge of activity in natural product synthesis based upon stereocontrolled Aldol Condensations. D. A. Evans, one of the principal protagonists in this effort, and his associates, J. V. Nelson and T. R. Taber, have surveyed the several modem variants of the Aldol Condensation and discuss models to rationalize the experimental results, particularly with respect to stereochemistry, in a chapter entitled Stereoselective Aldol Condensations. The authors examine Aldol diastereoselection under thermodynamic and kinetic control as well as enantioselection in Aldol Condensations involving chiral reactants. 

Most enolates can exist as two stereoisomers. Also, most aldol condensation products formed from a ketone enolate and an aldehyde can have two diastereomeric structures. These are designated as syn and anti. The cyclic-transition-state model provides a basis for understanding the relationship between enolate geometry and the stereochemistry of the aldol product. 

Shu and co-workers (35) identified 2-isobutyl-3,5-diisopropylpyridine, 2-pentyl-3,5-dimethylpyridine, and its dihydro derivative obtained under similar conditions. Sultan (29) confirmed the presence of 3,5-diethyl-2-propylpyridine in a model system consisting of butyraldehyde and ammonium sulfide. Our proposed mechanism of their formation (20) consists of three steps 1) aldol condensation of the starting aldehydes to 2,4-alkadienals, 2) imine formation with ammonia, and 3) subsequent cyclization and oxidation to corresponding pyridines. An alternate mechanism, suggested by Shu and co-workers (33), takes into consideration the isolated dihydro derivatives. Hwang and co-workers described another dihydro derivative (19, R = Bu, R = R" = Pr, R= H) (37). 

Aldol reactions of magnesium enolates are frequently more diastereoselective than the corresponding reactions of lithium enolates. The aldol condensation proceeds via a cyclic transition state in agreement with the Zimmerman-Traxler chelated model . 

The study of Mateos and Fuente Blanco on the aldol condensation between magnesium enolate of 2,2,6-trimethylcyclohexanone and 3-furaldehyde is in accord with the preceding stereochemical results. Application to the preparation of model compounds of limonoid, such as pyroangelensolide, is described (equation 84). 

Conseqnently, the magnesinm chelate 71 can also react as a nucleophilic donor in aldol reactions. In the chemistry involving magnesium chelates, these two aspects model their mode of action as nucleophilic partners in aldol condensations. This is exemplified in aldol condensations of y-diketones . Thus, sodium hydroxyde catalyzed cyclization of diketone 73 to give a mixtnre of 3,5,5-trimethyl-cyclopent-2-enone 74 and 3,4,4-trimethyl-cyclopent-2-enone 75 in a 2.2/1 isomeric ratio (equation 100). When treated with magnesinm methanolate, the insertion of a a-methoxy carbonyl group as control element, as in 76, allows the formation of a chelated magnesium enolate 77, and the major prodnct is now mainly the aldol 78. This latter treated with aqueous NaOH provides the trimethylcyclopent-2-enones 74 and 75 in a 1/49 ratio. 

Kraft cooking of dihydrodehydrodiconiferyl alcohol (I) as a model for the phenylcoumaran system shown to be present in native lignin (/, 2), resulted (3, 13) in the opening of the hydrofuran ring and splitting ofF of formaldehyde, probably through a reverse aldol condensation of an intermediate quinonemethide (77, 18). The resulting p,0 -dihydroxystilbene... 

Vapor-phase nitration of paraffin hydrocarbons, particularly propane, can be brought about by uncatalyzed contact between a large excess of hydrocarbon and nitric acid vapor at around 400°C, followed by quenching. A multiplicity of nitrated and oxidized products results from nitrating propane nitromethane, nitroethane, nitropropanes, and carbon dioxide all appear, but yields of useful products are fair. Materials of construction must be very oxidation-resistant and are usually of ceramic-lined steel. The nitroparaffins have found limited use as fuels for race cars, submarines, and model airplanes. Their reduction products, the amines, and other hydroxyl compounds resulting from aldol condensations have made a great many new aliphatic syntheses possible because of their ready reactivity. 

It is demonstrated that a great many flavor compounds are formed in both model systems. On the other hand, phenylalanine formed by aldol condensations some special aroma products. Furthermore, the generation of thermal aroma compounds depend on the pH, the sugar/amino acid ratio and the temperature. 

The neutral and cationic [Pd(II)NCN] pincer-containing dendritic assemblies 14 and 15 have been used as Lewis acid catalysts in the aldol condensation of benzaldehyde and methyl isocyanoacetate. These showed conversions, turnover frequencies and cis/trans ratios of the oxazoline products that were essentially identical to those of the monomeric model complex applied in the same reaction. 

Phenylacetaldehyde and its aldol condensation product with creatinine are very important intermediates in the formation of PhIP. The corresponding Schiff base could not be found in model systems or in fried meat.310... 

Ans. Five-coordinated square-pyramidal [CuL(BnOCH2CHO)] [L = (S,S)-bis (phenyloxazolinyl) pyridine]. A model catalytic intermediate in Cu-L-based asymmetric aldol condensation reactions (see D. A. Evans et al., J. Am. Chem. Soc. 121, 669-85 7559-73 and 7582-94, 1999). 

The transformations themselves involved reactions of ketoacids with a pyridoxamine unit, either covalently attached to the polymer or reversibly bound to the hydrophobic core (29), which converted the ketoacids to amino acids, and the pyridoxamine was converted to a pyridoxal unit either covalently attached to the polymer or reversibly dissociated from the polymer. This reaction was modeled directly on the transamination process observed in natural enzymes. However, the second part of a full transamination in nature is the reaction of the pyridoxal with a different amino acid, which runs the transamination backward to form the pyridoxamine again while converting the new amino acid into its corresponding ketoacid. We found that such a process was too slow in our biomimetic system and could not compete with the rapid aldol condensation of the ketoacids with the pyridoxal. 

It seems likely that the reaction proceeds through a prototropic ene reaction pathway, a pathway that has not been previously recognized as a possible mechanism in the Mukaiyama aldol condensation. Usually an acyclic antiperiplanar transition-state model has been used to explain the formation of the syn diastereomer from either ( )- or (Z)-silyl enol ethers [91]. The cyclic ene mechanism, however, now provides another rationale for the syn diastereoselectivity irrespective of enol silyl ether geometry (Sch. 32). 

Kajimoto, T, Liu, K K-C, Pederson, R L, Zhong, Z, Ichikawa, Y, Porco, J A, Wong, C-H, Enzyme-catalyzed aldol condensation for asymmetric synthesis of azasugars synthesis, evaluation, and modeling of glycosidase inhibitors, J. Am. Chem. Soc., 113, 6187-6196, 1991. 

In an effort to circumvent this difficulty, a situation encompassing an intramolecular aldol condensation was envisioned. To this end, the model methoxypropio-phenone (88) was acylated with malonyl monoacid chloride mono ethyl ester, and... 

Experimental studies in our laboratory on the aldol condensation were carried out in a lin. CD column using Ambelite IRA-900 anion-exchange resin housed in fiberglass bags. The reboiler duty, which affected the flow rates, was found to play an important role in the selectivity to DAA. A rate-based three-phase CD model was developed, which accurately predicts the yield and selectivity obtained under steady-state and transient conditions. Model predictions and experimental data indicate that the production of DAA is external mass transfer controlled while the production of MO is kinetically controlled. The external mass transfer resistance was caused by the fiberglass bags. Recently,... 

Huang, C. Yang, L. Ng, F.T.T. Rempel, G.L. Application of catalytic distillation for the aldol condensation of acetone a rate-based model in simulating the catalytic distillation performance under steady-state operations. Chem. Eng. Sci. 1998, 53 (19), 3489-3499. 

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