Trifluoromethyl formation

Some articles have described synthesis of 3-trifluoromethylquinoline (271) [161-165]. Catalytic oxidative trifluoromethylation of 3-qunolineboronic acid (270) resulted in 3-trifluoromethylquinoline in 49 % yield [161]. Use Togni s reagent (272) in reaction with boronic acids 270 resulted in increase yield of 271 up to 53 % [162]. 3-Trifluoromethylquinoline was also obtained by reaction of boronic acids 270 with CF3I [163] or with trifluoromethyl sulfonium salts [164] in 87 % yield. Interaction of 3-iodoquinoline (273) with sodium trifluoromethyl formate at presence Cu and AgjO also led to compound 271 [165] (Scheme 80). 

There have been several reports of the formation of tertiary bismuthines by the action of free radicals on metallic bismuth. One method of generating the radicals iavolves cleavage of ethane or hexafluoroethane ia a radiofrequeacy glow discharge apparatus the radicals thus formed are allowed to oxidize the metal at — 196°C (53). Trimethylbismuthiae and tris(trifluoromethyl)bismuthine [5863-80-9], C BiF, have been obtained by this procedure. 

The reaction of cyclohexane-cw-1,2-dicarboxylic acid with sulfur tetrafluoride affords the correspoding cyclic ether in a 70% yield with very limited formation of the bis(trifluoromethyl) derivative [2IJ] (equation 107)... 

In contrast to molecular fluorine, trifluoromethyl hypofluonte has limited synthetic value for geminal fluorination of diazoketones owing to formation of complex mixtures [97]... 

Trifluoromethyl groups are very resistant to hydrolysis, unless they are allylic or benzylic, or vicinal to a carbon linked to hydrogen. In the last case, elimination of hydrogen fluonde leads to the formation of a difluoromethylene group which is key to additional reactions... 

Hydrolysis of the trifluoromethyl group of 2 tnfluoiomethylimidazoles is promoted by the formation of the anion, which readily eliminates fluoride. The resultant ditluorodiazafulvene then easily adds water The remaining steps in the hydrolysis ate predictable When aqueous ammonia is used, 2-cyanoimidazoles result [40] (equation 4])... 

An unusual 1,4-migration of a trifluoromethyl group was observed when azomethine imines were synthesized from hexafluoroacetone azine and alkoxy-acetylenes The rearrangement, which occurs at temperatures as low as 0 "C, results in the formation of A-(perfluoro-ferf-butyl)pyrazoles [207] (equation 46)... 

Bischler-Napieralski reaction conditions can be attributed, again, to the destabilizing ability of the trifluoromethyl group to the cationic transition state of the acid catalyzed elimination. Formation of compound 29 was ultimately accomplished by base catalyzed methanol elimination-conditions conditions that are quite unusual for isoquinoline formation. 

For reasons discussed in Section VI, a survey of the purine series (29) is being made in this Department, but so far no example (including 2-hydroxy- and 8-trifluoromethyl-2-hydroxy-purine) of covalent hydration has come to light. An examination of ionization constants disclosed no apparent anomalies, although the interpretation is made more difficult by the ease of anion formation in the 9-position, which often competes with that from other anionic substituents. The only abnormal spectrum seems to be that of the anion of 2-mercaptopurine which is being further examined. 

A number of unusual aliphatic trifluoromethyl compounds have been obtained from 4-hexafluoroisopropylidene-2-phenyl-5-oxazolone (4) 10 The latter was prepared as shown in Eq. (2). The ease of formation... 

The hydrolysis proceeds via a diazafulvene intermediate, which in these systems can be formed without a total loss of aromatic character of the tricycle. It is tempting to suggest that, using this reasoning, linearly annelated 2-trifluoromethyl-imidazo[4,5-g]quinoline should be inert toward alkaline hydrolysis, as formation of the diazafulvene intermediate will again involve total dearomatization of the heterocyclic system (Scheme 36). 

A second reaction which is very often used for the preparation of phthalonitriles, although the yields are usually not reproducible, is the Rosenmund-von Braun reaction (see Houben-Weyl, Vol. E5, p 1460).106 107 Herein, a benzene derivative with a 1,2-dibromidc or 1,2-dich-loride unit is treated with copper(I) cyanide in dimethylformamidc or pyridine. During this reaction the formation of the respective copper phthalocyanine often occurs. This can be used as an easy procedure for the exclusive synthesis of copper phthalocyanines (see Section 2.1.1.7.),1 os-109 but can also lead to problems if the phthalonitrile is required as the product. For example, if l,2-dibromo-4-trifluoromethyl-benzene is subjected to a Rosenmund-von Braun reaction no 4-trifluoromethylphthalonitrile but only copper tetra(tri-fluoromethyljphthalocyanine is isolated.110... 

N 14.15% a deep blue solid, liq, or gas. The color of the liq is described as that of a coned ammoniacal Cu soln (Ref 2). The odor is described as earthy or similar to sewage sludge (Ref 2). Mp -196.6°, bp -84° (Refs 1 2) CA Registry No 334-99-6 Preparation. It was first isolated as a by-prod from the fluorination of Ag cyanide. Its formation was attributed to the presence of Ag nitrate or Ag oxide in the tech grade Ag cyanide used (Ref 2). The first prepn in good yield was by the irradiation in a sealed tube of a mixt of nitric oxide and trifluoromethyl iodide plus a small amt of Hg with the light from a Hg vapor lamp, yield 75% (Ref 3). 

Although there are several reports in the literature on boron-mediated amide formations, the boron reagents had to be used in stoichiometric amounts.1-4-5-6-7-8-9 Recently, Yamamoto et al. presented the first truly catalytic method allowing for a direct amide formation from free carboxylic acids and amines as the reaction partners.10-1112 Best results were obtained by using phenylboronic acids bearing electron withdrawing substituents in the meta- and/or para-positions such as 3,4,5-trifluorophenylboronic acid or 3,5-bis(trifluoromethyl)boronic acid as the catalysts. 

Operationally, however, the vast majority of the metal-containing products are those expected from the reactions already presented, namely, successive exchange of trifluoromethyl for halogen. Equations (7) and (8), for example, represent the last two steps of the formation of (CF3)4Ge. 

The trifluoromethyl-tin bond is, however, much less stable chemically (24). Reaction of, e.g., (CF3)2SnBr with an excess of the relatively covalent, methylating agent (CHaljCd results in the very slow substitution for one of the Sn-CFg bonds, but the reaction of CFaSnBr3 with an excess of the more powerful, more ionic reagent methyllithium results in the displacement of all of the ligands, and the formation of (CH3)4Sn as shown in Equations 16 and 17. 

Lipases are the enzymes for which a number of examples of a promiscuous activity have been reported. Thus, in addition to their original activity comprising hydrolysis of lipids and, generally, catalysis of the hydrolysis or formation of carboxylic esters [107], lipases have been found to catalyze not only the carbon-nitrogen bond hydrolysis/formation (in this case, acting as proteases) but also the carbon-carbon bond-forming reactions. The first example of a lipase-catalyzed Michael addition to 2-(trifluoromethyl)propenoic acid was described as early as in 1986 [108]. Michael addition of secondary amines to acrylonitrile is up to 100-fold faster in the presence of various preparations of the hpase from Candida antariica (CAL-B) than in the absence of a biocatalyst (Scheme 5.20) [109]. 

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