Carboxyl substituent groups

Hydroxyl and carboxyl substituent groups on the mixture constituents reduce the solubility of the substance in the SCF and therefore make the extraction extremely difficult. 

Carboxylic acids can be transformed into a variety of carboxylic acid derivatives in which the carboxyl -OH group has been replaced by another substituent. Acid halides, acid anhydrides, esters, and amides arc the most common such derivatives in the laboratory thioesters and acyl phosphates are common in biological molecules. 

When a carbonyl group is bonded to a substituent group that can potentially depart as a Lewis base, addition of a nucleophile to the carbonyl carbon leads to elimination and the regeneration of a carbon-oxygen double bond. Esters undergo hydrolysis with alkali hydroxides to form alkali metal salts of carboxylic acids and alcohols. Amides undergo hydrolysis with mineral acids to form carboxylic acids and amine salts. Carbamates undergo alkaline hydrolysis to form amines, carbon dioxide, and alcohols. 

As already reported in Table 6, the solubility of phosphazene polymers is strongly influenced by the nature of the substituent groups attached at the phosphorus atoms along the -P=N- skeleton. Water-solubility, for instance, can be induced in polyphosphazenes by using strongly polar substituents (e.g. methylamine [84], glucosyl [495], glyceryl [496], polyoxyethylene mono-methylether [273] or sulfonic acid [497,498] derivatives), or may be promoted by acids or bases when basic (amino substituents like ethylamine [499]) or acid (e.g. aryloxy carboxylate [499] or aryloxy hydroxylate [295]) substituents are exploited. 

Scheme 12.22 provides some examples of the oxidation of aromatic alkyl substituents to carboxylic acid groups. Entries 1 to 3 are typical oxidations of aromatic methyl groups to carboxylic acids. Entries 4 and 5 bring the carbon adjacent to the aromatic ring to the carbonyl oxidation level. 

In summary, para carboxylic acid groups remain active at all potentials in the useful range, while meta carboxylates are com-plexed with the Pt surface at positive potentials unless sheltered from the surface by ortho-substituents. Ortho-carboxylates are complexed to the Pt surface over most or all of the useful potential ranges. 

The parent molecule of the group is glycine (gly-seen) H2N—CH2—COOH. In addition to the amino group and the carboxylic acid group, the a carbon atom is bonded to two hydrogen atoms. These are the simplest possible substituents. Thus, glycine is the simplest possible a-amino acid and is a very common constituent of proteins ... 

More powerful directing groups such as those based on amides and sulphonamides are successful with pyridines as with carboxylic rings, and will not be discussed separately. The enhanced acidity of pyridine ring protons makes the simple carboxylate substituent an ideal director of lithiation in pyridine systems . The pyridinecarboxylic acids 232-234 are deprotonated with BuLi and then lithiated with an excess of LiTMP all the substitution patterns are lithiated nicotinic acid 233 is lithiated in the 4-position (Scheme 113). The method provides a valuable way of introducing substituents into the picolinic, nicotinic and isonicotinic acid series. 

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