Intermolecular aldehydes

Mennen MS, Gipson JD, Kim YR, Miller SJ (2005a) Thiazolylalanine-derived catalysts for enantioselective intermolecular aldehyde-imine cross-couplings. J Am Chem Soc 127 1654... 

The thiazolium-catalyzed addition of an aldehyde-derived acyl anion with a Michael acceptor (Stetter reaction) is a well-known synthetic tool leading to the synthesis of highly funtionalized products. Recent developments in this area include the thiazolylalanine-derived catalyst 191 for asymmetric intramolecular Stetter reaction of a,P-unsaturated esters <05CC195>. However, these cyclizations proceed only in moderate enantioselectivities and yields even under optimized conditions. Thiazolium salt 191 has been used successfully for enantioselective intermolecular aldehyde-imine cross coupling reactions <05JA1654>. Treatment of tosylamides 194 with aryl aldehydes in the presence of 15 mol% of 191 and 2... 

Intermolecular aldehyde/alkyne reductive couplings involving PBua and EtaB have been explored on a variety of systems ranging from simple to quite complex [22]. Aromatic alkynes are generally the best substrates, whereas more substrate generahty is observed on the aldehyde component (Scheme 7). In the course of examining asymmetric couplings (see Sect. 2.2.4), a variety of different monodentate phosphines were examined [23]. 

Demir et have reported the first, catalytic, intermolecular aldehyde-ketone (103) coupling with acyl phosphonate (102). The cyanide ion catalyzed formation of acyl anion from acyl phosphonates, which next reacted with activated carbonyl compounds to furnish products (104) in 41-95% yields after phosphorylation of the resulting oxyanion (Scheme 23). 

Compared with the aldehyde-ketone cross-benzoin reaction, intermolecular aldehyde-aldehyde coupling reactions are much more challenging, as the addition of the second aldehyde means the number of possible products is quadrupled. 

P. Lehwald, R. Michael, R. Caroline, L. Hung-Wen, M. Michael, Enantioselective intermolecular aldehyde-ketone cross-coupling through an enzymatic carboligation reaction, Angew. Chem. Int. 49 (2010) 2389-2392. 

An example of an intermolecular aldol type condensation, which works only under acidic catalysis is the Knoevenagel condensation of a sterically hindered aldehyde group in a formyl-porphyrin with a malonic ester (J.-H. Fuhrhop, 1976). Self-condensations of the components do not occur, because the ester groups of malonic esters are not electrophilic enough, and because the porphyrin-carboxaldehyde cannot form enolates. 

The selective intermolecular addition of two different ketones or aldehydes can sometimes be achieved without protection of the enol, because different carbonyl compounds behave differently. For example, attempts to condense acetaldehyde with benzophenone fail. Only self-condensation of acetaldehyde is observed, because the carbonyl group of benzophenone is not sufficiently electrophilic. With acetone instead of benzophenone only fi-hydroxyketones are formed in good yield, if the aldehyde is slowly added to the basic ketone solution. Aldols are not produced. This result can be generalized in the following way aldehydes have more reactive carbonyl groups than ketones, but enolates from ketones have a more nucleophilic carbon atom than enolates from aldehydes (G. Wittig, 1968). 

Enamines derived from ketones are allylated[79]. The intramolecular asymmetric allylation (chirality transfer) of cyclohexanone via its 5-proline ally ester enamine 120 proceeds to give o-allylcyclohexanone (121) with 98% ee[80,8l]. Low ee was observed in intermolecular allylation. Similarly, the asymmetric allylation of imines and hydrazones of aldehydes and ketones has been carried out[82]. 

Aldehydes can undergo an intermolecular oxidation—reduction (Canni22aro reaction) in the presence of base to produce an alcohol and a carboxyUc acid salt. Any aldehyde is capable of participating in such a reaction, however, it is more common for those containing no protons on the alpha carbon, for example... 

The general features of this elegant and efficient synthesis are illustrated, in retrosynthetic format, in Scheme 4. Asteltoxin s structure presents several options for retrosynthetic simplification. Disassembly of asteltoxin in the manner illustrated in Scheme 4 furnishes intermediates 2-4. In the synthetic direction, attack on the aldehyde carbonyl in 2 by anion 3 (or its synthetic equivalent) would be expected to afford a secondary alcohol. After acid-catalyzed skeletal reorganization, the aldehydic function that terminates the doubly unsaturated side chain could then serve as the electrophile for an intermolecular aldol condensation with a-pyrone 4. Subsequent dehydration of the aldol adduct would then afford asteltoxin (1). 

The elaboration of the polyunsaturated side chain of asteltoxin requires a stereoselective coupling of aldehyde 2 with a suitable synthetic equivalent for the anion of 4-formyl-1,3-butadiene (see intermediate 3 in Scheme 4). Acid-induced skeletal reorganization of the aldehyde addition product, followed by an intermolecular... 

It is worth pointing out that the stereochemistry of intermediate 147 at C-9 and C-10 is inconsequential since both positions will eventually bear trigonal carbonyl groups in the final product. The synthetic problem is thus significantly simplified by virtue of the fact that any or all C9-C10 diol stereoisomers could be utilized. A particularly attractive means for the construction of the C9-C10 bond and the requisite C8-C10 functionality in 147 is revealed by the disconnection shown in Scheme 41. It was anticipated that the venerable intermolecular aldol reaction could be relied upon to accomplish the union of aldehyde 150 and methyl glycolate (151) through a bond between carbons 9 and 10. 

Carboximide 160, the C35-C42 fragment, can be traced retro-synthetically to phosphonate 169 and aldehyde 170. In the synthetic direction, the C35-C36 bond in 160 could be constructed by an intermolecular Horner-Wadsworth-Emmons (HWE)70 coupling of intermediates 169 and 170. Reduction of the unsaturated coupling product and exchange of silyl protecting groups would then furnish compound 160. 

Aldehyde 170 is to serve as the electrophile in an intermolecular Homer-Wadsworth-Emmons (HWE) reaction70 with enantiomeri-cally pure phosphonate 169. Compounds 169 and 170 can in fact be joined efficiently under the mild reaction conditions shown in Scheme 50 to give a,/ -unsaturated imide 206 (96 % yield). The use... 

The stereoselectivity of these intermolecular reactions between 1-alkoxyallylstannanes and aldehydes induced by boron trifluoride-diethyl ether complex is consistent with an open-chain, antiperiplanar transition state. However, for intramolecular reactions, this transition state is inaccessible, and either (Z)-.yyn-products are formed, possibly from a synclinal process105, or 1,3-isomerization competes113. Remote substituents can influence the stereoselectivity of the intramolecular reaction114. 

Photolysis of chromium alkoxycarbene complexes with aldehydes in the presence of Lewis acids produced /J-lactones [83]. Intermolecular reactions were slow, low-yielding, and nonstereoselective, while intramolecular reactions were more efficient (Eqs. 19 and 20). Subsequent studies showed that amines, particularly DMAP, could also catalyze this process (Table 13) [84], resulting in reasonable yields and diastereoselectivity in intermolecular cases. 

Reaction of vinyliminophosphoranes with aldehydes gives betaines which undergo either intra- or intermolecular cyclization to give pyridines 1 or dihydropyridines 2 in moderate yields <95TL(36)8283, 96JOC(61)8094>. 

Attempted intermolecular cross-benzoin reactions typically generate a thermodynamically controlled mixture of products [50], although several groups including Enders [51], Suzuki [52] and You [53] have utilised catalysts 116-118 for the intramolecular crossed benzoin of keto-aldehydes (Scheme 12.22). 

Rovis and co-workers have also extended the intermolecular Stetter reaction to inclnde nitroaUcenes as the electrophilic component. Fluorinated triazolinm precatalyst 155 was effective in catalysing the reaction of a variety of heteroaromatic aldehydes 153 with nitroalkenes 154 to generate P-nitroketones in excellent yields and enantioselectivities. The authors propose that stereoelectronically induced conformational effects on the catalyst skeleton are key to the high selectivities observed with flnorinated catalyst 155 (Scheme 12.33) [69],... 

The values of x = 0.5 and = 1 for the kinetic orders in acetone [1] and aldehyde [2] are not trae kinetic orders for this reaction. Rather, these values represent the power-law compromise for a catalytic reaction with a more complex catalytic rate law that corresponds to the proposed steady-state catalytic cycle shown in Scheme 50.3. In the generally accepted mechanism for the intermolecular direct aldol reaction, proline reacts with the ketone substrate to form an enamine, which then attacks the aldehyde substrate." A reaction exhibiting saturation kinetics in [1] and rate-limiting addition of [2] can show apparent power law kinetics with both x and y exhibiting orders between zero and one. 

Intermolecular allylation of aldehydes with 1 -trialkylsilyl-1,3-dienes 22 in the presence of a stoichiometric amount of triethylsilane and a catalytic amount of Ni(cod)2 and PPI13 shows novel regio- and stereoselectivity (Scheme 6) [20-22], When a toluene solution of a 1-silyl-1,3-diene and an aldehyde is refluxed in the presence of trialkylsilane under the catalysis of Ni(cod)2 and PPh3, ( )-allylsilane (E)-23 is obtained exclusively. On the other hand, when the reaction is carried out in THF upon heating at 50 °C as... 

The synthetic utility and generality of the reaction is demonstrated by an intramolecular/intermolecular double allylation using an oo-dienyl aldehyde 38 as a probe. The internal diene terminus selectively undergoes nucleophilic allylation intramolecularly to form a cyclopentanol structure. The terminal... 

A rationale for the cz s-selective cyclization for the intramolecular homoal-lylation of oo-dienyl aldehyde 64 is illustrated in Scheme 16. The scenario is essentially the same as the one proposed for the intermolecular reaction, and a Ni(0) species undergoes oxidative addition upon the diene and the aldehyde moieties through a conformation placing the aldehyde substituent and the diene anti to each other. An intermediate 66 undergoes (>-II elimination and czs-reductive elimination of the thus-formed Ni - H complex to produce 65. 

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