Isoindoline

Isoindolines comprise a group of well-characterized and easily synthesized substances, and being at the next stable reduction state below that of isoindoles, they constitute suitable precursors for synthesis of the latter. In principle, either oxidation or elimination from isoindolines should lead to isoindoles however, in view of the susceptibility of isoindoles to further oxidation, elimination has been preferred, and in all cases reported the leaving group has been placed on nitrogen rather than carbon. 

Elimination from A -oxides of substituted isoindolines provides an exceptionally facile synthesis of the isoindole sy.stem. Kreher and Seubert found that treatment of the oxides of both 2-alkyl- and 2-arylisoindolines with acetic anhydride at 0° to —10° afforded... 

Pyrolytic elimination from isoindoline A -oxides also affords iso-indoles, but yields were found to be generally lower than those obtained by Kreher and Seubert s procedure. The considerable amount of polymeric material formed in the pyrolytic reaction makes isolation of the isoindole difficult, but a convenient method for separation of the product was found utilizing complex formation with 1,3,5 -trin i tro benzene. 

In contrast to isoindoliiiium salts and A-oxides of isoindolines, successful elimination from simple 2-substituted isoindolines has been realized in only two cases. One of these, however, was the synthesis of isoindole itself, and it seems likely that this method is particularly well suited to the preparation of other sensitive isoindoles. 

The perhydroisoindole system can be prepared by high-pressure hydrogenation of the isoindole over nickel on alumina at elevated temperatures. The use of Raney nickel with dioxane in the reduction of l,3-diphenyl-2-methylisoindole (47) gives the perhydro product (96), accompanied by the isoindoline (97). An alternative route to partially hydrogenated isoindoles has been described in Section III, D. 

Electrolytic reduction of phthalimide and of phthalimidines which are at an oxidation level above that of isoindole, proceeds through the isoindole to the isoindoline stage, which is then stable to further... 

Note, Added in Proof-. In their study of the autoxidation of 2-butyl-isoindoline, Kochi and Singleton showed that 2-butylisoindole is formed and is converted by further oxidation to 2-butylphthalimide and 2-butylphthalimidine. The rate of oxidation of 2-butylisoindoline to the isoindole was found to be markedly dependent on hydrogen donor ability of the solvent and was shoivn to involve a free radical chain process. Autoxidation of 2-butylisoindole also appears to be a radical process since it can initiate autoxidation of 2-butylisoindoline. 

Chiral N,N-disubstituted l-(aminomethyl)isoindolines as catalysts for asymmetric acylation of alcohols 99YGK598. 

Nevertheless, the adjacent position of the amide and acetylenic groups was used in another type of heterocyclization. The nitrogen atom in the amide group is a weak nucleophile. Therefore, the N anion should be generated by potassium ethoxide. There are two possible variants of nucleophilic addition to the triple bond. Only one takes place, i.e., the formation of y-lactam. After 7 h of heating in EtOH in the presence of KOH, amide 72 isomerized into the known isoindoline 73 in 80% yield (Scheme 128). 

X0-3-(Am inopheny I-p-ethoxy piper idino)isoindoline Sodium hydride Ethyl iodide... 

The method illustrates the ability of the sodium hydride-dimethylformamide system to effect the alkylation of aromatic sulfonamides under mild conditions and in good yield. The method appears to be fairly general. The submitters have prepared N,N-diethyl- and N,N-di- -butyl- >-toluenesulfonamide as well as 2-(/ -tolyIsuIfonyl)benz[/]isoindoline from 2,3-bis-(bromomethyl)naphthalene, and 1 %-tolylsulfony])pyrrolidine from 1,4-dichIorobutane the yield of purified product exceeded 75% in each case. 

In contrast to phthalocyanines (tetra- or octasubstituted) in which the isoindoline units carry all the same substituents, reports of phthalocyanines with lower symmetry, which have been prepared by using two different phthalonitriles, have rarely appeared. This is due to the problems which are associated with their preparation and separation. For the preparation of unsymmetrical phthalocyanines with two different isoindoline units four methods are known the polymer support route,300 " 303 via enlargement of subphthalocyanines,304 " 308 via reaction ofl,3,3-trichloroisoindoline and isoindolinediimine309,310 and the statistical condensation followed by a separation of the products.111,311 319 Using the first two methods, only one product, formed by three identical and one other isoindoline unit, should be produced. The third method can be used to prepare a linear product with D2h symmetry formed by two identical isoindoline units. For the synthesis of the other type of unsymmetrical phthalocyanine the method of statistical condensation must be chosen. In such a condensation of two phthalonitriles the formation of six different phthalocyanines320 is possible. 

The products from cyclization reactions of 5-substituted isoindolinediimirtes are 2,9,16,23-tetrasubstituted phthalocyanines, e.g. 2.110121,4lf Again, a mixture of four structural isomers is obtained (see p 737). It should be emphasized that reaction conditions employing isoindoline-diimines are mild in comparison to the use of phthalonitriles. 

The water-soluble sulfonic acids of copper phthalocyanine are produced by heating phthalocyanines in oleum. By varying the reaction conditions, one to four hydrogen atoms can be substituted. A maximum one sulfo group is introduced per isoindoline unit.335... 

NMP with acrylates and acrylamides with TEMPO provides only very low conversions. Very low limiting conversions and broad dispersities were reported.2 Better results were obtained with DTBN (83),111 151 imidazoline (61-64)I3S and isoindoline (59) nitroxides.111 However, limiting conversions were still observed. The self-regulation provided in S polymerization by thermal initiation is absent and, as a consequence, polymerization proceeds until inhibited by the buildup of nitroxide. The final product is an alkoxyamine and NMP can be continued... 

Researchers at GlaxoSmithKline have numerous recent patent applications describing several series of H3 antagonists including the benzazapines (41) [115] and (42) [116], quinolizidines (43) [117], isoindolines (44) [118], and the piperidine amides (45) [119] and (46) [120]. All of these structures were disclosed as functional H3 antagonists. 

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