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Aldehydes deuterated

Like deuterated formate ion, the aldehyde deuterated at the carbonyl carbon atom is a stronger base, and the equilibrium is shifted to the right. Within its rather large experimental error, the magnitude of the effect, AF° = — 55 cal., agrees well with the formic acid results. [Pg.158]

The concentrations of the different intermediates are determined by the equilibrium constants. The observation of immonium ions [Eq. (5)] in strongly acidic solutions by ultraviolet and NMR spectroscopy also Indicates that these equilibria really exist (23,26). The equilibria in aqueous solutions are of synthetic interest and explain the convenient method for the preparation of 2-deuterated ketones and aldehydes by hydrolysis of enamines in heavy water (27). [Pg.111]

Enantioselective reduction is not possible for aldehydes, since the products are primary alcohols in which the reduced carbon is not chiral, but deuterated aldehydes RCDO give a chiral product, and these have been reduced enantioselectively with B-(3-pinanyl)-9-borabicyclo[3.3.1]nonane (Alpine-Borane) with almost complete optical purity. ... [Pg.1201]

The decarboxylation of carboxylic acid in the presence of a nucleophile is a classical reaction known as the Hunsdiecker reaction. Such reactions can be carried out sometimes in aqueous conditions. Man-ganese(II) acetate catalyzed the reaction of a, 3-unsaturated aromatic carboxylic acids with NBS (1 and 2 equiv) in MeCN/water to afford haloalkenes and a-(dibromomethyl)benzenemethanols, respectively (Eq. 9.15).32 Decarboxylation of free carboxylic acids catalyzed by Pd/C under hydrothermal water (250° C/4 MPa) gave the corresponding hydrocarbons (Eq. 9.16).33 Under the hydrothermal conditions of deuterium oxide, decarbonylative deuteration was observed to give fully deuterated hydrocarbons from carboxylic acids or aldehydes. [Pg.306]

Many research groups have attributed the isomerization to a series of additions and eliminations of a cobalt carbonyl hydride. However, it has been shown that aldehydes may be found with formyl groups attached to a carbon atom other than the two of the double bond even under non-isomerizing conditions. Piacenti and co-workers (44, 45) studied the hydroformylation of [l-14C]propylene and of a>-deuterated a-olefins. Even for a-olefins with chain lengths up to C6, the formyl group was attached to all possible carbon atoms in the product mixture. However, in the deuterated experiments, deuterium was present only on carbons 2, 3, and a) of the resulting aldehydes. These results were explained by pro-... [Pg.13]

The bisfunctionalization of alkynes by both C02 and another electrophile can also be achieved, as shown in Scheme 9.17,17a The titanium-carbon bond in the titanacycle complex 31, which was formed by reaction of C02 with the titanacyclopropene 30, can be substituted with various electrophiles. For example, its reaction with NBS or I2 afforded the synthetically useful vinyl bromide or iodide 32, respectively, while the reaction with D20 yielded the /3-deuterated a,/ -unsaturated carboxylic acid. When an aldehyde such as PhCHO was used as an electrophile, butenolide 33 was produced after acidic workup. [Pg.540]

Darensbourg et al. found that HCr(CO)5 converts acyl chlorides to aldehydes rapidly at 25 °C (Eq. (26)) [26]. Yields >90% were detected by gas chromatography (GC) for preparation of CH3CHO, n-BuCHO, PhCHO, and PhCH2CHO. Since CH3OD converts HCr(CO)5 to DCr(CO)] , the reaction of [HCr(CO)5] with PhCOCl in the presence of CH3OD provided a convenient synthesis of the deuterated aldehyde, PhCDO. [Pg.173]

The aforementioned deuterated derivatives were prepared by way of reduction of a ketone, aldehyde, or ester with sodium borodeu-teride, or by deuteroboration of an alkene. An interesting reaction, perhaps eventually applicable to direct deuteration of polysaccharides, was reported by Koch and Stuart413 and by them and their coworkers,41b who found that treatment of methyl a-D-glucopyranoside with Raney nickel catalyst in deuterium oxide results in exchange of protons attached to C-2, C-3, C-4, and C-6. In other compounds, some protons of CHOH groups are not replaced, but the spectra may nevertheless be interpreted with the aid of a- and /3-deuterium effects. [Pg.20]

The present method is simple, proceeds easily and in good yield. The starting materials are readily available. The method is of particular value for the ready preparation of C-l deuterated aldehydes using the 2-deuterio-N,4,4-trimethyl-2-oxazolinium iodide.6 Also, since relabeled formic acid is routinely available, this provides easy access to isotopically labeled aldehydes. [Pg.93]

Further, a large number of examples with simple alkyl substituents [168, 171, 176-184], cyclic alkanes [185], aryl substituents [177, 186-192], olefmic substituents [78, 177, 193-196], deuterated compounds [172], thioether groups [171], ester groups [197], orthoesters [198, 199], acetals [168, 182, 200-204], silyl-protected alcohols [198, 205-211], aldehydes [212], different heterocycles [213-217], alkyl halides [218, 219] and aryl halides [192, 220-223] have been reported. A representative example is the reaction of 92, possessing a free hydroxyl group, an acetal and a propargylic ether, to 93 [224] (Scheme 1.40). [Pg.19]

This method is also applicable to the reduction of amides to the corresponding aldehydes and alcohols by controlling the amount of t-BuOH and supplied electricity. The reduction in the presence of t-BuOD gives deuterated aldehydes (Scheme 17). [Pg.205]

DePuy, as early as 1966 [14], reported that cw-1-methyl-2-phenylcyclopropanol gave exclusively deuterated 4-phenyl-2-butenone in 0.1 M NaOD/D20/dioxane. However, homoenolates derived from simple cyclopropanols by base-induced proton abstraction fail to react with electrophiles such as aldehydes and ketones, which would afford directly 1,4-D systems. Lack of a reasonably general preparative method was another factor which impeded the studies of homoenolate chemistry. For this reason, in the past twenty years more elaborated cyclopropanols, which might be suitable precursors of "homoenolates", have been prepared and studied. [Pg.126]

Some support for the allylic shift pictured above comes from the work of Goetz and Orchin (23) on the isomerization of allyl alcohol to propionaldehyde by DCo(CO)4. These authors found that in the deuterated aldehyde all the D was on the methyl carbon and the following reaction path was suggested ... [Pg.26]

Hydrogen telluride, H2Te, generated in situ by the hydrolysis of aluminium telluride, reduces aldehydes and ketones to the corresponding alcohols. In the presence of deuterium oxide, deuterated derivatives are formed. [Pg.115]

This procedure illustrates a general method for the reduction of aldehyde and ketone functions to methylene groups under very mild conditions. Since strong acids and bases are not employed, this procedure is of particular importance for the reduction of ketones possessing an adjacent chiral center. Moreover, the use of deuterated metal hydrides permits the preparation of labelled compounds. ... [Pg.63]

The reversibility of the hydride migration in unmodified rhodium catalysts has been studied intensively by Lazzaroni et al. [56]. Reversible hydride migration will result in aldehydes containing deuterium at the a-carbon, whereas irreversible hydride migration will result in exclusive deuteration of the aldehyde and P-carbon. Mutual reversible alkene coordination and hydride migration ivill result in the formation of deuterated alkenes. Reversible formation of the branched rhodium alkyl will place deuterium at Cl and reversible formation of the linear alkyl complex will provide deuterium at C2 (Scheme 6.4). [Pg.265]

To elucidate the reaction pathway, deuterium-labeled allenyl pinacol boronate 10 was prepared, and the addition reaction with hydrazonoester 6 was conducted in the presence of Bi(OH)3 and Cu(OH)2 (Scheme 4). In both Bi- and Cu-catalyzed cases, the reactions proceeded smoothly (in quantitative yields in both cases). In the Bi(OH)3-catalyzed reaction, a major product was allenyl compound 11, in which the internal position was deuterized. It was assumed that a propargyl bismuth was formed via transmetalation from boron to bismuth, followed by addition to hydrazonoester via y-addition to afford allenyl compound 11. Thus, two y-additions could selectively provide a-addition products [75, 76, 105, 106]. It was confirmed that isomerization of 10 did not occur. Recently, we reported Ag20-catalyzed anti-selective a-addition of a-substituted allyltributyltin with aldehydes in aqueous media [107], On the other hand, in the Cu(OH)2-catalyzed reaction, a major product was propargyl compound 12, in which the terminal position was deuterized. A possible mechanism is that Cu(OH)2 worked as a Lewis acid catalyst to activate hydrazonoester 6 and that allenyl boronate 10 [83-85] reacted with activated 6 via y-addition to afford 12. [Pg.14]

Evidence for this mechanism is (1) two equivalents of RLi are required (2) the hydrogen in the product comes from the water and not from the adjacent carbon, as shown by deuterium labeling 209 and (3) the intermediates 31-33 have been trapped.210 This reaction, when performed in tetramethylenediamine, can be a synthetically useful method211 of generating vinylic lithium compounds (33), which can be trapped by various electrophiles such as D20 (to give deuterated alkenes), C02 (to give a, 3-unsaturated carboxylic acids—6-34), or DMF (to give a, 3-unsaturated aldehydes—0-105). [Pg.1020]

Griffiths and Gutsche (23) recently studied the interconversion of deuterated mandelaldehyde dimer and 2-hydroxyacetophenone in pyridine to obtain information concerning the glyceraldehyde-dihydroxy-acetone rearrangement. Their results support an enolization mechanism requiring a base and an acid catalyst. They found a deuterium isotope effect of ca. 1.3 for the transformation of the aldehyde to the ketone. When they corrected this for the apparently differing amounts of the aldehyde form in equilibrium with the proteo dimer and the deuterio dimer, they obtained a value of 3.9. By the Swain-Schaad equation (26) ... [Pg.82]

Application of alumina-supported sodium borodeuteride under the reaction conditions described by Varma26 provided deuterated alcohols from aldehydes and ketones with a high degree of deuterium incorporation. The method is thus suitable for isotopic labelling procedures (Scheme 4.12)32. [Pg.82]

The ring opening of tetrahydro-l,3-oxazines to aldehydes has recently found wide application through the work of Meyers.2-3 2-Alkylidene-tetrahydro-l,3-oxazines, prepared from the readily available 5,6-dihydro-4//-1,3-oxazines, possess strong nucleophilic properties and can react with alkyl halides and carbonyl compounds. The derivatives so obtained can be reduced to tetrahydro-l,3-oxazines, and through ring opening the latter can furnish acyclic, alicyclic, and a,jS-unsaturated aldehydes and their C-l deuterated derivatives.221-223 228... [Pg.35]

Deuteration studies showed that the distribution of deuterium in the glycol aldehyde was consistent with this mechanism.336 It has been shown that, in presence of small amounts of an amine, the reaction can be carried out in solvents other than dialkylamides.337 The amines also ... [Pg.262]


See other pages where Aldehydes deuterated is mentioned: [Pg.252]    [Pg.338]    [Pg.252]    [Pg.338]    [Pg.79]    [Pg.23]    [Pg.172]    [Pg.1335]    [Pg.411]    [Pg.334]    [Pg.94]    [Pg.120]    [Pg.134]    [Pg.186]    [Pg.792]    [Pg.192]    [Pg.724]    [Pg.343]    [Pg.129]    [Pg.10]    [Pg.129]    [Pg.769]    [Pg.442]    [Pg.422]    [Pg.297]    [Pg.239]    [Pg.76]   


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Aldehydes with deuterated alpine-borane

Deuterated

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