Bromoacetic acid derivatives

The processes involving the aziridine cycle are very diverse. For instance, reactions of alkylation by alkyl halogenides [63], bromoacetic acid derivatives [29, 30] and acetoxypropene [64], are known. The use of arylboronic acids for synthesis of TV-alkyl derivatives, e.g., compound 45, is described in [63] (Scheme 1.13). The one-step reaction at room temperature of aziridinyl ketones 46 with chloroacetamides 47 and sulfur in the presence of Et3N yields mono-thio-oxamidines 48 [65]. 

GooUen has also reported a palladium-catalyzed cross<oupling reaction between aryl boronic acids or esters and a-bromoacetic acid derivatives which allows the synthesis of various substituted aryl acetic acid derivatives in good to excellent yields under mild conditions [72]. Aryl boronic acids with a range of electron-withdrawing and -donating substituents are tolerated in this reaction (Scheme 3.50). 

Scheme 3.50 Palladium-catalyzed cross-coupling of aryl boronic acids and boronates with a-bromoacetic acid derivatives.

Lehn and his coworkers have prepared a number of chiral cryptands based upon the 2,2 -binaphthyl unit " . In a typical preparation, the binaphthyl units are treated with bromoacetic acid to form the phenoxyacetic acid derivatives which are then converted into the corresponding diacyl chlorides (75). Reaction of 15 with l,10-diaza-18-... 

Alkylation of ll-mercaptopyrido[l,2-h]cinnolin-6-ium hydroxide inner salts (e.g., 41) with ethyl bromoacetate gave ll-(ethoxycarbonylmethyl(thio derivatives 64 (R = H), which could be hydrolyzed to the ll-(carboxy-methyl)thio derivative or back to the starting compound 41 (74JHC125). Hydrolysis of the ll-bis(methoxycarbonyl)methylene 66 (R = H), and 2-cyano derivatives of 17 (R = H) in boiling HCl afforded 11-methyl and 2-carboxylic acid derivatives, respectively (74JHC125). The 2-nitro derivative of 17 (R = H) was reduced to the 2-amino derivative over Pd/C with NaBH4 in aqueous methanol, and the 2-amino group was acylated with acetic anhydride at 100°C. 

Homologation via a-Haloenolates. Organoboranes can also be used to construct carbon-carbon bonds by several other types of reactions that involve migration of a boron substituent to carbon. One such reaction involves a-halocarbonyl compounds.19 For example, ethyl bromoacetate reacts with trialkylboranes in the presence of base to give alkylated acetic acid derivatives in excellent yield. The reaction is most efficiently carried out with a 9-BBN derivative. These reactions can also be effected with B-alkenyl derivatives of 9-BBN to give /i,y-unsaturatcd esters.20... 

SH Acetanhydride Bromoacetic acid and derivatives Chloroacetic acid and derivatives Dansylchloride lodoacetamide N-Ethylmaleinimide p-Chlormercuribenzoic acid Acetanhydride... 

Lipo-amino acid derivatives are readily obtained in good yields by direct alkylation of amino acids esters with the related alkyl halides, e.g. farnesyl bromide, under careful control of the reaction conditions to avoid exhaustive alkylation of the amino group. 128 Alternatively, peptoid chemistry is applied for N-alkylation of glycine ester via reaction of alkyl amines, e.g. hexadecylamine, with ethyl bromoacetate. 36,98 ... 

All four isomeric selenolopyridines which can be derived from benzoselenophene (423— 426 Scheme 123) have been described. Ethyl 3-hydroxyselenolo[2,3-fe]pyridine-2-carboxy-late (429) has been prepared as shown in Scheme 124 (73BSF704). Treatment of ethyl 2-chloropyridine-3-carboxylate with methaneselenol yields (427). Nucleophilic displacement of bromine in bromoacetic acid with subsequent loss of methyl bromide yields (428), which after esterification is cyclized under Dieckmann conditions to give (429). The parent compound (423 colorless oil with b.p. 92 °C/1 mmHg) is prepared either by cyclization of compound (430) and subsequent decarboxylation of the intermediate acid (equation 57) or by reduction of 2-nitroselenophene and subsequent condensation of the amino compound with malonaldehyde bis(diethyl acetal) in the presence of zinc chloride (equation 58) (76BSF883). Selenolo[3,2-6]pyridine (426 b.p. 127-129°C/10 mmHg m.p. 35.5-37.0°C) has been obtained in an analogous manner. 

Secondary aliphatic amines reacted readily with mercaptoaldimines (279), which could be prepared readily by the action of Na/NH3 on the aldehyde diacetals (278). The resulting N,N- dialkyl derivatives (280) were alkylated on sulfur by a-halocarbonyl compounds such as bromoacetic acid the resulting products (281) underwent spontaneous ring closure and aromatization via loss of the secondary amine to yield the acids (282 Scheme 97). Decarboxylation of the acids (282) furnished the substituted thieno[2,3-6 ]thiophenes (283). The use of other a-halocarbonyl compounds, such as bromoacetone or phenacyl bromide for the alkylation, led to the formation of the 2-acetyl or 2-benzoyl derivatives, (284) and (285) respectively (76AHC(19)123). 

Calixarene esters are easily available by alkylation with ethyl bromoacetate and are often used as starting materials for the introduction of chiral groups at the narrow rim. Their aminolysis by chiral amines led to chiral calixarene derivatives in high yields. Water soluble calix[4]arene amino acid derivatives 9a,b obtained in this way, were successfully used as a pseudostationary phase... 

The G 2 amine termini were converted into carboxylic acid and isothiocyanate derivatives by reacting with bromoacetic acid and thiophosgene, respectively, as illustrated below in Eq. la and Eq. lb, respectively ... 

In addition, there exists a group of carboxylic acid functionalised carbene ligands that have the appearance of being derived from the amino acid glycine, but their synthesis was actually achieved by quartemising N-substituted imidazole with a bromoacetic acid ester [71,72], A representative example for this synthetic route is presented in Figure 6.29. 

Several routes exist for the synthesis of amides of halo acids. Cuatrecasas et al. (1969) used two different bromoacetylating reagents in the synthesis of water soluble inhibitors of staphylococcal nuclease. The N-hydroxysuccinimide ester of bromoacetate was one of the reagents used. It is particularly useful for the synthesis of radioactive derivatives since C-bromoacetic acid is commercially available. Synthesis of the hydroxysuccininimide ester is accomplished by dissolving 87 mg (630 /imoles) of bromoacetic acid and 86 mg of N-hydroxysuccinimide in 3 ml of dioxane. To this solution, 132 mg (700 /imoles) of dicyclohexylcarbodiimide is added. Urea precipitates immediately and after 1 hr, is removed. The solution of bromoacetyl N-hydroxysuccinimide ester is brought to 5 ml. It can then be used without any further purification. 

Chase and Tubbs (1969) prepared the bromoacetate ester of carnitine by taking the appropriate enantiomer of carnitine chloride, dissolving it in bromoacetic acid at 53°C and heating it with an excess of bromoacetyl bromide for 4 hr. Excess bromoacetic acid and bromoacetyl bromide was removed by distillation in vacuo. The residue was dissolved in absolute ethanol and precipitated by ether. The derivatives can be recrystallized from butanol. 

Recently, ionic liquids with amino acids as anions were synthesized by neutralization between [C2mim][OH] and amino acids [88], Tetrabutylphosphonium amino acids [P(C4)4][AA] were synthesized by the reaction of tetrabutylphosphonium hydroxide [P(C4)4][OH] with amino acids, including glycine, L-alanine, l-/1-alanine, L-serine and L-lysine [89], The esters or amide derivatives of bromoacetic acid were either commercially available or formed in one step via the reaction of bromoacetyl bromide with the appropriate alcohol or amine [90-92], An advantage of this route is that a wide range of ester and amide side chains can be prepared easily. For ionic liquids with anions other than bromide, a metathesis reaction was employed to introduce the counter ion of choice. Additionally, functionalized ionic liquids with electrophilic alkene-type appendages were synthesized. 

M-Acetylsaccharinyl acid derivatives 408, which are structurally related to COX-2 inhibitor celecoxib, were designed and synthesised [133] from M-saccharinyl acetate 407a, prepared via the reaction of ethyl bromoacetate with sodium saccharin by heating the reactants in DMF (see [133]). Its transformation into the corresponding hydrazide 407b and subsequent reaction with ethyl acetoacetate, /3-diketones and maleic anhydride, afforded the heterocyclic compounds 408 [134] (Scheme 97). 

---