Borane reactions with benzaldehyde

Enol stannanes of cyclohexanone and propiophenone have been indicated to take part in r/treo-selective aldol reactions with benzaldehyde at low temperatures e.g. —78 °C), but to be erythro-seAsciiwe at higher temperatures ca 45 °C). Two complementary methods have been described for stereoselection in aldol-type reactions. Whilst a-mercurio-ketones show eryr/wo-selection in their reactions with aldehydes in the presence of boron trifluoride diethyl etherate, pre-formed lithium enolates and aldehydes, in the presence of simple trialkyl-boranes, lead to mixtures that are rich in the more stable threo-d do product. Aldol-type products arise from 1,3-alkyl migrations of alk-l-enyl alkyl acetals and ketals, in a reaction that is catalysed by boron trifluoride diethyl etherate (Scheme 52). Diastereoselection is possible, since (.E)-alkenyl acetals give the... 

Alcohols are converted to alkyl iodides by reaction with A A-diethyl-aniline/borane/iodine. Reductive iodination is observed when this system reacts with ketones or with carboxylic acids934,935. Direct reduction of aromatic aldehydes to benzyl bromide is reported by Le Corre and coworkers, who have brominated benzaldehydes and acetophenones in presence of a trimethylamine/borane complex and have obtained benzyl bromides and a-bromoethylbenzenes, respectively936. See also Reference937. 

A better accessible chiral mediator is the (acyloxy)borane (CAB) 2-64 prepared in situ from a tartaric acid derivative and arylboronic acid at room temperature. Hetero Diels-Alder reaction of benzaldehyde and Danishefsky s diene 2-10 in the presence of 2-64 gave the corresponding pyrone after acidic work up with 52 - 95 % ee depending on R. The best results were obtained with R = 2,4,6-Me3Ph and 2,4,6-iPr3Ph. Similarly, with 2-60 the pyrone 2-61 with up to 97% ee was found [107]. 

Several arylboronic acids have been examined in place of borane-THF to improve the Lewis acidity of 2 and the stereoselectivity [49b]. The boron substituent of 2 has a large effect on the chemical yield and the enantiomeric excess of the allylation adduct, and 3,5-bistrifluoromethylbenzeneboronic acid results in the greatest reactivity— when a complex which is easily prepared from a tartaric acid derivative and 3,5-bistri-fluoromethylbenzeneboronic acid in propionitrile at room temperature is used, the reactivity is improved without reducing the enantioselectivity. For instance, the reaction of l-trimethylsilyl-2-methyl-2-propene with benzaldehyde in the presence of only 10 mol % 2 proceeds to give 99 % yield and 88 % ee (Fig. 19). 

Oxazaborolidenes. Corey has reported the use of a novel oxazaborolidene complex 41 prepared from borane and A-tosyl (5)-tryptophan. This complex functions in a catalytic fashion in enantioselective, Mukaiyama aldol addition reactions (Scheme 8-3) [17]. The addition of ketone-derived enol silanes 42-43 gives adducts in 56-100% yields and up to 93% ee. The use of 1-trimethylsilyloxycyclo-pentene 43 in the addition reactions to benzaldehyde affords adducts 46 as a 94 6 mixture of diastereomers favoring the syn diastereomer in 92% ee. Addition reactions with dienol silanes 44 furnishes products 47 in up to 82% ee. Corey also demonstrated the use of these adducts as important building blocks for the synthesis of corresponding dihydropyrones treatment of 47 with trifluoroacetic acid affords the cyclic product in good yields. 

Masamune et al. examined the catalytic activity of several boron Lewis acids derived from BH3 THF and the p-toluenesulfonamides of simple a-amino acids towards the aldol reaction of benzaldehyde with TMS enolate 48 [121]. As a result, the borane catalysts derived from a,a-disubstituted glycine p-tolueriesulforiarriides were found to have high activity. The disubstitution would accelerate the second step (Step II) of the catalytic cycle (Scheme 10.43). On the basis of this observation, they developed chiral borane catalysts 47 c and 47 d, which enable highly enantioselective aldol reactions of KSA and thioketene silyl acetals (84—99% ee with 48). 

The hydroboration of 1,3-dienes has also been reported, and these reactions generate Z-allylic boronic ester products. These reactions have been reported with palladium catalysts and are thought to occur through Tr-allyl intermediates. Reactions with butadiene and isoprene, followed by addition of the product to benzaldehyde, are shown in Equation 16.47. This equation also shows the presumed mechanism that proceeds by generation of a palladium allyl from the combination of diene and palladium hydride formed by oxidative addition of the borane. 

The terminal alkynes react with 2 equiv of 9-BBN and affords, quantitatively, the corresponding 1,1-diboraylalkanes. Soderquist has reported that this trialkyl-borane reacts with 1 equiv of benzaldehyde or 1-NaphCHO in 2 h at 25 °C, and quantitatively form B-ArCH20-9-BBN and B-alkenyl-9-BBN, exclusively with tram configuration [18]. The frans-B-alkenyl-9-BBN undergoes selective oxidation [18] with 1 equiv of anhydrous trimethylamine-N-oxide (TMANO) [19] and affords almost quantitatively the corresponding stable fraws-B-vinyl-9-oxa-10-borabicyclo[3.3.2]decane derivatives (traws-B-vinyl-OBBD). tram-B-Yinyl-OBBD derivatives are inert to atmospheric oxygen and are unreactive toward protonolysis (HOAc, 25 °C, 8 h) or insertion process (PhCHO, neat, 80 C, 6 h). The reaction sequence for the synthesis of fraws-B-vinyl-OBBD is outlined in Scheme 20.6 [18]. 

Since our group (22) and Hehnchen s (23) independently announced a new class of chiral acyloxyboranes derive from iV-sulfonylamino acids and borane THF, chiral 1,3 -oxazaborolidines, their utility as chiral Lewis acid catalysts in enantioselective synthesis has been convincingly demonstrated (2(5). In particular, Corey s tryptophan-derived chiral oxazaborolidines 10a and 10b are highly effective for not only Mukaiyama aldol reactions (24) but also Diels-Alder reactions (25). More than 20 mol% of 10b is required for the former reaction, however. Actually, the reaction of the trimethylsilyl enol ether derived from cyclopentanone with benzaldehyde afforded the aldoI products in only 71% yield even in the presence of 40 mol%of 10b (24). We recently succeed in renewing 10b as a new and extremely active catalyst lOd using arylboron dichlorides as Lewis acid components (2(5). 

This method has not yet found widespread use for the preparation of allylboronates. In fact, uncatalyzed hydroborations of dienes tend to provide the undesired regioiso-mer with the boron atom on a terminal carbon, i.e., homoallylic boranes. By making use of certain transition metal catalysts, however, Suzuki and co-workers found that (Z)-allylic catecholboronates such as 22 can be obtained in high yield from various substituted butadienes (e.g., isoprene. Equation 11) [44]. Whereas a palladium catalyst is the preferred choice for acyclic dienes, a rhodium catalyst (Rh4(CO)i2) was best for the hydroboration of cyclohexadiene. A suitable mechanism was proposed to explain the high regioselectivity of this process. In all cases, a reaction quench with benzaldehyde afforded the expected homoallylic alcohol product from a tandem hy-droboration/allylation (Section 6.4.1.4). 

Besides direct reduction, a one-pot reductive amination of aldehydes and ketones with a-picoline-borane in methanol, in water, and in neat conditions gives the corresponding amine products (Scheme 8.2).40 The synthesis of primary amines can be performed via the reductive amination of the corresponding carbonyl compounds with aqueous ammonia with soluble Rh-catalyst (Eq. 8.17).41 Up to an 86% yield and a 97% selectivity for benzylamines were obtained for the reaction of various benzaldehydes. The use of a bimetallic catalyst based on Rh/Ir is preferable for aliphatic aldehydes. 

The addition reaction of carbon-11 labelled cyanide ion to the bisulphite addition adduct of an aldehyde has been extended to prepare carbon-11 labelled amines. Maeda and coworkers prepared both p- and m-octopamine [2-(p-and m-hydroxyphenyl)-2-hydroxyethyl-amine] from the corresponding benzaldehyde by reducing the cyanohydrin formed in the reaction between the appropriate benzaldehyde and cyanide ion both under enzymatic conditions and by the basic modification of the Bucherer-Strecker synthesis, with borane-THF. The synthesis of / -octopamine is presented in equation 64. 

Stirring a mixture of 2-formylamino-3-nitropyridine, benzaldehyde and borane pyridine complex in methylene chloride and acetic acid at room temperature afforded 1-benzyl-IbP. Similar derivatives of IbP were prepared from other aldehydes. The reaction of 3-benzylidenamino-2-formylaminopyridine with borane pyridine complex also led to the formation of benzyl-IbP (95JOC960). 

The borane derivative derived from readily available 3-(ferf-butyldimethylsi-lyl) - l-(trimethylsilyl) -1 -propyne [1] condenses with hexanal and benzaldehyde. The reaction proceeds through six-membered transition state to furnish after workup with 2-aminoethanol the homoprogylic alcohols with high diastereose-lectivities. The SR/RS RR/SS ratio is >98 2. 

The reduction of acylcyanide using neat (f )-Alpine-Borane affords the corresponding (i )-P-amino alcohols [4cj. The reduction of acylcyanide and subsequent workup is not a straightforward process. The reaction of benzoylcyanide with neat Alpine-Borane (1.5 equiv) is complete within 2 h. The cyanohydrin-9-BBN adduct builds up to maximum, and then decreases with the appearance of a 9-BBN-benzyl alcohol adduct. Apparently, the 9-BBN-cyanohydrin adduct undergoes an elimination reaction to give benzaldehyde, which then undergoes reduction. The results indicate that the desired bimolecular reduction process can compete with the elimination reaction. 

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