9-Benzyl-6- purines

Arprinocid (Fig. 5.7) is a benzyl purine derivative shown to be effective against all species of turkey and chicken coccidia. It is administered continuously with the feed at a dose of 60 ppm for chickens and 90-120 ppm for turkeys. 

Reviews on catalytic uses of DMAP and other 4-(dialkylamino)pyridines have appeared [9]. These bases are very efficient reagents for acylations, alkylations, silylations, phosphorylations, condensations, and transesterifications [ 10]. More recent applications of DMAP as a catalyst include a parallel synthesis of benzyl purine derivatives [11] and it has been employed as a base in the asymmetric synthesis of an amino acid via an auxiliary [12]. Uses of DMAP tethered to solid supports (of which one such example is commercially available) have been reviewed [10,13]. Such a system has recently been employed to synthesize multiple oligonucleotides linked end to end in tandem [14]. 

Synthesis of 9- p Nitrobenzyl)adenine (7). 6-Chloro-9-(p-nitro-benzyl) purine, 600 mg, in 50 ml of 20% methanolic NHj is heated at 73° for 45 hr in a stainless steel bomb. The precipitate, recrystallized from methanol, yields 400 mg (71%). 

Purine, 9-benzyl-6-thioxo-1,6-dihydro-synthesis, 5, 597 Purine, 6-bromo-alkylation, 5, 530 synthesis, 5, 597... 

Purine, 1,6-dihydro-8,9-dimethyl-6-thioxo-synthesis, 5, 583 Purine, 2,6-dimethoxy-synthesis, 5, 596 Purine, 2,6-dimethoxy-7-methyl-rearrangement, 5, 558 Purine, 2,7-dimethyl-halogenation, 5, 547 Purine, 7,9-dimethyl-UV spectra, 5, 517 Purine, 8,8-dimethyl-synthesis, 5, 580 Purine, 6-dimethylamino-mass spectra, 5, 519 occurrence, 5, 600 Purine, 6-dimethylamino-9-benzyl-alkylation, 5, 531 Purine, 3,7-dimethyl-6,8-dioxo-methylation, 5, 534 Purine, 6,8-dioxo-alkylation, 5, 534... 

Substitution of more complex acids for formic acid in the last step of the purine synthesis will afford intermediates substituted on the imidazole carbon atom. Thus, condensation of diaminouracyl, 12, with phenylacetic acid gives the benzylated... 

H-Bonding and Solvent Effects in the Benzylation of Purine and Pyrimidine Bases... 

Predictably, 1,2,4-triazole is alkylated preferentially at the 1-position [36, 38,39]. Specific alkylation at the 4-position can be achieved by the initial reaction with dibromomethane to form the bis-triazol-l-ylmethane (see below), followed by quat-emization of the triazole system at the 4-position and subsequent C-N cleavage of the 1,1 -methylenebistriazolium salts [40]. 1,2,3-Benztriazole yields a mixture of the isomeric 1- and 2-alkylated derivatives [41]. The 1-isomer predominates, but the ratio depends on whether the reactions are conducted in the presence, or absence, of a nonpolar organic solvent (Table 5.33). Higher ratios of the 1-isomer are obtained under solidrliquid two-phase conditions. Thus, alkylation of 1,2,3-benztriazole with benzyl chloride produces an overall yield of 95% with the l- 2-isomer ratio of ca. 5.7 1 similar reactions with diphenylmethyl and triphenylmethyl chlorides gives overall yields of 95% (9 1 ratio) and 70% (100% 1-isomer), respectively [38], 6-Substituted purines are alkylated at the N9-atom and reaction with 1-bromo-3-chloropropane yields exclusively the 9-chloropropyl derivative (cf. reaction wi phenols) [42]. 

Another way of synthesis of vidarabine that was developed later consists of alkylating of 6-benzamidopurine with 2,3,5-tn-(9-benzyl-D-arabinofuranosyl chloride using sodium in liquid ammonia. This simultaneously iV-debenzylates the sixth position of the purine system and fulfil 0-debenzylation of hydroxyl groups of the furanosyl fragment of the molu-cule, giving vidarabine [14]. 

The Suzuld-Miyaura cross-coupling reaction of 9-benzyl-6-chloropurine with boronic acids gives 6-alkylated purines in moderate to excellent yields. The reaction has been successfully... 

The well-known application of 2,4,6-tris(ethoxycarbonyl)-l,3,5-triazine as a diene in inverse electron demand Diels-Alder cyclizations was adapted for the synthesis of purines <1999JA5833>. The unstable, electron-rich dienophile 5-amino-l-benzylimidazole was generated in situ by decarboxylation of 5-amino-l-benzyl-4-imidazolecarboxylic acid under mildly acidic conditions (Scheme 54). Collapse of the Diels-Alder adduct by retro-Diels-Alder reaction and elimination of ethyl cyanoformate, followed by aromatization by loss of ammonia, led to the purine products. The reactions proceeded at room temperature if left for sufficient periods (e.g., 25 °C, 7 days, 50% yield) but were generally more efficient at higher temperatures (80-100 °C, 2-24 h). The inverse electron demand Diels-Alder cyclization of unsubstituted 1,3,5-triazine was also successful. This synthesis had the advantage of constructing the simple purine heterocycle directly in the presence of both protected and unprotected furanose substituents (also see Volume 8). 

Acylation of the theophylline diamine intermediate (26-6) with phenylacetyl chloride affords the corresponding amide (28-2). Base catalyzed cyclization then leads to the purine (28-3) that now includes a quite lipophilic benzyl group on the fused imidazole ring. The molecule is then provided with a side chain that incorporates basic nitrogen, arguably to improve water solubility. The anion from (28-3) is thus first alkylated with bromochloroethane to afford the chloroethyl product (28-4). The displacement of chlorine with ethanolamine affords the bronchodilator bamifylline (28-5) [28]. 

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