Cleavage, phthalimides

In a typical experiment, triethylene glycol was treated with two equivalents of sodium toluenesulfonamide in dry DMF solution. After 6 h at reflux, the solution was distilled and product obtained by a standard work-up procedure. By this procedure, 9 was obtained in about 10% yield. The transformation is illustrated below as Eq. (4.10). Note also that Vogtle and his coworkers have also utilized phthalimide as a source of nitrogen in the preparation of such azacrown precursors as H2N(CH2CH2 0)2CH2CH2NH2 In such reactions, a standard hydrazine cleavage was used to remove the phthaloyl residue. 

The 4-nitro-A -phthalimide, prepared by heating the amine with the anhydride to 130° for 30 min, is cleaved with MeNHCH2CH2NH2 (71-92% yield). These cleavage conditions were compatible with cephalosporins, where the phthalim-ide was removed in 92% yield at —50° in 30 min. ... 

The two-step procedure includes formation of a N-substituted phthalimide 3, and its subsequent cleavage to the primary amine 5. Phthalimide (which can be obtained from reaction of phthalic acid with ammonia) shows NH-acidity, since the negative charge of the phthalimide anion (the conjugated base) is stabilized... 

For the cydative cleavage step, it turned out that aprotic conditions were definitely superior to the use of protic media. Thus, employing N,N-dimethylformamide as solvent at somewhat elevated temperatures furnished the desired compounds in high yields and excellent purities. Having established the optimized conditions, various phthalic acids and amines were employed to prepare a set of phthalimides (Scheme 7.51). However, the nature of the amine was seen to have an effect on the outcome of the reaction. Benzyl derivatives furnished somewhat lower yields, probably due to the reduced activities of these amines. Aromatic amines could not be included in the study as auto-induced ring-closure occurred during the conversion of the polymer-bound phthalic acid. 

Phthalic anhydride initially reacts with ammonia, which in turn is liberated, for instance, by decomposition of urea. Diiminophthalimide is then produced via phthalimide and monoiminophthalimide. Subsequent self-condensation (as in the phthalonitrile process) under cleavage of ammonia affords polyisoindolenines, which form complexes with copper ions. Ring closure is achieved through further release of ammonia, and copper phthalocyanine is finally obtained by reduction. 

Tributylvinylphosphonium bromide forms the betaine 213 with sodium phthalimide. Addition of aldehydes RCHO (ketones are inert) gives almost exclusively the ( )-allylphthalimides 214, which form the corresponding allylamines by cleavage with hydrazine210. 

Because of the polyfunctional nature of carbohydrates, protective-group strategy plays an important role in synthetic methodology involving this class of compounds. In the present Chapter, results are described from a study of the utility of N-trimethylsilyl- and N-tert-butyldimethylsilyl-phthalimide for the selective silylation of primary hydroxyl groups in carbohydrates. Also described, is a new, facile method for cleavage of acetals and dithioacetals in carbohydrate derivatives the method involves treatment of the derivatives with a dilute solution of iodine in methanol. 

Phthalazine-l,4-diones have been prepared by nucleophilic cleavage of polystyrene-bound phthalimides (Entry 7, Table 15.27). The reaction rate proved to be highly dependent on the solvent used, being low in EtOH but high in DCM. Using DMF as solvent, no phthalazinediones could be isolated [325]. Hexahydropyridazines have been prepared on cross-linked polystyrene in low yields by treatment of support-bound 1-acyloxy-l, 3-dienes with diimide [326]. 

Thiiranes can be formed directly and stereospecifically from 1,2-disubstituted alkenes by addition of trimethylsilylsulfenyl bromide, formed at -78 C from reaction of bromine with bis(trimethylsilyl) sulfide (Scheme 7).12 A two-step synthesis of thiiranes can be achieved by addition of succinimide-A/-sulfe-nyl chloride or phthalimide-A -sulfenyl chloride to alkenes followed by lithium aluminum hydride cleavage of the adducts (Scheme 8).13 Thiaheterocycles can also be formed by intramolecular electrophilic addition of sulfenyl chlorides to alkenes, e.g. as seen in Schemes 914 and 10.13 Related examples involving sulfur dichloride are shown in Schemes 1116 and 12.17 In the former case addition of sulfur dichloride to 1,5-cyclooctadiene affords a bicyclic dichloro sulfide via regio- and stereo-specific intramolecular addition of an intermediate sulfenyl chloride. Removal of chlorine by lithium aluminum hydride reduction affords 9-thiabicyclo[3.3.1]nonane, which can be further transformed into bicyclo[3.3.0]oct-1,5-ene.16... 

The alkylation products are synthetically useful because simple subsequent transformations furnishes precursors of important natural products as illustrated in Scheme 8E.23. Simple oxidative cleavage of allylic phthalimide 45 generates protected (5)-2-aminopimelic acid, whose dipeptide derivatives have shown antibiotic activity. The esterification via deracemization protocol is not limited to the use of bulky pivalic acid. The alkylation with sterically less hindered propionic acid also occurs with high enantioselectivity to give allylic ester 116, which has been utilized as an intermediate towards the antitumor agent phyllanthocin and the insect sex excitant periplanone. Dihydroxylation of the enantiopure allylic sulfone gives diol 117 with complete diastereoselectivity. Upon further transformation, the structurally versatile y-hydroxy-a,(f-un-saturated sulfone 118 is readily obtained enantiomerically pure. 

An alternative reagent equivalent for the amide anion synthon is the potassium salt of phthalimide which can only react with one molecular proportion of alkyl halide. The resulting JV-alkylphthalimide is then cleaved to the primary amine (the Gabriel synthesis). The preliminary preparation of potassium phthalimide (from a solution of phthalimide in absolute ethanol and potassium hydroxide in 75% ethanol) may be avoided in some cases by boiling phthalimide with the halide in the presence of anhydrous potassium carbonate. The cleavage of the JV-substituted phthalimide is best effected by reaction with hydrazine hydrate and then heating the reaction mixture with hydrochloric acid. The insoluble phthalylhydrazide is filtered off, leaving the amine hydrochloride in solution from which the amine may be liberated and isolated in the appropriate manner. 

A number of other five-membered ring nitrogen heterocycles have been prepared by cyclative cleavage. The illustrative examples (Fig. 4) depict the synthesis of pyrazolones,12 succinimides and phthalimides,13 pyrrolo[3,4-h] pyridines,14 2-aminoimidazolones,15 imidazo[4,5-fr]pyridin-2-ones,16 and l,2,4-triazoline-3,5-diones.17... 

Phthalimides have often been used in the double role of electron acceptor sensitizers and radical traps, and are in fact benzylated by irradiation in the presence of toluene and several other precursors. 4,5-Dicyanophthalimide undergoes substitution of a benzyl for a cyano group when irradiated with toluene, but mainly attack at the imide carbon occurs with diphenylmethane. With various donors the competition between the two modes of reaction has been found to depend on the cage vs. out of cage radical cation cleavage, in the first case with the assistance of the radical anion [223] (Sch. 18). 

The substitution pattern of TfOH-mediated electrophilic aminomethylation of psoralens (furo-coumarins) by V-(hydroxymethyl)phthalimide has been elucidated <85JHC73>. Multiple phthal-imidoylated adducts were obtained when a B-ring hydroxy or methoxy activating group was present, and these resisted simple cleavage with NH2NH2. However, this two-step procedure to aminomethyl group introduction worked well when the psoralens contained only methyl substituents. 

Phenylethylamine has been made by a number of reactions, many of which are unsuitable for preparative purposes. Only the most important methods, from a preparative point of view, are given here. The present method is adapted from that of Adkins,1 which in turn was based upon those of Mignonac,2 von Braun and coworkers,3 and Mailhe.4 Benzyl cyanide has been converted to the amine by catalytic reduction with palladium on charcoal,5 with palladium on barium sulfate,6 and with Adams catalyst 7 by chemical reduction with sodium and alcohol,8 and with zinc dust and mineral acids.9 Hydrocinnamic acid has been converted to the azide and thence by the Curtius rearrangement to /3-phenyl-ethylamine 10 also the Hofmann degradation of hydrocinnamide has been used successfully.11 /3-Nitrostyrene,12 phenylthioaceta-mide,13 and the benzoyl derivative of mandelonitrile 14 all yield /3-phenylethylamine upon reduction. The amine has also been prepared by cleavage of N- (/3-phenylethyl) -phthalimide 15 with hydrazine by the Delepine synthesis from /3-phenylethyl iodide and hexamethylenetetramine 16 by the hydrolysis of the corre-... 

Okada, Okamoto and Oda [97] have recently described a novel method of decarboxylation through a PET bond cleavage process in IV-acyloxyphthalimides. A photoexcited electron donor such as l,6-bis(dimethylamino)pyrene (BDMAP) transfers an electron to the phthalimide to produce an anion-radical that is protonated to form a radical prior to homolytic N—O bond cleavage. Bond... 

Deprotection of phthalimidesJ Phthalimides arc useful for complete protection of primary amino groups, including amino acids, oven though hydrazinolysis is usually necessary for deprotection, A mild, two-step but one-flask cleavage involves reduction with NaBHi in aqueous 2-propanol followed by eyclization to a lactone with release of the amine (equation 1). Yields are generally 80-97%. Racemization docs not occur in deprotection of amino acids (four examples). 

Thermolysis of the dibenzylsulfoximide 69 resulted in an N-N bond cleavage and formation of phthalimide 70 as the only product identified. The resultant sulfur-containing products generated in this hydrogen-transfer process originated in the ring sulfoximide 71 (Scheme 13) <1972JCP(P1)1317>. 

The Gabriel method of making primary amines (Scheme 2.33) rests on the fact that the imide hydrogen of phthalimide is rendered acidic by the two carbonyl groups. It therefore forms a potassium salt, which is a powerful nucleophile and may be alkylated. Hydrolysis of the amide generates the primary amine. The cleavage of the phthalimide may be carried out with hydrazine (H NNHj). 

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