Boronic acids ketones

Moderate yields of acids and ketones can be obtained by paHadium-cataly2ed carbonylation of boronic acids and by carbonylation cross-coupling reactions (272,320,321). In an alternative procedure for the carbonylation reaction, potassium trialkylborohydride ia the presence of a catalytic amount of the free borane is utilized (322). FiaaHy, various tertiary alcohols including hindered and polycycHc stmctures become readily available by oxidation of the organoborane iatermediate produced after migration of three alkyl groups (312,313,323). 

The methylenebis(boronic acid) 122 may be deprotonated and alkylated at the central position and may thus behave as an acyl anion equivalent. Monoalkylation of 122 followed by hydrolysis gives aldehydes in good yield, and a second alkylation led to a ketone in one case (77JA3196). 

Regarding the use of other metals for this transformation, Shirai and co-workers reported that a system constituted by palladium(II) complex [Pd(p-Cl)(r -aUyl)]2 and thioether-imidazolium chloride 19 achieved the arylation of aldehydes with boronic acids [33] and potassium trifluoroborates in good to excellent yields (Scheme 7.5) [34], More recently, Buffard and Itami showed that a NKcod) / IPr-HCl system could catalyse the reaction of arylboronate esters and inactivated aldehydes and ketones (Scheme 7.5) [35]. 

Scheme 9.11 General scheme for catalytic coupling of aryl boronic acids with diazonium ions using Pd-SIPr to make ketones...

Scheme 4.19 Arylations of ketones with boronic acids and HOCSAC ligand.

Ketones can also be prepared by palladium-catalyzed reactions of boranes or boronic acids with acyl chlorides. Both saturated and aromatic acyl chlorides react with trialkylboranes in the presence of Pd(PPh3)4.233... 

The medicinal chemists subsequently discovered an improved route to racemic acid 9 that started with 2-bromo-2-cyclopente-l-one 11 (Scheme 7.2) [5]. Suzuki-Miyaura cross-coupling of 11 with 4-fluorophenyl boronic acid 12 provided 13 in 67% yield. Conjugate addition of cyanide furnished ketone 14 in 71% yield. Reduction of 14 with NaB H4 gave a 2.8 1 mixture of desired 15 and undesired 16 which were separated by silica gel chromatography. The observed diastereoselec-tivity with the cyano group was similar to ester 6. Hydrolysis of 15 with 5 M NaOH in MeOH gave racemic acid 9 in 91% yield, which was resolved as outlined in Scheme 7.1. 

A group of peptide derivatives such as peptide arginals and boronic acid peptide derivatives belong to another class of reversible thrombin inhibitors. One such inhibitor is PPACK (D-Phe-Pro-Arg chloromethyl ketone), which functions as a powerful irreversible thrombin inhibitor by alkylating the histidine residue at the catalytic site of thrombin (58). It, however, is unstable in neutral solution, as it undergoes cyclization and inactivation. However, the D-methyl derivative of D-Phe-Pro-Arg-H (D-Mephe-Pro-Arg-H) called efegatran, with a molecular mass of 515 Da, is a stable selective reversible inhibitor of thrombin with a K. of approximately 100 nM. The basic amino terminus in this compound is responsible for promoting the specificity toward thrombin (63). 

Entry Enone 7 Boronic acid 2 or 4 (equiv. to 1) Ketone 3 or 5 ... 

Oi and Inoue recently described the asymmetric rhodium-catalyzed addition of organosilanes [35]. The addition of aryl- and alkenyltriaUcoxysilanes to u,y9-unsaturated ketones takes place, in the presence of 4 mol% of a cationic rhodium catalyst generated from [Rh(COD)(MeCN)2]BF4 and (S)-B1NAP in dioxane/H20 (10 1) at 90°C, to give the corresponding conjugate addition products (Eq. 3). The enantioselectivity is comparable to that observed with the boronic acids, as the same stereochemical pathway is applicable to these reactions (compare Scheme 3.7). 

One popular method that has been apphed to industrial processes for the enantio-selective reduction of prochiral ketones, leading to the corresponding optically active secondary alcohols, is based on the use of chiral 1,3,2-oxazaborolidines. The original catalyst and reagent system [diphenyl prolinol/methane boronic acid (R)] is known as the Corey-Bakshi-Shibata reagent. Numerous examples... 

Interestingly, the chhal diamine 508 catalyzes the enantioselective addition of boronic acids to aromatic ketone.s like acetophenone. The reaction produces interesting tertiary diarylcarbinols such as 509 in up to 93% ee. Bolm and coworkers have shown that this approach can also be used for a simple preparation of chiral diarylcarbinols (such as 510) in the presence of the chiral ferrocenyl ligand 511 (Scheme 122) . The addition of... 

The ketone carbonyl of a series of isatins (63) undergoes enantioselective addition of aryl- and alkenyl-boronic acids, using a rhodium catalyst and a chiral phosphine.180... 

While the above stepwise bimolecular process was well suited for reactions with paraformaldehyde, other aldehydes and ketones did not behave similarly, presumably because of incomplete reactions between the amine and the carbonyl components. To overcome these difficulties, we invented a three-component process (Scheme 7.6) based on the one-step reaction between various amines 38, carbonyls 39, and boronic acids or boronates 40 to give the corresponding amine derivatives... 

The reaction is also referred to as the Boronic Acid Mannich Reaction, since it proceeds via an imine with the organic ligand of the boronic acid acting as the nucleophile, similar to the role of the enolizable ketone component in the original Mannich Reaction. 

The Suzuki coupling reaction of 2-haloselenophenes with boronic acids catalyzed by palladium salt is a new route to prepare 2-arylselenophenes and 2,5-diarylselenophenes in good yields. In addition, 2-arylselenophenyl ketones were also obtained by this protocol from 2-iodoselenophene and boronic acids via a carbonylative process [130],... 

Vinyl boronates 244 undergo radical addition to a,/3-unsaturated ketones 245 in the presence of a rhodium catalyst and (V)-BINAP to yield the 1,4-addition product 246 in high ee and yield <1998TL8479>. Under the reaction conditions, the boronates undergo hydrolysis to provide the corresponding boronic acids, which further undergo conjugate addition with the enone (Scheme 42). 

The asymmetric 1,4-addition of aryl boronic acids to a,P-unsaturated ketones has been reported with rhodium catalysts that contained P-Phos (120a) (Scheme 12.46).154... 

In order to introduce functionality at key positions, an intramolecular Diels-Alder reaction with furan as the diene component was planned. Suzuki coupling of the previously mentioned 105 with furan-3-boronic acid 106 gave compound 107, which was N-tosylated to 108. Construction of the dienophile portion was performed as in the previous case, by addition of vinylmagne-sium bromide to give 109, followed by MnC>2 oxidation to give the cyclization precursor, which was immediately heated at 120 °C in toluene and afforded compound 110, which incorporates an oxygen atom at both the ketone and vinyl chloride positions of welwistatin (Scheme 24). 

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). 

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