Aldol proline-catalyzed

The investigation of the driving forces and robnstness of proline-catalyzed aldol reaction is performed by ntilizing the methodology of reaction progress kinetic analysis. 

A DFT study found a corresponding TS to be the lowest energy.167 This study also points to the importance of the solvent, DMSO, in stabilizing the charge buildup that occurs. A further computational study analyzed the stereoselectivity of the proline-catalyzed aldol addition reactions of cyclohexanone with acetaldehyde, isobu-tyraldehyde, and benzaldehyde on the basis of a similar TS.168 Another study, which explored the role of proline in intramolecular aldol reactions, is discussed in the next section.169... 

Visual models, additional information and exercises on Proline-Catalyzed Aldol Reactions can be found in the Digital Resource available at Springer.com/carey-sundberg. 

The detailed mechanism of this enantioselective transformation remains under investigation.178 It is known that the acidic carboxylic group is crucial, and the cyclization is believed to occur via the enamine derived from the catalyst and the exocyclic ketone. A computational study suggested that the proton transfer occurs through a TS very similar to that described for the proline-catalyzed aldol reaction (see page 132).179... 

The TS proposed for these proline-catalyzed reactions is very similar to that for the proline-catalyzed aldol addition (see p. 132). In the case of imines, however, the aldehyde substituent is directed toward the enamine double bond because of the dominant steric effect of the (V-aryl substituent. This leads to formation of syn isomers, whereas the aldol reaction leads to anti isomers. This is the TS found to be the most stable by B3LYP/6-31G computations.199 The proton transfer is essentially complete at the TS. As with the aldol addition TS, the enamine is oriented anti to the proline carboxy group in the most stable TS. 

As shown in Scheme 53, L-proline-catalyzed asymmetric aldol reaction between 3-methylbutanal and acetone was used by List for the synthesis of (S)-34 [79]. 

The development of enamine catalysis parallels that of iminium catalysis (Scheme 3) [24], Like iminium catalysis, the concept took a long time to mature, and also required a key discovery - the discovery of intermolecular proline-catalyzed aldol reactions by List and coworkers in 2000 [23] - to set the field in motion. The timeline of historical developments of enamine catalysis is outlined in Scheme 4. 

Discovery of the proline-catalyzed intramolecular aldol reaction - the Hajos-Parrish-... 

List, Barbas and Lerner discover the intermolecular proline-catalyzed aldol reaction... 

Gryko and coworkers studied the influence of an acid additive in the aldol reaction catalyzed by a proline derivative equipped with an existing hydrogen bonding... 

Typical starting materials, catalysts, and products of the enamine-catalyzed aldol reaction are summarized in Scheme 17. In proline-catalyzed aldol reactions, enantioselectivities are good to excellent with selected cyclic ketones, such as cyclohexanone and 4-thianone, but generally lower with acetone. Hindered aldehyde acceptors, such as isobutyraldehyde and pivalaldehyde, afford high enantioselectivities even with acetone. In general, the reactions are anti selective, but there are aheady a number of examples of syn selective enamine aldol processes [200, 201] (Schemes 17 and 18, see below). However, syn selective aldol reactions are still rare, especially with cychc ketones. 

Scheme 22 Proline-catalyzed aldol reaction in the synthesis of caUipeltoside C...

In similar works, a number of [AMIM] -containing ionic liquids were evaluated for proline-catalyzed aldol reactions. The catalyst in the ionic liquid with Cl as the anion was characterized by a higher reaction rate than the ionic liquids with the anions BF)T and PFg", but elimination products affected the yields in the latter ionic liquids (149). 

Fluoral hydrate and hemiacetals are industrial products. They are stable liquids that are easy to handle, and they react as fluoral itself in many reactions. Thus, in the presence of Lewis acids, they react in Friedel-Crafts reactions. They also react very well with organometallics (indium and zinc derivatives) and with silyl enol ethers.Proline-catalyzed direct asymmetric aldol reaction of fluoral ethyl hemiac-etal with ketones produced jS-hydroxy-jS-trifluoromethylated ketones with good to excellent diastereo- (up to 96% de) and enantioselectivities. With imine reagents, the reaction proceeds without Lewis acid activation. The use of chiral imines affords the corresponding 8-hydroxy ketones with a 60-80% de (Figure 2.49). ° ... 

The best chemical and optical yields in the above reactions are obtained by using (S)- or (R)-proline. Some 19-norsteroids are prepared on an industrial scale from products of intramolecular aldol additions catalyzed by (S)-proline 68). 

Enantioselective aldol reactions also can be used to create arrays of stereogenic centers. Two elegant ot-amino anion approaches have recently been published. Fujie Tanaka and Carlos F. Barbas III of the Scripps Institute, La Jolla, have shown (Org. Lett. 2004,6,3541) that L-proline catalyzes the addition of the aldehyde 6 to other aldehydes with high enantio- and diastereocontroJ. Keiji Maruoka of Kyoto University has developed (J. Am. Chem. Soc. 2004,126,9685) a chiral phase transfer catalyst that mediates the addition of the ester 9 to aldehydes, again with high enantio- and diastcrcocontrol. 

It is true that highly enantioselective reactions are possible with proline in the asymmetric a-amination of aldehydes by azodicarboxylates and in a-oxidation with nitrosobenzene. However, good rather than excellent yields and enantioselectivities are more common in intermolecular Michael and aldol reactions. Moreover, the high catalyst loadings required for proline-catalyzed aldol reactions (up to 30%), and low TOFs (from hours to days to achieve a good conversion, even at a high catalyst... 

Hence, if the proline-catalyzed aldol reaction between acetone and 4-nitrobenzal-dehyde in DM SO is carried out using 5 mol% proline, decarboxylation occurs and [3 + 2] cycloaddition between the resulting ylide and benzaldehyde gives a 1,3-oxazolidinone as the maj or side product [98]. Therefore, it is important that if catalyst loadings are to be reduced, either the carboxylic acid should be unable to decarbox-ylate (e.g. Appendix 7.B, Entries 12 [97, 98], 35 [99]) or else must be replaced by an isostere [101, 102] (e.g. Appendix 7.B, Entries 7 [103, 104], 8-10 [105], 11 [106], 28 [107]). Alternatively, the relative rate of the aldol reaction can be increased in order to minimize the concentration of iminium ion in solution and remove it from equilibrium before decarboxylation can take place. 

Figure 7.13 1,1 -Bi-2-naphthol (BINOL) can dramatically enhance proline-catalyzed aldol reactions.

List gave the first examples of the proline-catalyzed direct asymmetric three-component Mannich reactions of ketones, aldehydes, and amines (Scheme 14) [35], This was the first organocatalytic asymmetric Mannich reaction. These reactions do not require enolate equivalents or preformed imine equivalent. Both a-substituted and a-unsubstituted aldehydes gave the corresponding p-amino ketones 40 in good to excellent yield and with enantiomeric excesses up to 91%. The aldol addition and condensation products were observed as side products in this reaction. The application of their reaction to the highly enantioselective synthesis of 1,2-amino alcohols was also presented [36]. A plausible mechanism of the proline-catalyzed three-component Mannich reaction is shown in Fig. 2. The ketone reacts with proline to give an enamine 41. In a second pre-equilib-... 

Surprisingly, the catalytic potential of proline (1) in asymmetric aldol reactions was not explored further until recently. List et al. reported pioneering studies in 2000 on intermolecular aldol reactions [14, 15]. For example, acetone can be added to a variety of aldehydes, affording the corresponding aldols in excellent yields and enantiomeric purity. The example of iso-butyraldehyde as acceptor is shown in Scheme 1.4. In this example, the product aldol 13 was obtained in 97% isolated yield and with 96% ee [14, 15]. The remarkable chemo- and enantioselectivity observed by List et al. triggered massive further research activity in proline-catalyzed aldol, Mannich, Michael, and related reactions. In the same year, MacMillan et al. reported that the phenylalanine-derived secondary amine 5 catalyzes the Diels-Alder reaction of a,/>-un saturated aldehydes with enantioselectivity up to 94% (Scheme 1.4) [16]. This initial report by MacMillan et al. was followed by numerous further applications of the catalyst 5 and related secondary amines. 

It is worthy of note that - similarly to the proline catalyzed aldol reaction - the Mannich reaction can also be extended to an enantio- and diastereoselective process in which two stereogenic centers are formed in one step, although using non-chiral starting materials (Scheme 5.16) [22, 23, 26, 27, 28]. In these reactions substituted acetone or acetaldehyde derivatives, rather than acetone, serve as donor. In contrast with the anti diastereoselectivity observed for the aldol reaction (Section 6.2.1.2), the proline-catalyzed Mannich reaction furnishes products with syn diastereoselectivity [23]. A proline-derived catalyst, which led to the formation of anti Mannich products has, however, been found by the Barbas group [29]. 

The concept The possibility of using a simple organic molecule from the chiral pool to act like an enzyme for the catalytic intermolecular aldol reaction has recently been reported by the List and Barbas groups [69-71]. L-proline, (S)-37, was chosen as the simple unmodified catalytic molecule from the chiral pool . The proline-catalyzed reaction of acetone with an aldehyde, 36, at room temperature resulted in the formation of the desired aldol products 38 in satisfactory to very good yields and with enantioselectivity up to >99% ee (Scheme 6.18) [69, 70a],... 

The substrate range scope and limitations Promising prospects for synthetic applications of the proline-catalyzed aldol reaction in the future were opened up by experimental studies of the range of substrates by the List [69, 70a, 73] and Barbas [71] groups. The reaction proceeds well when aromatic aldehydes are used as starting materials - enantioselectivity is 60 to 77% ee and yields are up to 94% (Scheme 6.19) [69, 70], The direct L-proline-catalyzed aldol reaction proceeds very efficiently when isobutyraldehyde is used as substrate - the product, (R)-38d, has been obtained in very good yield (97%) and with high enantioselectivity (96% ee). 

Extensions of the proline-catalyzed aldol reaction Recently interesting extensions of the enantioselective proline-catalyzed aldol reaction have been reported. An enan-tioselective proline-catalyzed self-aldolization of acetaldehyde was observed by Barbas and co-workers (Scheme 6.21) [77]. Starting from acetaldehyde, the valuable building block 5 -h ydroxy-( 2E)-hexcnal, (S)-43, was obtained as a product with up to 90% ee, although the yield did not exceed 13%, irrespective of the reaction conditions. This reaction requires a small amount catalyst only (ca. 2.5 mol%). 

Another interesting extension of the proline-catalyzed aldol reaction was recently reported by the Jorgensen group (Scheme 6.22), who used keto malonates as acceptors and a-substituted acetone derivatives as donors [78]. In contrast with the classic proline-catalyzed reaction discussed above, in this reaction the stereogenic center is formed at the nucleophilic carbon atom of the donor. The resulting products of type 46 are formed in good yields, from 88% to 94%, and with enantioselectivity between 84 and 90% ee (Scheme 6.22). The reactions were performed with a catalytic amount of 50 mol% [78],... 

The Kotsuki group investigated the effect of high-pressure conditions on the direct proline-catalyzed aldol reaction [79a], a process which, interestingly, does not require use of DMSO as co-solvent. Use of high-pressure conditions led to suppression of the formation of undesired dehydrated by-product and enhancement of the yield. Study of the substrate range with a range of aldehydes and ketones revealed that enantioselectivity was usually comparable with that obtained from experiments at atmospheric pressure. Additionally, proline catalyzed aldol reactions in ionic liquids, preferably l-butyl-3-methylimidazolium hexafluorophosphate, have been successfully carried out [79b,c]. 

The mechanism similarities to enzymatic processes In principle, L-proline acts as an enzyme mimic of type I metal-free aldolases. Similar to this enzyme, L-proline catalyzes the direct aldol reaction according to an enamine mechanism. Thus, for the first time a mimic of type I aldolases has been found. The close similarity of... 

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