By the Stille reaction

Table 5.13. Preparation of biaryls by the Stille reaction on insoluble supports.

Poly(p-pyridyl vinylene)s with random (equation 110) and with head-to-head (equation 111) couplings of the pyridyl units were synthesized by the Stille reaction (205). Soluble poly(l,4-phenyleneethynylene)s were prepared by the Pd(0) catdyzed cross-coupling of bis(tributylstannyl)acetylene with 2,5-dialkoxy-1,4-dibromobenzenes. (equation 112) (208)... 

As in case of other palladium-catalyzed reactions, the general mechanism of the Stille reaction is best described by a catalytic cycle—e.g. steps a) to c) ... 

The Stille reaction has been employed by a number of researchers in the sy thesis of soluble PTV derivatives [130]. Alkyl-substituted PTVs were synthesiz... 

The palladium-catalyzed cyclization of compound 138 amply demonstrates the utility of the Stille reaction as a macrocyclization method (see Scheme 37). This efficient ring closure is just one of many examples disclosed by J.E. Baldwin and his group at Oxford.58 Interestingly, compound 138 can be employed as a stereoisomeric mixture of vinylstannanes because both stereoisomers converge on the same cyclized product. To rationalize this result, it was suggested that the configuration of the vinylstannane moiety is conserved in the cyclization, but that the macrocycle resulting from the (Z)-vinylstannane stereoisomer isomerizes to the thermodynamically favored trans product under the reaction condi-... 

Our general survey of palladium in organic synthesis must now come to an end. At the very least, we hope that our brief foray into this fascinating area conveys some of the vitality that characterizes research in this area. The remainder of this chapter will address the first total synthesis of rapamycin by the Nicolaou group. This work is predicated on a novel variant of the Stille reaction. 

Let us see now what happens in a similar linear scan voltammetric experiment, but utilizing a stirred solution. Under these conditions, the bulk concentration (C0(b, t)) is maintained at a distance S by the stilling. It is not influenced by the surface electron transfer reaction (as long as the ratio of electrode area to solution volume is small). The slope of the concentration-distance profile [(CQ(b, t) — Co(0, /))/r)] is thus determined solely by the change in the surface concentration (Co(0, /)). Hence, the decrease in Co(0, t) duiing the potential scan (around E°) results in a sharp rise in the current. When a potential more negative than E by 118 mV is reached, Co(0, t) approaches zero, and a limiting current (if) is achieved ... 

The Stille reaction has developed as a popular protocol for the formation of C-C bonds due to the air- and moisture-stability as well as functional group compatibility of organotin compounds. Together with the Suzuki-Miyaura coupling it is one of the most powerful methods for the synthesis of molecules containing unsymmetrical biaryl moieties. However, despite its efficiency, this versatile reaction has slowly been displaced by other procedures that avoid the use of highly toxic organostannanes. 

The Stille reaction has been successfully applied to a number of macrocyclic ring closures.207 In a synthesis of amphidinolide A, the two major fragments were coupled via a selective Stille reaction, presumably governed by steric factors. After deprotection the ring was closed by coupling the second vinyl stannane group with an allylic acetate.208... 

Compounds 575, obtained by the Stille coupling reaction, react with PTAD to give high yields of the Diels-Alder products 576 obtained with good to excellent asymmetric induction (Equation 81) <1995SL1264>. 

Porco s pathway to complete the synthesis of (- )-kinamycin C (3) is shown in Scheme 3.8. The arylstannane 34 and the a-bromoenone 35 were efficiently coupled by a Stille reaction using tris(dibenzylideneacetone)dipalladium and triphenylarsine... 

Some of the disadvantages of the Stille reaction, e. g. the low reactivity of some substrates, separation difficulties in chromatography, and the toxicity of tin compounds, have been ameliorated by recent efforts to improve the procedure. Curran has, in a series of papers, reported the development of the concept of fluorous chemistry, in which the special solubility properties of perfluorinated or partly fluorinated reagents and solvents are put to good use [45]. In short, fluorinated solvents are well known for their insolubility in standard organic solvents or water. If a compound contains a sufficient number of fluorine atoms it will partition to the fluorous phase, if such a phase is present. An extraction procedure would thus give rise to a three-phase solution enabling ready separation of fluorinated from nonfluorinated compounds. 

In analytical chemistry there is an ever-increasing demand for rapid, sensitive, low-cost, and selective detection methods. When POCL has been employed as a detection method in combination with separation techniques, it has been shown to meet many of these requirements. Since 1977, when the first application dealing with detection of fluorophores was published [60], numerous articles have appeared in the literature [6-8], However, significant problems are still encountered with derivatization reactions, as outlined earlier. Consequently, improvements in the efficiency of labeling reactions will ultimately lead to significant improvements in the detection of these analytes by the POCL reaction. A promising trend is to apply this sensitive chemistry in other techniques, e.g., in supercritical fluid chromatography [186] and capillary electrophoresis [56-59], An alter-... 

Oxazole compounds can also be produced by use of the Stille reaction. Clapham and Sutherland describe the use of tri-2-furylphosphine/Pd2(dba)3-catalyzed Stille coupling reactions (Scheme 12) to produce a range of oxazole-containing derivatives, including 58, with an 85% yield [56]. 

In conclusion, the already rich chemistry of pyrroles is greatly expanded by the palladium reactions presented in this chapter. The abundance of both 2- and 3-pyrrolyl halides and triflates has led to many examples of high-yielding Negishi, Suzuki, Stille, Sonogashira, and Heck reactions. Noteworthy are the excellent approaches to alkynyl pyrroles and porphyrins using Sonogashira, Stille, and Suzuki reactions. 

Like most aryl halides, furyl halides and furyl triflates have been coupled with a variety of organostannanes including alkenyl, aryl, and heteroaryl stannanes in the presence of catalytic palladium. Carbamoylstannane 66 was prepared by treating lithiated piperidine with carbon monoxide and tributyltin chloride sequentially. The Stille reaction of 66 and 3-bromofuran then gave rise to amide 67 [61]. In another example, lithiation of 4,4-dimethyl-2-oxazoline followed by quenching with MesSnCl resulted in 2-(tributylstannyl)-4,4-dimethyl-2-oxazoline (68) in 70-80% yield [62], Subsequent Stille reaction of 68 with 3-bromofuran afforded 2-(3 -furyl)-4,4-dimethyl-2-oxazoline (69). 

One method for preparing imidazolylstannanes is direct metalation followed by treatment with RjSnCl [21]. l-Methyl-2-tributylstannylimidazole, derived in such manner, was coupled with 3-bromobenzylphosphonate (26) to furnish heterobiaryl phosphonate 27 [22], Under the same reaction conditions, 4-bromobenzylphosphonate led to the adduct in 69% yield, whereas only 24% yield was obtained for 2-bromobenzylphosphonate. The low yield encountered for the ortho derivative may be attributed to the steric factors to which the Stille reaction has been reported to be sensitive [23]. Heterobiaryl phosphonates such as 27 are not only substrates for the Wadsworth-Homer-Emmons reaction, but also bioisosteric analogs of the carboxylic acid group. 

Analogously, 5-tributylstannylimidazole 29 was easily obtained from the regioselective deprotonation of 1,2-disubstituted imidazole 28 at C(5) followed by treatment with tributyltin chloride [24]. In the presence of 2.6 equivalents of LiCl, the Stille reaction of 29 with aryl triflate 30 afforded the desired 1,2,5-trisubstituted imidazole 31 with 2,6-di-tert-butyl-4-methylphenol (BHT) as a radical scavenger. Reversal of the nucleophile and electrophile of the Stille reaction also provided satisfactory results. For example, the coupling reaction of 5-bromoimidazole 33, derived from imidazole 32 via a regioselective bromination at C(5), and vinylstannane 34 produced adduct 35 [24],... 

Intriguingly, the Stille coupling of quaternary pyridylstannane 12 with 2-chloropyrazine (13) proceeded to afford adduct 14 [12]. A-Methylated 3-(tributylstannyl)pyridine 12 was easily prepared by refluxing 3-(tributylstannyl)pyridine (11) with methyl tosylate in EtOAc. By contrast, only 29% yield of the coupling adduct was isolated from the Stille reaction of 3-(tributylstannyl)pyridine A-oxide and 13. 

The Stille reaction featuring bromoquinoxaline 84 and vinylstannane delivered vinylquinoxaline 85. In addition, 85 was further manipulated to a 5-aminomethylquinoxaline-2,3-dione 86 as an AMPA receptor antagonist [47]. Pd-catalyzed nucleophilic substitution on the benzene ring has also been described [48]. Thus, transformation of 5,8-diiodoquinoxalines to quinoxaline-5,8-dimalononitriles with sodium malononitrile was promoted by PdCl2,(Ph3P)2. 

After some transition time x, ca(x = 0) reaches a value of zero and no more decrease is possible. Since S still keeps increasing, the concentration gradient becomes less steep. The current can no longer be maintained by the redox reaction of A. Now, F increases steeply until another electrode process is possible (not shown in Figure 6). 

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