Nitro groups, reduction sulfonic acids

The resin-bound perfluoroalkylsulfonyl linker is compatible with many common solid-phase reactions, such as tin dichloride-mediated aromatic nitro group reduction, trifluoroacetic acid-mediated tBoc deprotection, reductive amination reactions, acylation, and sulfonation. It is possible to perform several sequential synthetic reactions on the nonflate resin so that multistep syntheses can be carried out. The solid-phase approach provides an operationally simple, inexpensive, and general protocol for the cleavage... 

According to a common procedure (aromatic nucleophilic substitution involving a binaphthyl phenol, reduction of the nitro groups, and sulfonation), a binaphthyl-containing diamine (2,2 -bis(p-aminophenoxy)-l,l -binaphthyl-6,6 -disulfonic acid (BNDADS)) has been synthesized by Li et al. [99] (Fig. 21). Binaphthyl moieties induce a kinked chain structure which is supposed to increase the polymer solubility, inhibit interchain interactions and chain packing, and therefore increase the free volume accessible to water, thus helping in the formation of the observed microphase-separated structures. 

Sodium Bisulfite. Sodium bisulfite [7631-90-5] NaHSO, is occasionally used to perform simultaneous reduction of a nitro group to an amine and the addition of a sulfonic acid group. For example, 4-amino-3-hydroxyl-l-naphthalenesulfonic acid [116-63-2] C qH NO S, is manufactured from 2-naphthol in a process which uses sodium bisulfite (59). The process involves nitrosation of 2-naphthol in aqueous medium, followed by addition of sodium bisulfite and acidification with sulfuric acid. 

Sulfonic acids are completely resistant to any reductions, and other functions contained in their molecules can be easily reduced, e,g. nitro groups with iron [692],... 

Prior to the discovery of a-sulfonation of anthraquinone, nitration was the only useful method for preparing a-substituted anthraquinones. The nitro group of a-nitroanthraquinones can be replaced in a manner similar to the sulfonic acid moiety, e.g., by chlorine atoms and amino, hydroxy, alkoxy, or mercapto groups. Reduction readily yields aminoanthraquinones. Nitration of anthraquinone has gained increasing importance because of environmental considerations, this method offering an economical alternative to a-sulfonation... 

The type of the electrochemical cell (divided or undivided) can influence the EOI values especially for the treatment of benzene derivatives containing a -NO2 substituent. A typical example is the electrochemical treatment of p-Nitro Toluene Sulfonic acid (p-NTS) low EOI values (- 0,1) were obtained in the divided cell contrary to the undivided cell where high EOI values (0,5) were obtained. The increase of EOI values in the undivided cell is due to the cathodic reduction of -NOg group to -NH2 group, this transformation promotes the electrochemical oxidation as the substituent constant (a) for -NH2 has negative value (favouring the electrophilic attack on the benzene ring) contrary to the -NO2 substituent which has positive value (see 4 i). 

Toluene-4-sulfonic acid is used as a starting material in the production of 2-chloro-5-aminotoluene-4-sulfonic add (CLT-acid). CLT-acid is manufactured by chlorination of toluene-4-sulfonic add, transformation of 2-chlorotoluene-4-sulfonic add into 2-chloro-5-nitrotoluene-4-sulfonic acid followed by the reduction of the nitro group with iron/HCl. CLT-acid is used, for example, as a raw material in the production of Pigment Red 52 1, Pigment Red 53 1 and other metal complexes. 

In summary, the reactivity of various functional groups toward Li 9-BBNH is classified into four broad categories [18] (1) rapid- or fast-reduction aldehyde, ketone, ester, lactone, acylchloride, acid anhydride, epoxide, disulfide, -alkyli-odide, and tosylate (2) slow-reduction tertiary amide, alkylbromide, and aromatic nitrile (3) sluggish-reduction carboxylic acid, aliphatic nitrile, primary amide, nitro and azoxy compounds, and secondary alkylbromide and tosylate (4) inert olefin, oxime, alkylchloride, sulfoxide, azo-compound, sulfide, sulfone, and sulfonic acid. 

Cyanoborohydride and its modified reagents have been used for reductive dehalogenations. Thus, the combination of sodium or tetrabutylammonium cyanoborohydride, sodium or potassium 9-cyano-9-hydro-9-borabicyclo[3.3.1]nonanate [9-BBNCN] (2) or polymeric cyanoborane (3) in HMPA furnishes an efficient and mild system for the reduction of alkyl halides. The reagents are selective in that other functional groups, including ester, carboxylic acid, amide, cyano, alkene, nitro, sulfone, ketone, aldehyde and epoxide, are essentially inert under the reduction conditions thus, the reduction procedure is attractive for synthetic schemes which demand minimum damage to sensitive portions of the molecule. 

Silvestri et alP showed that the reduction of the nitro sulfone 49 with iron-acetic acid led to the formation of carbohydrazide 50 with extrusion of sulfone group. Further, 50 undergoes Smiles rearrangement affording an intermediate 51, which then cyclizes to give benzimidazole 52. 

Selective reduction. A soln. of borane in tetrahydrofuran added dropwise at -18 during 19 min. to a mixture of adipic acid monoethyl ester and tetrahydrofuran, stirred and allowed to warm to room temp, during 16 hrs. -> ethyl 6-hydroxy-hexanoate. Y 75-88%. - Other functional groups such as cyano, halogeno, keto, or nitro, are likewise retained during this highly convenient reduction. F. e., also reduction of sterically hindered acids, s. N. M. Yoon, H. C. Brown et al., J. Org. Chem. 38, 2786 (1973) 2-aminoalcohols from a-aminocarboxylic acids s. M. L. Anhoury et al., Soc. Perkin 11974,191 via reduction with aq. NaBH of enolesters obtained from the acids and N-ethyl-5-phenylisoxazolium 3 -sulfonate (s. Synth. Meth. 16, 448) s. P. L. Hall and R. B. Perfetti, J. Org. Chem. 39, 111 (1974). 

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