Carboxylation, indirect

Ketones of the form RCOCH3 and RCOCH2R can be carboxylated indirectly by... 

Ketones of the form RCOCH3 and RCOCH2R can be carboxylated indirectly by treatment with magnesium methyl carbonate 52.613 Because formation of the chelate 53 provides the driving force of the reaction, carboxylation cannot be achieved at a disubstituted a position. The reaction has also been performed on CH3N02 and compounds of the form RCH2N02614 and on certain lactones.61s Direct carboxylation has been reported in a number of instances. Ketones have been carboxylated in the a position to give (3-keto acids.616 The base here was lithium 4-methyl-2,6-di-f-butylphenoxide. 

Carboxyl (indirect) Carboxyl (direct) Phenolic (indirect) Phenolic (direct)... 

Let s first consider how to prepare an aldehyde from a carboxylic acid There are no good methods for going from RCO2H to RCHO directly Instead we do it indirectly... 

Carboxylate soaps are most commonly formed through either direct or indirect reaction of aqueous caustic soda, ie, alkaH earth metal hydroxides such as NaOH, with fats and oils from natural sources, ie, triglycerides. Fats and oils are typically composed of both saturated and unsaturated fatty acid molecules containing between 8 and 20 carbons randomly linked through ester bonds to a glycerol [56-81-5] backbone. Overall, the reaction of caustic with triglyceride yields glycerol (qv) and soap in a reaction known as saponification. The reaction is shown in equation 1. 

Indirect detection of an intermediate. The overall reaction of hydroxylamine with a carboxylic acid derivative yields a hydroxamic acid as the product, Eq. (3-176). 

The influence of pH on the affinity of Hb for oxygen known as the Bohr-effect indicates that protons retain the allosteric regulation of oxygen transport. It is also an indirect confirmation of the ability of Hb and Im Hb for transporting carbon dioxide. The values of the Bohr-effect d log P50/d pH for Hb and Im Hb are close to each other in the pH range 7.1-7.4. It is possible that the effect of the micro-environment of carboxylic CP on immobilized Hb and its polyfunctional interaction represents the interaction between Hb and the structural elements inside the red cell [99]. 

The alkyl group R of certain carboxylic esters can be reduced to RH by treatment with lithium in ethylamine. The reaction is successful when R is a tertiary or a sterically hindered secondary alkyl group. A free-radical mechanism is likely. Similar reduction, also by a free-radical mechanism, has been reported with sodium in HMPA-r-BuOH. In the latter case, tertiary R groups give high yields of RH, but primary and secondary R are converted to a mixture of RH and ROH. Both of these methods provide an indirect method of accomplishing 10-81 for tertiary R. 

Compounds 137 and 138 are thus synthons for carboxylic acids this is another indirect method for the a alkylation of a carboxylic acid, representing an alternative to the malonic ester synthesis (10-104) and to 10-106 and 10-109. The method can be adapted to the preparation of optically active carboxylic acids by the use of a chiral reagent. Note that, unlike 132, 137 can be alkylated even if R is alkyl. However, the C=N bond of 137 and 138 cannot be effectively reduced, so that aldehyde synthesis is not feasible here. ... 

The alkylation of activated halogen compounds is one of several reactions of trialkylboranes developed by Brown (see also 15-16,15-25,18-31-18-40, etc.). These compounds are extremely versatile and can be used for the preparation of many types of compounds. In this reaction, for example, an alkene (through the BR3 prepared from it) can be coupled to a ketone, a nitrile, a carboxylic ester, or a sulfonyl derivative. Note that this is still another indirect way to alkylate a ketone (see 10-105) or a carboxylic acid (see 10-106), and provides an additional alternative to the malonic ester and acetoacetic ester syntheses (10-104). 

Ketones can also be obtained by treatment of the lithium salt of a carboxylic acid with an alkyllithium reagent (16-31). For an indirect way to convert carboxylic esters to ketones, see 16-33. 

An indirect method ° of double-bond reduction involves hydrolysis of boranes (prepared by 15-16). Trialkylboranes can be hydrolyzed by refluxing with carboxylic acids,while monoalkylboranes RBH2 can be hydrolyzed with base. ° Triple bonds can be similarly reduced, to cis alkenes. °... 

Direct elimination of a carboxylic acid to an alkene has been accomplished by heating in the presence of palladium catalysts.Carboxylic esters in which the alkyl group has a P hydrogen can be pyrolyzed, most often in the gas phase, to give the corresponding acid and an alkene. No solvent is required. Since rearrangement and other side reactions are few, the reaction is synthetically very useful and is often carried out as an indirect method of accomplishing 17-1. The yields are excellent and the work up is easy. Many alkenes have been prepared in this manner. 

Carboxylic acids can also be converted to alkanes, indirectly,by reduction of... 

Figure 4.18 A, separation of antihistanine and decongestant drugs by reversed-phase IPC. Mobile phase nethanol-water (1 1) containing 5 aM hexanesulfonate and 1 % acetic acid at a flow rate of 3 al/nin. B, separation and indirect OV detection of carboxylic acids by reversed-phase IPC. Coaponents 1 acetic acid, 2 = propionic acid, 3 butyric acid, 4 = valeric acid, 5 caproic acid, and S -. systea peak. Mobile phase 0.3 aM l-phenethyl-2-picoliniua in acetate buffer at pH 4.6.

In general, the methods for protection and deprotection of carboxylic acids and esters are not as convenient as for alcohols, aldehydes, and ketones. It is therefore common to carry potential carboxylic acids through synthetic schemes in the form of protected primary alcohols or aldehydes. The carboxylic acid can then be formed at a late stage in the synthesis by an appropriate oxidation. This strategy allows one to utilize the wider variety of alcohol and aldehyde protective groups indirectly for carboxylic acid protection. 

Since the early 1990s an increasing number of papers has been devoted to the application of CE for the analysis of both inorganic cations [906-915] and low-molecular-mass anions [915-922]. Standard CE methods have been developed and validated for determining inorganic anions (e.g. chloride, sulfate and nitrate), small carboxylic acids and metal ions that all have limited or no UV absorbance. In those situations, short UV wavelengths (190 nm) or indirect UV detection should be used. Such methods might be extended to metallic... 

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