2-furyl boronic acid

Asymmetric hydrogenation of either a carbonyl or an imino group to a hydroxyl group or an amino group has frequently been employed for the introduction of chirality in amino acid syntheses. Corey s catecolborane-oxazaborolidine protocol enables transformation of difluoromethyl ketone 1 into alcohol 2 with excellent enantioselectivity. The reaction of diastereoselective amination of a-hydroxyaldehyde 3 with A,A-diallylamine and 2-furyl-boronic acid provides furyl amino alcohol 4 in good chemical yield along with excellent diastereoselectivity. This protocol is applicable for the preparation of amino acids and amino alcohols with a trifluoromethyl group by the combination of /V,/V-diallyl or N,N-dibenzyl amine and aromatic, heteroaromatic and alkenyl boronic acids [7]. The usual chemical transformations as shown in steps 5 to 8 in Scheme 9.1 lead to (2S,3R) difluorothreonine 5 [8]. 

Other issues with the synthesis were the apparent instability of 2-furyl boronic acid tmder the reaction conditions (several portions of the expensive boronic acid had to be added to drive the reaction to completion) and the variability in the quality of Pd(PPh3)4 from various vendors as well as its stability on storage under normal warehouse conditions. 

An alternative multistep approach to the synthesis of a-amino acids, using the boronic acid as the precursor of the carboxylic acid group, was reported by Harwood et al. [56]. Thus, reaction of a chiral morpholinone derivative with furyl boronic acid and various aldehydes gave, in a diastereocontrolled manner, the corresponding adducts which were converted in several steps to the a-amino acids [56],... 

A 2009 paper described a palladium-catalyzed domino-C,N-coupling/carbonyl-ation/Suzuki coupling reaction was used provide an efficient synthesis of 2-aroyl-/ heteroaroylindoles [163]. For instance, 2-ge/M-dibromovinyIaniline 118 and 3-furyl-boronic acid under carbon monoxide afforded 3-fuiylindole 119 in 67% yield. 

Costanzo et al. <2002MI87> published the synthesis of the furyl-substituted pyrazolo[3,2-f][l,2,4]triazine derivative 146 by Suzuki coupling of the iodo compound 145 with 2-furylboronic acid. The yield was found to be moderate (38%). It may be important to mention that these authors also tried to transform 145 to a heteroaromatic boronic acid and to carry out cross-coupling of this compound with 3-bromofuran. Unfortunately, however, this approach failed and only homo-coupling occurred. 

Aryl and heteroaryl (furyl, thienyl) boronic acids are especially suitable for the preparation of their iodonium salts, having the added advantage of better yields and lack of toxicity [108]. Tetraarylborates (sodium or potassium) reacted with (diacetoxyiodo)arenes in acetic acid to afford diaryliodonium salts in excellent yield (Scheme 37). It appears that triarylboranes formed upon reaction of the borates with acetic acid serve actually as the real arylating agents [109]. 

However, studies on the scope of this sequence revealed that the substrate has to be an N-tosyl sulfonamide and that certain boronic acids are not trans-metallated but rather give rise to the formation of the pyrrole 21 or a pyridine derivative 22 (Scheme 7). The peculiar outcome as a carbopalladation-Suzuki sequence is rationalized by co or dinative stabilization of the insertion intermediate 18 by the sulfonyl oxygen atom, as represented in structure 19, now suppressing the usual /3-hydride elimination. If the transmetallation is rapid the Suzuki pathway is entered leading to product 17. However, if the transmetallation is slow, as for furyl or ferrocenyl boronic acid, either /i-hydride elimination or a subsequent cyclic carbopalladation occurs. The former leads to the formation of the diene 20 that is isomerized to the pyrrole 21. The latter furnishes the cyclopropylmethyl Pd species 23, which rearranges with concomitant ring expansion to furnish piperidyl-Pd intermediate 24 that suffers a -hydride elimination to give the methylene tetrahydro pyridine 22. 

The 2-furyl derivative and the 2-thiazolyl analog of 261 are of special interest in this context because they could not be prepared by the reverse polarization procedure since furan-2- and thiazole-2-boronic acid are not readily available (90JHC2165). 

Heterocyclic aromatic boronic acids, in particular pyridinyl, pyrrolyl, indolyl, thienyl, and furyl derivatives, are popular cross-coupling intermediates in natural product synthesis and medicinal chemistry. The synthesis of heterocyclic boronic acids has been reviewed recently [222], and will not be discussed in detail here. In general, these compounds can be synthesized using methods similar to those described in the above section for arylboronic acids. Of particular note, all three isomers of pyridineboronic acid have been described, including the pinacol ester of the unstable and hitherto elusive 2-substituted isomer, which is notorious for its tendency to pro-todeboronate [223]. Improvements and variants of the established methods for synthesizing heterocyclic boronic acids have been constantly reported [13, 182]. For example, a Hg-to-B transmetallation procedure was recently employed to synthesize a highly functionalized indolylboronic acid (entry 19, Table 1.3) [187]. 

Indolizines with a saturated six-membered ring may be obtained from pyrrole or furan derivatives.225,226 The reaction of 3,4-dimethylpyrryl-magnesium bromide with y-chlorobutyronitrile followed by dilute acid gave 5,6,7,8-tetrahydro-l,2-dimethyl-5-oxoindolizine. 5,6,7,8-Tetrahy-droindolizine can be obtained by the cyclodehydration of 3-(2-furyl)-propylamine over alumina at 400°C. The same product is obtained by the treatment of 3-(2-pyrryl)propyl cyanide with hydrogen chloride in the presence of boron trifluoride etherate catalyst, followed by Wolff-Kishner reduction of the intermediate ketone. 

Brown, Buchanan, and Humffray have studied kinetically the protodemerDuration of 2- and 3-furyl, 2-thienyl, and 2-selenophenyl mercuric chlorides, and the protodeboronation and the iodode-boronation of 2- and 3-thiophenboronic acids. 

Furyl alcohol 2-Furylcarbinol a-Furylcarbinol. See Furfuryl alcohol 2-Furyl methanal. See Furfural (2-Furyl) methanol. See Furfuryl alcohol Fused boric acid. See Boron oxide... 

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