Tetrabutylammonium bromide catalyst

The synthesis of some new substituted thieno[2,3-Z>]thiophenes (369)-(372) has been achieved <93BCJ201l> in a one-pot reaction employing solid-liquid phase transfer catalysis (PTC) conditions (K2C03, benzene, tetrabutylammonium bromide catalyst) and starting from acetylacetone, CS2, and a-chloro compounds in 1 1 2 molar ratio. The reaction of acetylacetone and CS2 with ethyl chloroacetate, chloroacetonitrile, 2-(chloroacetylamino)thiazole, or chloroacetanilide was carried out under PTC conditions by stirring the reactants reaction times and temperatures were optimized. The corresponding thieno[2,3-6]thiophenes (369)-(372) were obtained in excellent yields (51-93%). 

Under phase transfer conditions (tetrabutylammonium bromide catalyst) butyl bromide was found to alkylate 2- and 4-hydroxypyridines at both O and N with alkylation at the latter predominating. A variety of alterations in reaction conditions (salts, solvent, temperature) did not profoundly affect the product distribution. This finding is in apparent contrast to the findings reported in section 15.4. 

Pha.se-Tra.nsfer Ca.ta.lysts, Many quaternaries have been used as phase-transfer catalysts. A phase-transfer catalyst (PTC) increases the rate of reaction between reactants in different solvent phases. Usually, water is one phase and a water-iminiscible organic solvent is the other. An extensive amount has been pubHshed on the subject of phase-transfer catalysts (233). Both the industrial appHcations in commercial manufacturing processes (243) and their synthesis (244) have been reviewed. Common quaternaries employed as phase-transfer agents include benzyltriethylammonium chloride [56-37-17, tetrabutylammonium bromide [1643-19-2] tributylmethylammonium chloride [56375-79-2] and hexadecylpyridinium chloride [123-03-5]. 

Similarly to classical PTC reaction conditions, under solid-liquid PTC conditions with use of microwaves the role of catalyst is very important. On several occasions it has been found that in the absence of a catalyst the reaction proceeds very slowly or not at all. The need to use a phase-transfer catalyst implies also the application of at least one liquid component (i.e. the electrophilic reagent or solvent). It has been shown [9] that ion-pair exchange between the catalyst and nucleophilic anions proceeds efficiently only in the presence of a liquid phase. During investigation of the formation of tetrabutylammonium benzoate from potassium benzoate and tetrabu-tylammonium bromide, and the thermal effects related to it under the action of microwave irradiation, it was shown that potassium benzoate did not absorb micro-waves significantly (Fig. 5.1, curves a and b). Even in the presence of tetrabutylammonium bromide (TBAB) the temperature increase for solid potassium benzoate... 

The use of larger than normal quantities of catalyst leads to some surprising results. The elimination reaction of (2-bromoethyl)benzene in the presence of toluene and aqueous sodium hydroxide is catalysed by the presence of tetrabutylammonium bromide [48]. 

The utilization of polar polymers and novel N-alkyl-4-(N, N -dialklamino)pyridinium sedts as stable phase transfer catalysts for nucleophilic aromatic substitution are reported. Polar polymers such as poly (ethylene glycol) or polyvinylpyrrolidone are thermally stable, but provide only slow rates. The dialkylaminopyridininium salts are very active catalysts, and are up to 100 times more stable than tetrabutylammonium bromide, allowing recovery and reuse of catalyst. The utilization of b is-dialkylaminopypridinium salts for phase-transfer catalyzed nucleophilic substitution by bisphenoxides leads to enhanced rates, and the requirement of less catalyst. Experimental details are provided. 

In an extension of this work, the reuse of the polymeric catalyst was addressed and several new PE-poly(alkene) glycol copolymers were prepared [68]. Commercially available oxidized polyethylene (CO2H terminated, both high and low molecular weight) was converted to the acid chloride and reacted with Jeffamine D or Jeffamine EDR, and subsequently converted to the tributylammonium bromide salt with butyl bromide. These new quaternary salts were shown to catalyze the nucleophihc substitution of 1,6-dibromohexane with sodium cyanide or sodium iodide. While none of the polymeric quaternary salts catalyzed the reaction as well as tetrabutylammonium bromide, the temperature-dependent solubility of the polymers allowed removal of the polymer by simple filtration. 

Condensed derivatives have also been prepared. Reaction of 2-aminothi-azoles with 2,3-dichloro-l,4-naphthoquinone yields naphth[2,3-h]im-idazo[2,l-h]thiazole-5,10-dienones 62 via thiazolylaminoquinones 61. Cycli-zation can be effected either with diethylaniline (method a) [77IJC(B)356] or with sodium hydroxide and tetrabutylammonium bromide (TBAB) catalyst (method b) (82H333). Following route b, compound 62 (R = Et) can be isolated in 92% yield. Reactions between 2-aminothiazoles and chloranil leading to dithiazolobenzobisimidazolediones have also been reported [79IJC(B)523]. 

In a 500 ml flat-bottomed three-necked flask, equipped with a powerful stirrer, dropping funnel, nitrogen inlet,and bubble counter are placed successively 0.93 g (5 mmol) of bisphenol A, 1.0 g of tetrabutylammonium bromide (phase transfer catalyst), and... 

The synthesis of anastrozole (Scheme 3.3) began with an 8 2 displacement of commercially available 3,5-fc (bromomethyl)toluene (19) using potassium nitrile and a phase-transfer catalyst, tetrabutylammonium bromide (Edwards and Large, 1990). The resulting fcw-nitrile 20 in DMF was then deprotonated with sodium hydride in the presence of excess methyl iodide to give the fc -dimethylated product 21. Subsequently, a Wohl-Ziegler reaction on 21 was carried out using A-bromosuccinamide (NBS), and a catalytic amount of benzoyl peroxide (BPO) as the radical initiator. Finally, an Sn2 displacement of benzyl bromide 22 with sodium triazole in DMF afforded anastrozole (2) as a white solid. 

Alkylation of 2,4-disubstituted-5(477)-oxazolones can be conveniently performed via phase-transfer catalysis. For example, the substrate and an alkyl halide are dissolved in an organic solvent and stirred with an aqueous sodium carbonate solution containing tetrabutylammonium bromide as a phase-transfer catalyst. 4,4-(Diarylmethyl)-2-phenyl-5(4/f)-oxazolones can be prepared in one-step by dialkylation of 146 using magnesium methyl carbonate and the corresponding... 

A potential way to avoid the formation of undesired side products, like in 7.2., is the use of such boron compounds that have only one transferable group. In most cases boronic acids are the compounds of choice, as they are easy to prepare, insensitive to moisture and air, and usually form crystalline solids. In certain cases, however the transmetalation of the heteroaryl group might be hindered by the formation of stable hydrogen bonded complexes. In such cases the use of a boronate ester, such as in equation 7.4., provides better yields. For example pyridine-2-boronic acid dimethylester coupled readily with a bromoquinoline derivative under conditions similar to 7.3. (potassium hydroxide was used as base and tetrabutylammonium bromide as phase transfer catalyst).6... 

DetkioketaKzation. Various thioacetals and thioketals are readily hydrolyzed by pyridinium bromide perbromide (1 equivalent) under phase-transfer conditions. Tetrabutylammonium bromide is used as catalyst and aqueous methylene chloride as solvent. The reaction is more efficient in the presence of pyridine as buffer. Yields are generally 75-90%.1... 

The use of mixtures of sodium hydroxide and benzyltrimethylammonium chloride or tetrabutylammonium bromide failed to enhance the DPGE alkylation of HEC by the in situ formation of the corresponding quaternary ammonium hydroxide phase transfer catalyst. These quaternary ammonium halides are too soluble in aqueous /-butyl alcohol and are preferentially extracted into the organic phase. Mixtures of benzyltrimethylammonium hydroxide and sodium acetate were also ineffective in enhancing the DPGE alkylation of HEC for the same reason, namely preferential solubility of benzyltrimethylammonium acetate in the organic phase. 

The capture of 4,6-dichloro-2-(methylthio)pyrimidine (8) was performed in DMF with diisopropylethylamine (DIPEA, Huenig s base) as a base and tetrabutylammonium bromide as a catalyst at 90°. The substitution of the remaining chlorine atom on the polymer-bound scaffold requires harsher conditions. Thus the immobilized 6-chlorothiomethylpyrimidine (9) could be substituted with aliphatic amines in neat amine at 140°. The coupling with anilines could be afforded consistently only by using KO Bu as base and [18]crown-6. Also, the use of Pd catalysts gave positive results, but failures were observed occasionally. Finally, the substitution of the thiomethyl group in resin-bound 2-(methylthio)pyrimidine-4,6-diamines... 

The phase-transfer technique is a simple and efficient tool for the benzylation of carbohydrates. With benzyltriethylammonium chloride or tetrabutylammonium bromide as a catalyst, a mixture of aqueous, 50 % sodium hydroxide and benzyl bromide or chloride in benzene or dichloromethane solution gives a good yield of the fully protected product [103, 104], such as methyl 2,3-di-0-benzyl-4,6-0-benzylidene c-D-glucopyranoside, when stirred at room temperature for several hours. The latter catalyst is slightly more efficient. Dichloromethane has been observed to produce methylene acetals from cis vicinal diols under comparable conditions [103]. 

The phase-transfer-catalyzed asymmetric alkylation of 1 has usually been performed with achiral alkyl halides, and hence the stereochemistry of the reaction with chiral electrophiles has scarcely been addressed. Nevertheless, several groups have tackled this problem. Zhu and coworkers examined the alkylation of 1 with stereo-chemically defined (5S)-N-benzyloxycarbonyl-5-iodomethyl oxazolidine using 4d to prepare (2S,4R)-4-hydroxyornithine for the total synthesis of Biphenomycin. Unexpectedly, however, product 7 with a 2 R absolute configuration was formed as a major isomer, and the diastereomeric ratio was not affected by switching the catalyst to pseudoenantiomeric 2d and even to achiral tetrabutylammonium bromide (TBAB), indicating that the asymmetric induction was dictated by the substrate (Scheme 2.3) [21]. 

Upon facing the difficulty of stereochemical control in peptide alkylation events, Maruoka and coworkers envisaged that the chiral phase-transfer catalyst should play a crucial role in achieving an efficient chirality transfer, and consequently examined the alkylation of the dipeptide, Gly-L-Phe derivative 57 (Scheme 5.28) [31]. When a mixture of 57 and tetrabutylammonium bromide (TBAB, 2 mol%) in toluene was treated with a 50% KOH aqueous solution and benzyl bromide at 0°C for 4h, the corresponding benzylation product 58 was obtained in 85% yield with the diastereo-meric ratio (DL-58 LL-58) of 54 46 (8% de). In contrast, the reaction with chiral quaternary ammonium bromide (S,S)-lc under similar conditions gave rise to 58 with 55% de. The preferential formation of LL-58 in lower de in the reaction with (R,R)-lc indicated that (R,R)-lc is a mismatched catalyst for this diastereofacial differentiation of 57. Changing the 3,3 -aromatic substituent (Ar) of the catalyst 1 dramatically increased the stereoselectivity, and almost complete diastereocontrol was realized with (S,S)-lg. 

Benzylations reaction using TBAB (tetrabutylammonium bromide) as a phase-transfer catalyst in glass microchannel reactors has been investigated as well [215], A dichloromethane/aqueous biphasic system was used in which both the substrate... 

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