Exchange aldol

Oxime exchange Aldol exchange Nitroaldol exchange... 

Early patents indicated that because water inhibits the aldol condensation mechanism, it was necessary to dry recycle acetone to less than 1% water (139—142). More recent reports demonstrate DAA production from waste acetone containing 10—50% water (143), and enhanced DAA production over anion-exchange resins using acetone feeds that contain 3—10% water (144,145). 

Class (2) reactions are performed in the presence of dilute to concentrated aqueous sodium hydroxide, powdered potassium hydroxide, or, at elevated temperatures, soHd potassium carbonate, depending on the acidity of the substrate. Alkylations are possible in the presence of concentrated NaOH and a PT catalyst for substrates with conventional pX values up to - 23. This includes many C—H acidic compounds such as fiuorene, phenylacetylene, simple ketones, phenylacetonittile. Furthermore, alkylations of N—H, O—H, S—H, and P—H bonds, and ambident anions are weU known. Other basic phase-transfer reactions are hydrolyses, saponifications, isomerizations, H/D exchange, Michael-type additions, aldol, Darzens, and similar... 

The 2-methyl group of 2-methyl-3T/-azepines, e.g. 11, is surprisingly reactive and undergoes rapid deuterium exchange and, in the presence of base, aldol condensation with areneal-dehydes to yield styryl derivatives, e.g. 12.76108... 

The charged group introduced into products by the aldol donors (phosphate, carboxylate) facilitates product isolation and purification by salt precipitation and ion exchange techniques. Although many aldehydic substrates of interest for organic synthesis have low water solubility, at present only limited data is available on the stability of aldolases in organic cosolvents, thus in individual cases the optimal conditions must be chosen carefully. 

Reaction between Two Molecules of the Same Aldehyde. The equilibrium lies far to the right, and the reaction is quite feasible. Many aldehydes have been converted to aldols and/or their dehydration products in this manner. The most effective catalysts are basic ion-exchange resins. Of course, the aldehyde must possess an a hydrogen. 

The spiroindolinobenzopyran 2 is a classical example of spiropyran and is easily prepared by the condensation of l,3,3-trimethyl-2-methyleneindo-line (Fischer s base) and salicylaldehyde in anhydrous ethanol or benzene (Scheme 2).ia The nucleophilic attack of Fischer s base on the carbonyl group (like an enamine) gives an aldol product, which undergoes ring closure followed by dehydration. This condensation is reversible therefore, an exchange of the salicylaldehyde component of spiropyran with a different salicylaldehyde is possible. For example, when a solution of spiropyran 2 (Scheme 2) was refluxed with 3,5-dinitro-substituted salicylaldehyde, the open form of 6,8-dinitro-BIPS was obtained.2... 

Domino Michael/aldol processes, which are initiated by the addition of a halide to an enone or enal, have found wide attention. They are valuable building blocks, as they can be easily converted into a variety of extended aldols via subsequent SN2 reactions with nucleophiles or a halide/metal exchange. As an example, a-haloalkyl- 3-hy-droxy ketones such as 2-76 have been obtained in very good yields and selectivities by reaction of enones 2-71 with nBu4NX in the presence of an aldehyde 2-74 and TiCl4as described by the group of Shinokubo and Oshima (Scheme 2.16) [24]. 

As with the above pyrrolidine, proline-type chiral auxiliaries also show different behaviors toward zirconium or lithium enolate mediated aldol reactions. Evans found that lithium enolates derived from prolinol amides exhibit excellent diastereofacial selectivities in alkylation reactions (see Section 2.2.32), while the lithium enolates of proline amides are unsuccessful in aldol condensations. Effective chiral reagents were zirconium enolates, which can be obtained from the corresponding lithium enolates via metal exchange with Cp2ZrCl2. For example, excellent levels of asymmetric induction in the aldol process with synj anti selectivity of 96-98% and diastereofacial selectivity of 50-200 116a can be achieved in the Zr-enolate-mediated aldol reaction (see Scheme 3-10). 

LA represents Lewis acid in the catalyst, and M represents Bren sled base. In Scheme 8-49, Bronsted base functionality in the hetero-bimetalic chiral catalyst I can deprotonate a ketone to produce the corresponding enolate II, while at the same time the Lewis acid functionality activates an aldehyde to give intermediate III. Intramolecular aldol reaction then proceeds in a chelation-controlled manner to give //-keto metal alkoxide IV. Proton exchange between the metal alkoxide moiety and an aromatic hydroxy proton or an a-proton of a ketone leads to the production of an optically active aldol product and the regeneration of the catalyst I, thus finishing the catalytic cycle. 

Judging from these findings, the mechanism of Lewis acid catalysis in water (for example, aldol reactions of aldehydes with silyl enol ethers) can be assumed to be as follows. When metal compounds are added to water, the metals dissodate and hydration occurs immediatdy. At this stage, the intramolecular and intermolecular exchange reactions of water molecules frequently occur. If an aldehyde exists in the system, there is a chance that it will coordinate to the metal cations instead of the water molecules and the aldehyde is then activated. A silyl enol ether attacks this adivated aldehyde to produce the aldol adduct. According to this mechanism, it is expected that many Lewis acid-catalyzed reactions should be successful in aqueous solutions. Although the precise activity as Lewis acids in aqueous media cannot be predicted quantitatively... 

These retro-Aldol and -Michael reactions can, obviously, follow an isomerization of the aldose to the corresponding ketose, leading thereby to different Aldol fragments or retro-Michael products. Keto-enol exchange as well as the retro-... 

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... 

An exceptionally mild procedure for the cross-condensation of aldimines and enolsilanes has been described (eq. [67]) (80). This titanium tetrachloride-mediated reaction is predicated on the previous analogies provided by Mukaiyama for related aldol condensations (73a). Depending on aldimine structure and reaction time, either -lactams or their penultimate amino esters may be isolated from the reaction. The authors postulate that these reactions are proceeding via titanium enolates derived from ligand exchange by... 

This radical cyclization strategy was utilized for the synthesis of the smaller fragment silyl ether 54 as well (Scheme 8). Evans aldol reaction of the boron eno-late derived from ent-32 with aldehyde 33, samarium(III)-mediated imide methyl ester conversion, and protecting group exchange led to tosylate 51. Elaboration of 51 to ketone 53 was achieved under the conditions used for construction of the second tetrahydrofuran moiety of 49 from 46. A highly diastereoselective reduc-... 

Cyclohexenones 34 also undergo a highly diastereoselective dihydroxylation to give cii-diols 39 (Scheme 11).22 These diol amides are converted to hydroxylactones 40 by an acid-catalyzed process involving retro aldol-realdolization prior to transacylation. The enantiomers of hydroxylactones 40 are obtained from iodolactones 35 by iodide exchange with 2,2,6,6-tetramethylpiperidin-l-yloxy free radical (TEMPO) followed by reductive cleavage of the TEMPO derivative with Zn in ElOAc. The enantiomeric purity of the hydroxylactones prepared by either route is 95-98% ee. 

OH—on the adjacent (/ -) carbon atom. The possibility of such an elimination may displace the equilibrium over to the right in a number of simple aldol additions, where it would otherwise lie far over to the left. It is important to remember, however, that the overall process aldol addition + dehydration is reversible, i.e. (88) 4= (96), and that a -unsaturaled carbonyl compounds are thus cleaved by base under suitable conditions. It is also pertinent that (96) is still an aldehyde and can undergo further carbanion addition, followed by dehydration, and so on. This is how low molecular weight polymers are produced on heating simple aliphatic aldehydes with aqueous NaOH to stop at the aldol, the best catalysts are basic ion-exchange resins. 

Wang et al. investigated the catalytic behavior of cation exchange resin supported lanthanide(III) salts of the general structure (31) (Scheme 4.15), prepared from Dowex, Amberlite, Amberlyst and other resins [99]. It turned out that Am-berlyst XN-1010 and Amberlyst 15 complexed best with lanthanides(III). Thus, among others, electrophilic substitution of indole with hexanal and Mukayiama-type aldol reaction of benzaldehyde with ketene silyl acetal proceeded in excellent yields under catalytic conditions (Scheme 4.16). 

Amberlyst 15 DRY, a sulfonic cation exchange resin with a large surface area, was found to catalyze the imino aldol reaction of imines with ketene silyl acetals to provide racemic y9-amino esters in yields up to 99% [104]. 

Subsequent ion exchange of the metal cation with the quaternary ammonium ion catalyst provides a lipophilic ion pair (step 2), which either reacts with the requisite alkyl electrophile at the interface (step 3) or is partitioned into the electrophile-containing organic phase, whereupon alkylation occurs and the catalyst is reconstituted. Enantioselective PTC has found apphcation in a vast number of chemical transformations, including alkylations, conjugate additions, aldol reactions, oxidations, reductions, and C-X bond formations." ... 

Marhwald reported that ligand exchange of Ti(rac-BINOLate)(Of-Bu)2 with optically active a-hydroxy acids presents an unexpected and novel approach to enantio-selective direct aldol reactions of aldehydes and ketones (Scheme 12.19). The aldol products have been isolated with a high degree of syn diastereoselectivity. High enantioselectivities have been observed when using simple optically pure a-hydroxy acids. 

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