Carboxylic acids reaction with organolithium compounds

The most general synthetic route to ketones uses the reaction of carboxylic acids (or their derivatives) or nitriles with organometallic compounds (M.J. Jorgenson, 1970). Lithium car-boxylates react with organolithium compounds to give stable gem-diolates, which are decom-... 

The reactions of several carboxylic acid derivatives with organomagnesium and organolithium compounds were described in Section 14-12. The key step in these reactions is addition of the organometallic compound, as R60MS , to the carbonyl group. For a Grignard reagent,... 

Acyl anions (RC(=0)M) are unstable, and quickly dimerize at temperatures >-100 °C (Section 5.4.7). These intermediates are best generated by reaction of organolithium compounds or cuprates with carbon monoxide at -110 °C and should be trapped immediately by an electrophile [344—347]. Metalated formic acid esters (R0C(=0)M) have been generated as intermediates by treatment of alcoholates with carbon monoxide, and can either be protonated to yield formic acid esters, or left to rearrange to carboxylates (R0C(=0)M —> RC02M) (Scheme 5.38) [348]. Related intermediates are presumably also formed by treatment of alcohols with formamide acetals (Scheme 5.38) [349]. More stable than acyl lithium compounds are acyl silanes or transition metal acyl complexes, which can also be used to perform nucleophilic acylations [350],... 

CARBONYL ADDITIONS, CERIUM(III) CHLORIDE-PROMOTED, 76, 237 Carbonyl compounds, reactions with organolithiums or Grignard reagents, 76, 228 Carboxylic acid amides, 77, 27 Cells, storage of, 76, 80 Centrifugation, 76, 78... 

Although the early literature records a number of examples of the synthesis of ketones by reactions of Grignard reagents with carboxylic acids or metal carboxylates [A], this method has been generally found less satisfactory than the corresponding reaction of organolithium compounds [G, 13]. However, it has been reported that reactions of halomagnesium... 

Addition reactions. a,0-Unsaturated carbonyl compounds 1 and 3 undergo exclusive 1,4-addition reactions with organolithium (and organomagnesium) compounds owing to steric hindrance of the carbonyl group. The adducts 2 and 4 are converted into carboxylic acids by cleavage with potassium t-butoxide and H2O in the case of 2 see potassium r-hutoxidc, this volume) and by treatment with ethanolic... 

It might be expected that in the presence of TMEDA or other tertiary diamines anomalous reaction products might be obtained with organolithium compounds such as benzyllithium. A number of reports in the literature disclose instances of the expected reaction products from reactions such as carbonation to the carboxylic acid and addition to benzophenone (I, 3, 4, 12). The phenyllithium-TMEDA (1 1) complex in benzene was allowed to react with benzophenone to give a 95% yield of triphenylcarbinol and with cyclohexanone to yield 59% of the 1-phenylcyclohexanol. The reaction with excess trimethylsilyl chloride is apparently quantitative. The main consideration in using these complexes is to use low temperatures for reaction and aqueous washes of ammonium chloride solution in the work-up to remove all of the tertiary diamine (the odor can be detected in low concentrations.)... 

In the synthesis directed towards lincosamine, Szechner [32] utilized a known reaction [33] of lithium salts of carboxylic acids with organolithium compounds (Scheme 14). 

The reactions of carbon dioxide and carbon disulfide with organoUthium reagents have attracted much attention and have been applied in various organic synthesis. Reaction of carbon dioxide with organolithium compounds normally affords carboxylic acids after hydrolysis [50]. The formation of unsymmetrical ketones was reported from the reaction of CO2 and two organolithium compounds via an intermolecular reaction pathway [51]. When 1,4-dilithio-l,3-dienes 1 was treated with CO2, cyclopentadienone derivatives 20 with various substituents could be prepared in high yields in one-pot within several minutes via cleavage of one of the C=0 double bonds (Scheme 10) [52]. The experimental results indicate that this intermolecular reaction pattern affords cyclopentadienones in the reaction mixture before hydrolysis. 

Eunctionalized organolithium compounds, having a protected carboxylic acid functionality, can also be considered as masked lithium tris-homoenolates and were prepared by DTBB-catalyzed (5%) Uthiation of the corresponding )-chlorinated materials. Eor instance, compound 227 in THE at —78°C leads to the expected organoUthium intermediate 228, which reacts with a series of electrophiles present in the reaction medium... 

Carboxylic acid groups can also be installed in molecules using the reaction of an organometallic compound with carbon dioxide. This is a reductive method since the carbon dioxide is reduced to a carboxylic acid by formation of a new carbon-carbon bond. Both Grignard reagents and organolithium compounds work well in this reaction. 

The Weinreb amide syntheses in Figure 6.50 proceeding via the stable tetrahedral intermediates B and F are chemoselective SN reactions at the carboxyl carbon atom of carbon acid derivatives that are based on strategy 1 of the chemistry of carboxylic acid derivatives outlined in Figure 6.41. Strategy 2 of the chemistry of carboxylic acid derivatives in Figure 6.41 also has a counterpart in carbon acid derivatives, as is demonstrated by a chemoselective acylation of an organolithium compound with chloroformic acid methyl ester in this chapter s final example ... 

Alcohols, aldehydes, ketones and carboxylic acids can be prepared from Grignard reagents. ArMgBr, and organolithium compounds, ArLi. by reaction with molecules with an electron-delicieni site. 

The carbonation of pol3meric anions using carbon dio.xide is one of the most useful and widely used functionalization reactions. However, there are special problems associated with the carbonation of polymeric organolithium compounds . For example, Wyman, Allen and Altares reported that the carbonation of poly-(styryl)lithium in benzene with gaseous carbon dioxide produced only a 60% yield of carboxylic acid the acid was contaminated vrith significant amounts of the corresponding ketone(dimer) and tertiary alcohol(trimer) as shown in Eq. (70). 

---