Benzaldehydes activated

The energy of the localized transition state for the ortho route (uncatalyzed reaction) is 14kcal/mol higher than that of the meta channel. Therefore, the ortho channel can be excluded. Unlike the uncatalyzed transformation, the TADDOL-catalyzed HDA reaction exhibited a clear energetic preference for the endo- over the exo-approach. Thus, only endo transition states were considered. The number of possible reaction paths/transition states is thus reduced from eight to two, namely endo-approach with re- or si-face attack of the model diene to the activated benzaldehyde. 

The furanoterpene 15-acetoxytubipofuran 12 shows cytotoxicity against B-16 melanoma cells. E. Peter Kiindig of the University of Geneva has reported (J. Am. Chem. Soc. 125 5642, 2003) a concise asymmetric synthesis of 12, based on the addition of lithio ethyl vinyl ether to the chromium tricarbonyl-activated benzaldehyde 10. In the course of the organometallic addition, five carbon-carbon bonds are formed. 

Triethylsilane in trifluoroacetic acid has proved to be a mild and selective reducing agent for the conversion of aryl and diaryl ketones into the corresponding arenes however, with activated benzaldehydes, e.g, 4-MeCeH4-CHO, Friedel-Crafts alkylation competes with reduction. Reduction of phenyl cyclobutyl ketone and phenyl cyclopropyl ketone gives low yields (36 and ca. 25%, respectively) of the corresponding benzylcycloalkanes [the former reaction also affords phenylcydo-pentane (ca. 42%) via ring-expansion] and with ortAo-benzoylbenzoic acid and 3-benzoyIpropanoic acid the lactones (11) (100%) and (12) (86%), respectively, are formed. ... 

Quite similar considerations apply to the other types of thiamine-catalyzed reactions. In particular, the structure of active acetaldehyde is sinular to that of active benzaldehyde . 

The use of an (5)-threonine/a,a-(5)-diphenylvalinol-derived ionic liquid 81 gave comparable results to the 0-iBu-L-tyrosine-catalyzed reaction, but the recovery of the catalyst was simpler [100]. The simple primary-tertiary diamine 38 proved syn-selective, though it works only for aromatic aldehydes [76]. For the synthesis of iy -aldols derived from active benzaldehydes, other catalysts bearing primary amine functionalities also gave satisfactory results [90b, 60, 100, 101]. 

Transaminases (also termed amino transferases [EC 2.6.l.X]) catalyze the redox-neutral amino-transfer reaction between an amine donor and a carbonyl group serving as acceptor (Scheme 2.225) [94, 1707-1712]. These enzymes require an activated benzaldehyde (pyridoxal-5 -phosphate, PLP, vitamin Bg) as cofactor, which functions as a molecular shuttle for the transfer of the NHa-moiety. In a first step, PLP forms a ketimine Schiff base with the amine-donor. Tautomerization of the C=N bond yields an aldimine, which is hydrolyzed to yield the cofactor in its aminated form (pyridoxamine, PMP). The latter reacts through the same order of events with the carbonyl group of the substrate to form the amine product and... 

The derivative 39 has also been reported to catalyze the aldol reaction between underivatized hydroxyacetone and activated benzaldehydes, affording the products with low diastereoselectivity and in moderate to high ee [109]. The best results were obtained with (R,R)-tartaric acid as co-catalyst and the absence of a solvent. In addition, a scalable procedure for the reaction with 4-nitrobenzaldehyde was developed involving a single crystallization step in order to obtain the enantiopure branched product of the aldol reaction. j n example of an intramolecular aldol reaction is provided by work of List and coworkers, who found that the formation of enantioenriched 5-substituted-3-methyl-2-cyclohexene-l-ones could be obtained from 4-substituted-2,6-hexadiones with 36 as the catalyst (Scheme 6.51) [llOj. 

Preparation of REAOENTS.t It is essential for this preparation that the zinc powder should be in an active condition. For this purpose, it is usually sufficient if a sample of ordinary technical zinc powder is vigorously shaken in a flask with pure ether, and then filtered off at the pump, washed once with ether, quickly drained and without delay transferred to a vacuum desiccator. If, however, an impure sample of zinc dust fails to respond to this treatment, it should be vigorously stirred in a beaker with 5% aqueous sodium hydroxide solution until an effervescence of hydrogen occurs, and then filtered at the pump, washed thoroughly with distilled water, and then rapidly with ethanol and ether, and dried as before in a vacuum desiccator. The ethyl bromoacetate (b.p. 159 ) and the benzaldehyde (b.p. 179 ) should be dried and distilled before use. 

The same products can be also obtained from 267 and benzaldehyde. This behavior indicates the presence of an active methylene group and supports the thiazolone structure (267a). Alkyl or aryl ethers of 267 are prepared by two different procedures (Scheme 139). 

Reactions. Heating an aqueous solution of malonic acid above 70°C results in its decomposition to acetic acid and carbon dioxide. Malonic acid is a useful tool for synthesizing a-unsaturated carboxyUc acids because of its abiUty to undergo decarboxylation and condensation with aldehydes or ketones at the methylene group. Cinnamic acids are formed from the reaction of malonic acid and benzaldehyde derivatives (1). If aUphatic aldehydes are used acryhc acids result (2). Similarly this facile decarboxylation combined with the condensation with an activated double bond yields a-substituted acetic acid derivatives. For example, 4-thiazohdine acetic acids (2) are readily prepared from 2,5-dihydro-l,3-thiazoles (3). A further feature of malonic acid is that it does not form an anhydride when heated with phosphorous pentoxide [1314-56-3] but rather carbon suboxide [504-64-3] [0=C=C=0], a toxic gas that reacts with water to reform malonic acid. 

Aldol additions of benzaldehyde with active methylene groups produce other aldehydes. 

The low autoignition temperature of benzaldehyde (192°C) presents safety problems since benzaldehyde can be ignited by exposure to low pressure steam piping, for example. Benzaldehyde may also spontaneously ignite when soaked into rags or clothing or adsorbed onto activated carbon (13). 

This reaction is favored by moderate temperatures (100—150°C), low pressures, and acidic solvents. High activity catalysts such as 5—10 wt % palladium on activated carbon or barium sulfate, high activity Raney nickel, or copper chromite (nonpromoted or promoted with barium) can be used. Palladium catalysts are recommended for the reduction of aromatic aldehydes, such as that of benzaldehyde to toluene. 

When partially resolved samples of 5-hydroxymethylpyrrolidin-2-one are allowed to react with benzaldehyde in the presence of an acid catalyst, two products, A (C12H13NO2) and B (C24H26N2O4), are formed. The ration A B depends on the enantiomeric purity of the starting material. When the starting material is optically pure, only A is formed. When it is racemic, only B is formed. Partially resolved material gives both A and B. The more nearly it is enantiomerically pure, the less B is formed. The products A is optically active but B is achiral. Develop an explanation for these observations, including structures for A and B. 

The dehydration reactions have somewhat higher activation energies than the addition step and are not usually observed under strictly controlled kinetic conditions. Detailed kinetic studies have provided rate and equilibrium constants for the individual steps in some cases. The results for the acetone-benzaldehyde system in the presence of hydroxide ion are given below. Note that is sufficiently large to drive the first equilibrium forward. 

Reductions by NaBKt are characterized by low enthalpies of activation (8-13kcal/mol) and large negative entropies of activation (—28 to —40eu). Aldehydes are substantially more reactive than ketones, as can be seen by comparison of the rate data for benzaldehyde and acetophenone. This relative reactivity is characteristic of nearly all carbonyl addition reactions. The reduced reactivity of ketones is attributed primarily to steric effects. Not only does the additional substituent increase the steric restrictions to approach of the nucleophile, but it also causes larger steric interaction in the tetrahedral product as the hybridization changes from trigonal to tetrahedral. 

Darzens reaction can be used to efficiently complete the stereoselective synthesis of a"-substituted epoxy ketones. As an example, Enders and Hett reported a technique for the asymmetric synthesis of a"-silylated a,P-epoxy ketones. Thus, optically active a -silyl a-bromoketone 38 was treated with LDA followed by the addition of benzaldehyde to give a"-silyl epoxyketone 40 in 66% yield with good... 

Ring closure of 2-chloro-l-phenethylpyridinium ion (247) (prepared in situ) to l,2-dihydro-3,4-benzoquinolizium ion involves intramolecular nucleophilic displacement of the chloro group by the phenyl 77-electrons. A related intermolecular reaction involving a more activated pyridine ring and more nucleophilic 7r-electrons is the formation of 4-( -dimethylaminophenyl)pyridine (and benzaldehyde) from dimethylaniline and 1-benzoylpyridinium chloride (cf. Section III,B,4,c). 

Active carbonyl compounds such as benzaldehyde attack the electron-rich double bond in DTDAFs to give a dipolar adduct, which immediately undergoes dissociation with formation of two molecules of 146 (64BSF2857 67LA155).Tlie existence of by-products such as benzoin led to the synthetic application of thiazolium salts in the acyloin condensation. For example, replacement of the classic cyanide ion by 3-benzyl-4-methyl-5(/3-hydroxyethyl) thiazolium salts allowed the benzoin-type condensation to take place in nonaqueous solvents (76AGE639) (Scheme 57). 

Yamamoto et al. were probably the first to report that chiral aluminum(III) catalysts are effective in the cycloaddition reactions of aldehydes [11]. The use of chiral BINOL-AlMe complexes (R)-S was found to be highly effective in the cycloaddition reaction of a variety of aldehydes with activated Danishefsky-type dienes. The reaction of benzaldehyde la with Danishefsky s diene 2a and traws-l-methoxy-2-methyl-3-(trimethylsilyloxy)-l,3-pentadiene 2b affords cis dihydropyrones, cis-3, as the major product in high yield with up to 97% ee (Scheme 4.6). The choice of the bulky triarylsilyl moiety in catalyst (J )-8b is crucial for high yield and the en-antioselectivity of the reaction in contrast with this the catalysts derived from AlMe3 and (J )-3,3 -disubstituted binaphthol (substituent = H, Me, Ph) were effective in stoichiometric amounts only and were less satisfactory with regard to reactivity and enantioselectivity. 

Chiral boron(III) Lewis acid catalysts have also been used for enantioselective cycloaddition reactions of carbonyl compounds [17]. The chiral acyloxylborane catalysts 9a-9d, which are also efficient catalysts for asymmetric Diels-Alder reactions [17, 18], can also catalyze highly enantioselective cycloaddition reactions of aldehydes with activated dienes. The arylboron catalysts 9b-9c which are air- and moisture-stable have been shown by Yamamoto et al. to induce excellent chiral induction in the cycloaddition reaction between, e.g., benzaldehyde and Danishefsky s dienes such as 2b with up to 95% yield and 97% ee of the cycloaddition product CIS-3b (Scheme 4.9) [17]. 

A chiral vanadium complex, bis(3-(heptafluorobutyryl)camphorato)oxovana-dium(IV), can catalyze the cycloaddition reaction of, mainly, benzaldehyde with dienes of the Danishefsky type with moderate to good enantioselectivity [21]. A thorough investigation was performed with benzaldehyde and different activated dienes, and reactions involving double stereo differentiation using a chiral aldehyde. 

Danishefsky et al. were probably the first to observe that lanthanide complexes can catalyze the cycloaddition reaction of aldehydes with activated dienes [24]. The reaction of benzaldehyde la with activated conjugated dienes such as 2d was found to be catalyzed by Eu(hfc)3 16 giving up to 58% ee (Scheme 4.16). The ee of the cycloaddition products for other substrates was in the range 20-40% with 1 mol% loading of 16. Catalyst 16 has also been used for diastereoselective cycloaddition reactions using chiral 0-menthoxy-activated dienes derived from (-)-menthol, giving up to 84% de [24b,c] it has also been used for the synthesis of optically pure saccharides. 

The structures along the reaction path in Fig. 8.13 are outlined in Fig. 8.14 starting with benzaldehyde activated by (MeO)2AlMe in the reaction with Danishefsky s diene 10 leading to the transition-state structure for the formation of the al-dol-like intermediate, and finally the formation of the hetero-Diels-Alder adduct. 

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