Suzuki-type

The more utilitarian means for installing an aryl substituent in position 4 onto the 2(5//)-furanone ring, the Suzuki-type cross-coupling of arylboronic acid with... 

The authors used a synthesis of 9,9-spirobitluorenes 32 which was developed by Clarksen and Gomberg [60] and which includes the addition of biphenyl-2-yl-magnesium iodide to fluorenone and subsequent cyclization with protic acids. To obtain 2,2,, 7,7 -arylated 9,9-spirobifluorenes 33, 9,9-spirobifluorene (32) was tetrabrominated [58] to yield 34 followed by a Suzuki-type aryl-aryl cross-coupling with various oligoaryl and oligoheteroaryl boronic acids to obtain the 2,2, 7,7 -tetraarylated derivatives 33. 

Remarkably, one year later Leadbeater described that biaryls can be synthesized via a Suzuki-type coupling under transition-metal free conditions [51, 52]. The reaction conditions were almost identical to those reported for the ligand-free process, with the difference being that a larger amoimt of Na2C03 and arylboronic acid were used. Only one successful example of a heteroaryl haUde substrate is shown namely, the coupling of 2-bromopyridine with phenylboronic acid (Scheme 32). 3-Bromothiophene did not couple under the same reaction conditions. Unfortimately, attempts to use heteroarylboronic acids such as 3-pyridinylboronic acid, 3-thienylboronic acid, and lH-indol-5-ylboronic acid on 4-bromoacetophenone completely failed. 

Early 2005, Leadbeater s team reported that the previously claimed tran-sition-metal-free Suzuki-type protocol was definitely palladium-catalyzed [ 53 ]. Palladium contaminants down to the level of 50 ppb found in commercially available sodium carbonate were responsible for the generation of the biaryl. For good product yields in a short reaction time under microwave irradiation, a loading of 1 ppm Pd was required. 

A drawback of the Heck-type reaction is that it is not strictly regioselective [119]. Depending on the substituents >1% of 1,1-diarylation is observed. Soluble 2,5-dialkoxy-PPVs 63 or 2-phenyl-PPV PPPV 93, without 1,1-diarylated moieties, were synthesized by Heitz et al. in a Suzuki-type cross coupling of substituted 1,4-phenylenediboronic acids and fran5-l,2-dibromoethylene, catalyzed by Pd(0) compounds [120]. However, about 3% of biaryl defect structures are observed in the coupling products (M up to 12,000), resulting from homocoupling of boronic acid functions. 

In 1996, Wegner et al. published the synthesis of poly(oligophenylenevinyle-ne)s (96), consisting of biphenylene-, terphenylene- and quinquephenylene moieties as aromatic building blocks, via Suzuki-type aryl-aryl cross coupling of AA/BB-type monomers [121]. By judicious choice of the arylene moieties, the optical properties of the resulting polymers can be tailored within a wide range. 

Phenyltrimethoxysilane 75 is activated by fluoride anion to 76, which undergoes palladium-catalyzed couphng with 4-methyliodobenzene 77 to give a nearly quantitative yield of 4-methyldiphenyl 78 [90]. Such Heck-, Stille-, or Suzuki-type C-C coupling of arylsilanes such as 75 were recently reviewed [91] (Scheme 2.12). 

To mention a few synthetic appHcations of trialkylsilanols, trimethylsilanol 4 adds readily to 2-chloroacrylonitrile in diethyl ether in the presence of triethylamine as triethylammonium trimethylsilanolate followed by ehmination of triethylamine hydrochloride to give 99 [32] (cf. discussion of the strongly nucleophihc properties of ammonium trimethylsilanolate 155 in Section 4.2.1). The stable potassium trimethylsilanolate 97 has also been used for the saponification of esters (Section 4.7). Dimethylphenylsilanol 100 adds readily to a,y9-unsaturated carbonyl compounds such as methyl vinyl ketone 764 in the presence of Pd(OAc)2 in a Heck-Suzuki-type reaction to give the sihcon-free /9-phenylmethylvinylketone 101 [33]. 

Nickel can also be used in place of Pd in Suzuki-type couplings of boronic acids. The main advantage of nickel in this application is that it reacts more readily with aryl chlorides275 and methanesulfonates276 than do the Pd systems. These reactants may be more economical than iodides or triflates in large-scale syntheses. 

A potentially interesting development is the microwave-assisted transition-metal-free Sonogashira-type coupling reaction (Eq. 4.10). The reactions were performed in water without the use of copper(I) or a transition metal-phosphine complex. A variety of different aryl and hetero-aryl halides were reactive in water.25a The amount of palladium or copper present in the reaction system was determined to be less than 1 ppm by AAS-MS technique. However, in view of the recent reassessment of a similarly claimed transition-metal-free Suzuki-type coupling reaction, the possibility of a sub-ppm level of palladium contaminants found in commercially available sodium carbonate needs to be ruled out by a more sensitive analytical method.25 ... 

Recently, Suzuki-type reactions in air and water have also been studied, first by Li and co-workers.117 They found that the Suzuki reaction proceeded smoothly in water under an atmosphere of air with either Pd(OAc)2 or Pd/C as catalyst (Eq. 6.36). Interestingly, the presence of phosphine ligands prevented the reaction. Subsequently, Suzuki-type reactions in air and water have been investigated under a variety of systems. These include the use of oxime-derived palladacycles118 and tuned catalysts (TunaCat).119 A preformed oxime-carbapalladacycle complex covalently anchored onto mercaptopropyl-modified silica is highly active (>99%) for the Suzuki reaction of p-chloroacetophenone and phenylboronic acid in water no leaching occurs and the same catalyst sample can be reused eight times without decreased activity.120... 

Suzuki-type Pd(0) coupling reactions have been used for the synthesis of 2-arylpurines <06BMCL3144>. 

Scheme 6.25 Suzuki-type couplings involving boroxarophenanthrenes.

Scheme 6.26 Suzuki-type couplings for the preparation of fluorescent dyes.

Scheme 6.27 Semiconducting polymers via Suzuki-type couplings.

Scheme 7.80 Fluorous phase Suzuki-type couplings.

The described fluorous-tag strategy has also been applied to the synthesis of biaryl-substituted hydantoins (Scheme 7.81) [94]. 4-Hydroxybenzaldehyde was converted into the corresponding perfluorinated species, which was then subjected to a reductive amination. The resulting amine was treated with an isocyanate to produce the fluorous-tagged urea, which spontaneously cyclized to form the corresponding hydantoin. Finally, the fluorous tag was detached by a Suzuki-type carbon-carbon bond formation to furnish the desired target structure in good yield. 

Rollin et al 5 have applied those direct coupling conditions in a Suzuki-type process-using p-methoxyphenyl boronic acid and CuTc-to three carbohydrate-based OZTs but the coupling reaction only resulted in moderate yields (42%-47%). Using the same thionocarbamates, a direct Stille... 

The first report of all-phenylene dendrimers was presented in 1990 by Miller and Neenan [10], Via a convergent approach, they coupled arylboronic acids to arylbromides under Suzuki-type conditions to synthesize the first two generations of polyphenylene dendrimers based on 1,3,5-triphenylene building units (Scheme 1). 

Suzuki type coupling reactions (Figure 34) were performed by He et al. [62,63] in three different reactor types (Figure 32,33). Two consisted of plates and the third one was a U-type reactor prepacked with catalyst. 

R = Bu, CH(Oa>2, CH(OAc)CHj Figure 20 Suzuki-type cross coupling reaction. 

Leadbeater, N.E. and Marco, M., Transition-metal-free Suzuki-type coupling reactions, Angew. Chem., Int. Ed. Engl, 2003,115, 1445-1447. 

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