Aldehyde substrates

Isolated carbonyls always give epoxides from the Corey-Chaykovsky reaction. Take the aldehyde substrate as an example. Spiro epoxide 30 was produced from the reaction of trisnorsqualene aldehyde 28 (R20 represents the polyene side-chain with 20 carbons) with substituted sulfur ylide 29, prepared in situ from cyclopropyldiphenylsulfonium tetrafluoroborate and KOH. " For the epoxidation of ketones, the Corey-Chaykovsky reaction works well for diaryl- (31), arylalkyl- (32), ... 

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. 

Three types of synthases catalyze the addition of phosphoenolpyruvate (PEP) to aldoses or the corresponding terminal phosphate esters. By concurrent release of inorganic phosphate from the preformed enolate nucleophile, the additions are essentially irreversible. None of the enzymes are yet commercially available and little data are available oil the individual specificities for the aldehydic substrates. A bacterial NeuAc synthase (EC 4.1.3.19) has been used for the microscale synthesis of A -acetylncuraminic acid from Af-acetyl-D-mannosamine31 and its 9-azido analog from 2-acetamido-6-azido-2,6-dideoxy-D-mannose32. 

Extensive studies have indicated that only pyruvate is acceptable as the NeuA donor substrate, with the exception of fluoropyruvate [49], but that the enzyme displays a fairly broad tolerance for stereochemically related aldehyde substrates as acceptor alternatives, such as a number of sugars and their derivatives larger or equal to pentoses [36,48,50,51]. Permissible variations include replacement of the natural D-manno configured substrate (4) with derivatives containing modifications such as epimerization, substitution, or deletion at positions C-2, -4, or -6 [16,27]. Epimeriza-tion at C-2, however, is restricted to small polar substituents owing to strongly... 

Transfer hydrogenation of aldehydes with isopropanol without addition of external base has been achieved using the electronically and coordinatively unsaturated Os complex 43 as catalyst. High turnover frequencies have been observed with aldehyde substrates, however the catalyst was very poor for the hydrogenation of ketones. The stoichiometric conversion of 43 to the spectroscopically identifiable in solution ketone complex 45, via the non-isolable complex 44 (Scheme 2.4), provides evidence for two steps of the operating mechanism (alkoxide exchange, p-hydride elimination to form ketone hydride complex) of the transfer hydrogenation reaction [43]. 

The best ee s (67-70%) were obtained with cyclohexanediol, and this catalyst system was also studied with other aldehyde substrates (Scheme 5-32). 

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. 

Polar polyoxyethylene-polyoxypropylene (POEPOP) resin, deriva-tized with a 4-hydroxymethyl phenoxy linker, was used as a solid support for lanthanide triflate-catalyzed Mukaiyama-type solid-phase aldol reactions.282 The use of an aqueous solvent was found to be crucial. The reactions on an N-terminal peptide aldehyde substrate proceeded in very high yields. 

Influence of THP/Ru ratio and solvent systems. Many empirical studies were carried out on variation of conversions with the THP Ru ratio, defined as R, which was varied from 0.5 to 6.0. Invariably, in the H20/buffer standard conditions (and other solvent systems - see below), conversions for any selected reaction time decreased when R > 3, but this was not usually the optimum ratio. For the ketone 10b, the maximum conversion was at R = 3, but for ketone 10c and the alkene substrates such as lb and 3a, R was closer to 1 for 6c, the aldehyde substrate, optimum conversion was at R 2. The unknown nature of the catalytic species present in solution makes any discussion of these data meaningless. 

Gijsen, H.J.M. and Wong, C.-H. (1994) Unprecedented asymmetric aldol reactions with three aldehyde substrates catalyzed by 2-deoxyribose-5-phosphate aldolase. Journal of the American Chemical Society, 116 (18), 8422-8423. 

Pozzi and co-workers have also reported a fluorous soluble cobalt complex, which is active in the aerobic epoxidation of alkenes in a fluorous biphasic system (FBS).[50] The ligand used in this complex was a fluorinated tetraarylporphyrin, with eight perfluorooctyl chains shown in Figure 6.13. The cobalt complex was dissolved in perfluorohexane and added to a solution of the alkene with 2-methylpropanal (aldehyde substrate — 2 1) at room temperature. 

We thank N.S.E.R.C. for research grants, Johnson,Matthey and Co., Ltd. for a loan of ruthenium, and Professor E. Piers for several of the aldehyde substrates. 

In the reaction of (R,R)-tartrate allyl-boronate with aldehydes, Si attack of the nucleophile on the carbonyl group has been observed, while Re attack occurs in (S, S )-tartrate allyl-boronate reactions. Thus, an (S )-alcohol is produced preferentially when an (R,R)-allyl reagent is used, and the (R)-product can be obtained from an (S.Sj-reagent. assuming that the R substituent in the aldehyde substrate takes priority over the allyl group to be transferred. In fact, no exceptions to this generalization have yet been found in over 40 well-characterized cases where the tartrate auxiliary controls the stereochemical outcome of the allyl or crotyl transfer.72... 

Systematic studies of the reactions of tartrate allyl-boronates with a series of chiral and achiral alkoxy-substituted aldehydes show that conformationally unrestricted a- and /f-alkoxy aldehyde substrates have a significant negative impact on the stereoselectivity of asymmetric allyl-boration. In contrast, con-... 

The Meerwein-Ponndorf-Verley reaction is a classic method for ketone/ aldehyde carbonyl group reduction, which involves at least 1 equivalent of aluminum alkoxide as a promoter. In this reaction, the hydrogen is transferred from isopropanol to the ketone/aldehyde substrate, so the reaction can also be referred to as a transfer hydrogenation reaction. 

Fluorine-containing compounds can also be synthesized via enantioselective Reformatsky reaction using bromo-difluoroacetate as the nucleophile and chiral amino alcohol as the chiral-inducing agent.86 As shown in Scheme 8-41, 1 equivalent of benzaldehyde is treated with 3 equivalents of 111 in the presence of 2 equivalents of 113, providing a,a-difluoro-/ -hydroxy ester 112 at 61% yield with 84% ee. Poor results are observed for aliphatic aldehyde substrates. For example, product 116 is obtained in only 46% ee. 

Addition of the indium reagent derived from the foregoing (P)-allenylstannane to /8-benzyloxy-a-methylpropanal as the aldehyde substrate at low temperature afforded a 70 30 mixture of anti,anti and anti,syn adducts (Eq. 9.141). The improved dia-stereoselectivity in this case can be attributed to substrate control, reflecting the chelating ability of an OBn versus an ODPS group. The lower temperature may also account for the improved diasteroselectivity. 

For Aldehyde Substrates H0(CH2)40H (1 equiv.) NaOAc (1 equiv.) PhMe (2 M)... 

In a series of important papers, MacMillan described the alkylation of electron rich aromatic and heteroaromatic nucleophiles with a,P-unsaturated aldehydes, using catalysts based upon the imidazoUdinone scaffold, further establishing the concept and utility of iminium ion activation. In line with the cycloaddition processes described above, the sense of asymmetric induction of these reactions can be rationalised through selective (F)-iminium ion formation between the catalyst and the a,P-unsaturated aldehyde substrate, with the benzyl arm of the catalyst blocking one diastereoface of the reactive Jt-system towards nucleophilic attack (Fig. 3). 

J0rgensen [111] and Vicario [112] independently described the conjugate addition of both triazole and tetrazole based nucleophiles to a,P-unsaturated aldehyde substrates as an alternative method for C-N bond formation. These reactions were catalysed by the diarylprolinol and imidazolidinone scaffolds with equal efficiency showing the complementarity and efficacy of both these catalyst architectures. In addition, Jprgensen has also shown succinimide to be an effective Michael donor (see Sect. 2.3.5 Scheme 49 for further details) [113]. 

This enzyme [EC 1.2.1.10] catalyzes the oxidation of acetaldehyde in the presence of NAD+ and coenzyme A to form acetyl-CoA -i- NADH + H+. Other aldehyde substrates include glycolaldehyde, propanal, and bu-tanal. 

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