Boronic acids, metal mediated

In this method, Furstner converts N-BOC protected pyrrole to the 2,5-dibromo compound (122) with NBS and this is followed by metalation and carbomethoxylation with t-butyl lithium in THF and subsequent trapping of the metalated species with methyl chloroformate to yield a pyrrole diester (123). Bromination of this diester at positions 3 and 4 with bromine in water followed by Suzuki cross-coupling with 3,4,5-trimethoxyphenyl boronic acid yields the symmetrical tetrasubstituted pyrrole (125). Base-mediated N-alkylation of this pyrrole with 4-methoxyphenethyl bromide produces the key Boger diester (126) and thereby constitutes a relay synthesis of permethyl storniamide A (120). 

Boronic acid hnkers (Tab. 3.6) are useful for the attachment of diols, the protection of glycosides [105] or as precursors for the metal-mediated cleavage [106]. The boronates formed are sensitive to water and simple hydrolysis is sufficient for cleavage. Recently, Carreaux and Carboni developed a new boronate-based strategy for traceless sohd-phase synthesis of aromatic compounds [107]. 

To expand the diversity of their libraries Brill et al.16 also modified various heterocycles by alkylation, acylation, or metal-mediated coupling reaction prior to resin capture. A remaining chloro substituent was still available for nucleophilic displacement or a palladium-mediated coupling reaction with anilines, phenols, and boronic acids on solid phase [see Fig. 10 for the preparation of purine derivative (62)]. 

Boronates have been used in a variety of linker types either as linkers for diols [42] or as precursors for metal-mediated cleavage. A boronic acid ester, which contains an aryl iodide moiety attached by an appropriate tether, can act as an intramolecular arylation agent. A polymer-bound precursor furnished a macrocydic constrained / -tum peptide mimic via biaryl coupling, leading to cleavage [43] (Scheme 6.1.10). 

The two key catalytic intermediates have been observed by electrospray mass spectrometry [394]. Although the exact role and influence of the base remains unclear [395], the transmetallation is thought to be facilitated by base-mediated formation of the tetracoordinate boronate anion [396], which is more electrophilic than the free boronic acid (Sections 1.5.1 and 1.5.2). A useful carbonylative variant has also been developed to access benzophenones (Equation 70) [397], which can also be produced from the coupling of acid chlorides [398] or anhydrides [399], A variant of this method allows the preparation of a, 3-unsaturated esters from alkenylboronic esters [243]. In all of these reactions, one dreaded limitation with some ortho-substituted and electron-poor arylboronic acids is the possible occurrence of a competitive protolytic de-boronation, which is exacerbated by the basic conditions and the use of a transition metal catalyst (Section 1.5.1). Methods to minimize this side reaction were developed in particular the use of milder alternative bases [400] such as fluoride salts [401], and... 

The Ullmann reaction (79) and the metal mediated oxidative polymerization (20) were used for the synthesis. These methods are replaced by metal catalyzed reactions nowadays. Schluter and Wegner (27) used in 1989 the coupling of boronic acids described by Susuki (22) to synthesize soluble polyphenylenes. The Pd catalyzed reaction tolerates a large number of functional groups. The diaryl coupling of Kumada can be used as well to synthesize polyphenylenes (29,J0). 

A great majority of the catalytic aldol processes that have been developed over the last two decades involve Lewis acids derived from complexes of titanium, boron, tin, and, more recently, copper as well as silver. A recent, exciting area of rapid development for aldehyde addition reactions is represented by the catalytic aldol methods that utilize soft-metal and lanthanide coordination complexes which mediate addition reactions through metalloenolate intermediates. 

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