Aldehydes bifunctional

The synthesis of a large number of y-pyrones and y-pyranols from enamines has been brought about through the use of a wide variety of bifunctional molecules. These molecules include phenolic aldehydes (126,127), phenolic Mannich bases (128), ketal esters (129), and diketene (120-132). All of these molecules have an electrophilic carbonyl group and a nucleophilic oxygen center in relative 1,4 positions. This is illustrated by the reaction between salicylaldehyde (101) and the morpholine enamine of cyclohexanone to give pyranol 102 in a quantitative yield (127). 

Paquatte, O., Fried, A., and Tu, S. C. (1988). Delineation of bacterial luciferase aldehyde site by bifunctional labeling reagents. Arch. Biochem. 264 392-399. 

By Far the simplest bifunctional crosslinking agent is formaldehyde. Although structurally a mono-functional aldehyde compound, formaldehyde reacts with proteins via a two-step reaction... 

In real systems (hydrocarbon-02-catalyst), various oxidation products, such as alcohols, aldehydes, ketones, bifunctional compounds, are formed in the course of oxidation. Many of them readily react with ion-oxidants in oxidative reactions. Therefore, radicals are generated via several routes in the developed oxidative process, and the ratio of rates of these processes changes with the development of the process [5], The products of hydrocarbon oxidation interact with the catalyst and change the ligand sphere around the transition metal ion. This phenomenon was studied for the decomposition of sec-decyl hydroperoxide to free radicals catalyzed by cupric stearate in the presence of alcohol, ketone, and carbon acid [70-74], The addition of all these compounds was found to lower the effective rate constant of catalytic hydroperoxide decomposition. The experimental data are in agreement with the following scheme of the parallel equilibrium reactions with the formation of Cu-hydroperoxide complexes with a lower activity. 

The enantioselective isomerization of bifunctional Cs-isoprenoid allylamines to optically active bifunctional aldehydes was developed by using Rh(l)+/( )-BIPHEMP as the catalyst (Scheme 2).17 These aldehydes are useful optically active bifunctional building blocks for isoprenoid homologation. 

Another example is the asymmetric cyanosilylation of aldehydes catalyzed by bifunctional catalyst 131.100 Compound 131 contains aluminum, the central metal, acting as a Lewis acid, and group X, acting as a Lewis base. The asymmetric cyanosilylation, as shown in Scheme 8-50, proceeds under the outlined... 

Y. Hamashima, D. Sawada, M. Kanai, M Shibasaki A New Bifunctional Asymmetric Catalysis An Effident Catalytic Asymmetric Cyanosilylation of Aldehydes, J. Am Chem Soc 1999,121, 2641-2642. 

Trost s group reported direct catalytic enantioselective aldol reaction of unmodified ketones using dinuclear Zn complex 21 [Eq. (13.10)]. This reaction is noteworthy because products from linear aliphatic aldehydes were also obtained in reasonable chemical yields and enantioselectivity, in addition to secondary and tertiary alkyl-substituted aldehydes. Primary alkyl-substituted aldehydes are normally problematic substrates for direct aldol reaction because self-aldol condensation of the aldehydes complicates the reaction. Bifunctional Zn catalysis 22 was proposed, in which one Zn atom acts as a Lewis acid to activate an aldehyde and the other Zn-alkoxide acts as a Bronsted base to generate a Zn-enolate. The... 

Okamura and Nakatani [65] revealed that the cycloaddition of 3-hydroxy-2-py-rone 107 with electron deficient dienophiles such as simple a,p-unsaturated aldehydes form the endo adduct under base catalysis. The reaction proceeds under NEtj, but demonstrates superior selectivity with Cinchona alkaloids. More recently, Deng et al. [66], through use of modified Cinchona alkaloids, expanded the dienophile pool in the Diels-Alder reaction of 3-hydroxy-2-pyrone 107 with a,p-unsaturated ketones. The mechanistic insight reveals that the bifunctional Cinchona alkaloid catalyst, via multiple hydrogen bonding, raises the HOMO of the 2-pyrone while lowering the LUMO of the dienophile with simultaneous stereocontrol over the substrates (Scheme 22). 

Volatiles and cuticular extracts of the wheat stem sawfly, Cephus cinc-tus Norton (Hymenoptera Cephidae), were analyzed. The bifunctional 9-acetyloxynonanal gave the strongest EAD response. Additional EAD-active compounds included 13-acetyloxytridecanal, aldehydes with 9—16 carbon chain lengths, acids with 8—10 carbon chain lengths, and pheny-lacetic acid. The odor of phenylacetic acid was detected instantly by human... 

If further acidic C—H bonds in the molecule cause problems, the tin-trick can be applied. The asymmetric deprotonation of a bifunctional carbamate (39a) is accomplished at an early stage and the masked carbanionic centre carried through the synthesis as a stan-nyl group. For instance, the (S)-5-silyloxy-l-tributylstannyl-pentyl carbamate 39b (> 95% ee) was produced by the usual means and converted by standard steps via the aldehyde 78 into the allyl chloride 79 (equation 17) . Lithiodestannylation of 79 by n-BuLi proceeds faster than reductive lithiation in the allylic position to form the lithiocarbamate 80,... 

Cho et al. describes an alternative synthesis (Scheme 20) of the 2,5 DKP scaffold 92 = 123 via a bifunctional dipeptide 120, an aldehyde 121, and an isocyanide 122 [42]. These commercially available starting materials were added in equimolar amounts to trifluoroethanol at 40°C under nitrogen. The reaction was brought to room temperature and allowed to complete. The standard Ugi workup was used followed by column chromatography. Yields were shown in the range of 21-87%. When this reaction was done in a microwave, time taken for the reaction to complete was decreased significantly and yields increased by a factor of 4. The substitution pattern of this and the previously described (in Scheme 15) are identical however, the reactions use different types of starting materials, for example, dipeptide vs. N- and C-protected amino acids. Thus different stereochemical outcomes can be expected for the two syntheses. 

Combination of MCR with the Pictet-Spengler cyclization also leads to different types of scaffolds with ketopiperazine fused ring systems. Tetrahydro-jS-carboline scaffold 221 was prepared in a convergent, two-step procedure [67]. An array of indole derivatives was prepared by the reaction of tryptophan derivative 222, aldehyde 223, carboxylic acid 224, and bifunctional amine 214 (Scheme 40). 

One of the pioneer works in the synthesis of DKPs through MCRs was reported by Hulme and coworkers in a three-step solution phase protocol based on UDC [33, 34]. They have obtained a series of different DKPs by reacting Armstrong s convertible isocyanide with aldehydes, M-Boc-protected amino acids as bifunctional acid component containing a protected internal amino nucleophile, and amines in methanol at room temperature. After Ugi-reaction, the isonitrile-derived amide is activated with acid (UAC) and allows cyclization to the DKP with the... 

Scheme 6.82 Proposed reactive complex of the Petasis reaction utilizing a-hydroxy aldehydes, amines, and organic boronic acids (A) and bifunctional mode of action of chelating thiourea catalyst 65 in the enantioselective Petasis-type 2-vinylation of N-acetylated quinolinium ions (B).

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