Boron enolates Boronic acids

In a similar way, Carreaux and coworkers [53] used 1-oxa-l,3-butadienes 4-155 carrying a boronic acid ester moiety as heterodienes [54], enol ethers and saturated as well as aromatic aldehydes. Thus, reaction of 4-155 and ethyl vinyl ether was carried out for 24 h in the presence of catalytic amounts of the Lewis acid Yb(fod)3 (Scheme 4.33). Without work-up, the mixture was treated with an excess of an aldehyde 4-156 to give the desired a-hydroxyalkyl dihydropyran 4-157. Although this is not a domino reaction, it is nonetheless a simple and useful one-pot procedure. 

Boronic acids 96 and 97 couple very well with vinyl triflates 98 and 99 under typical Suzuki conditions (Pd(PPh3)4/Na2C03/LiCl/DME) to give indoles 100 and 101, respectively, in 76-92% yield [115, 116]. Enol triflates 98 and 99 were prepared in good yield (73-86%) from N-substituted 3-piperidones, wherein the direction of enolization (LDA/THF/-78 °C PhNTf2) is dictated by the tf-substituent. 

This procedure illustrates a general method for the preparation of crossed aldols. The aldol reaction between various silyl enol ethers and carbonyl compounds proceeds smoothly according to the same procedure (see Table I). Sllyl enol ethers react with aldehydes at -78°C, and with ketones near 0°C. Note that the aldol reaction of sllyl enol ethers with ketones affords good yields of crossed aldols which are generally difficult to prepare using lithium or boron enolates. Lewis acids such as tin tetrachloride and boron trifluoride etherate also promote the reaction however, titanium tetrachloride is generally the most effective catalyst. 

Rhodium-catalyzed addition of boronic acids to enone moiety 89 led to a rhodium-enolate 90 which can be trapped by addition to the adjacent carbonyl function giving functionalized cyclopentanes or cyclohexanes 91. An important feature of this methodology is that this process allows the creation of three contiguous stereocenters with a high level of stereoselectivity. An asymmetric version of this reaction has also been realized with a chiral ligand (BINAP) giving excellent enantiomeric excesses (77 to 95%) (Scheme 34). 

Facile synthesis of simple 3-arylpyrroles from pyrroline by tandem Suzuki dehydrogenation reaction is depicted in Scheme 229. Thus, treatment of l-benzyl-2,5-dihydro-l//-pyrrol-3-yl trifluoromethanesulfonate 1195 (prepared in 55% yield from l-benzyl-3-pyrrolidinone 1194 by trapping the enolate with a triflating reagent), with boronic acid derivatives leads to the formation of 3-arylpyrroles 1196 in good yields (65-74%) <2000TL3423>. 

This chapter is primarily concerned with keto-enol equilibrium and the chemistry of dissociated enols (enoxides) and lithium enolates. The acid-base aspects of the chemistry of other metal enolates (e.g. silyl enol ethers "", boron enol ethers" " " , aluminium , tin " , gallium , bismuth , zinc " ", rhodium , palladium " , manganese ", copper , nickel , magnesium " , titanium " , molybdenum , zirconium" " and ammonium" " enolates) have been reported elsewhere. 

CAB 2, R = H, derived from monoacyloxytartaric acid and diborane is also an excellent catalyst (20 mol %) for the Mukaiyama condensation of simple enol silyl ethers of achiral ketones with various aldehydes. The reactivity of aldol-type reactions can, furthermore, be improved, without reducing the enantioselectivity, by use of 10-20 mol % of 2, R = 3,5-(CF3)2C6H3, prepared from 3,5-bis(trifluoromethyl)phenyl-boronic acid and a chiral tartaric acid derivative. The enantioselectivity could also be improved, without reducing the chemical yield, by using 20 mol % 2, R = o-PhOCgH4, prepared from o-phenoxyphenylboronic acid and chiral tartaric acid derivative. The CAB 2-catalyzed aldol process enables the formation of adducts in a highly diastereo- and enantioselective manner (up to 99 % ee) under mild reaction conditions [47a,c]. These reactions are catalytic, and the chiral source is recoverable and re-usable (Eq. 62). 

The enol ether 150 was reacted with the lithium derivative of the thioether 149 to give the intermediate 151 after oxidation. A Suzuki coupling, as you will learn to call it, linked the boronic acid derivative of the pyridine to the bromoenone to give the cyclopentenone 146 in just two steps. 

This review covers the catalytic literature on condensation reactions to form ketones, by various routes. The focus is on newer developments from the past 15 years, although some older references are included to put the new work in context. Decarboxylative condensations of carboxylic acids and aldehydes, multistep aldol transformations, and condensations based on other functional groups such as boronic acids are considered. The composition of successful catalysts and the important process considerations are discussed. The treatment excludes enantioselective aldehyde and ketone additions requiring stoichiometric amounts of enol silyl ethers (Mukaiyama reaction) or other silyl enolates, and aldol condensations catalyzed by enzymes (aldolases) or catalytic antibodies with aldolase activity. It also excludes condensations catalyzed at ambient conditions or below by aqueous base. Recent reviews on these topics are those of Machajewski and Wong, Shibasaki and Sasai, and Lawrence. " The enzymatic condensations produce mainly polyhydroxyketones. The Mukaiyama and similar reactions require a Lewis acid or Lewis base as catalyst, and the protecting silyl ether or other group must be subsequently removed. However, in some recent work the silane concentrations have been reduced to catalytic amounts (or even zero) this work is discussed. 

In 2010, Weinreb and coworkers reported their synthesis of communesin F (17) [30]. The synthesis began with known enol triflate 37. A Suzuki-Miyaura crosscoupling with 0-nitrophenyl boronic acid (38) followed by a two-step reaction with iodoaniline 39, afforded amide 40. A one-pot displacement of the benzyl group with ethyl carbamate, amide nitrogen protection, and a subsequent intramolecular Heck reaction provided enamide 41 (Scheme 5). 

Cross-coupling reactions leading to the formation of C-X (X = heteroatom) bonds catalyzed by Pd(dba)2 have been reported. Aniline derivatives have been prepared via reaction of amine nucleophiles with aryl halides in the presence of Pd(dba)2 and phosphines, especially P( Bu)3. Likewise, diaryl and aryl alkyl ethers are produced from aryl halides (Cl, Br, I) and sodium aryloxides and alkoxides under similar conditions. Conditions effective for the coupling of aryl chlorides with amines, boronic acids, and ketone enolates using an easily prepared phosphine chloride as a ligand have recently been uncovered (eq 22). The preparation of aryl siloxanes and allyl boronates via Pd(dba)2-catalyzed C-Si and C-B coupling have been reported as well. 

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