A Facile Synthesis, Spectroscopic Identification, and Antimicrobial Activities of Some New Heterocyclic Derivatives from D-erythro-2,3-hexodiuloso-1,4-lactone-2-(o-chlorophenyl hydrazone)-3-oxime

N. M. Hamada, S. Mancy, Mohamed A. El Sekily
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Abstract

A new series of different heterocyclic derivatives was prepared via a facile unimolecular condensation of D-iso ascorbic acid with o-chlorophenyl hydrazine to give D-erythro-2,3-hexodiulosono-1,4-lactone 2-( o-chlorophenyl hydrazine (2). Reactions of (2) with hydroxylamine gave the 2-( o-chlorophenyl hydrazone)-3-oxime (3). On boiling with boiling acetyl chloride, (3) gave 2-o-chlorophenyl-4-(2,3-di-O-acetyl-D-erythro-glyceryl-1-yl)-1,2,3-triazole-5-carboxylic acid-5,1́-lactone (4). In the treatment of (3) with benzoyl chloride in pyridine the same dehydrative cyclization occurred giving, 2-o-chlorophenyl-4-(2,3-di-o-benzoyloxy-D-erythro-glycerol-1-yl)-1,2,3-triazole-5-carboxylic acid-5,1΄-lactone (5). On the treatment of compound (4) with liquid ammonia in methanol, deacetylation occurred concurrently with the opening of the lactone ring, to afford the 2-o-chlorophenyl-4-(D-erythro-glycerol-1-yl)-1,2,3-triazole-5-carboxamide (6). Similarly, treatment of compound (4) with hydrazine hydrate in methanol, afforded 2-o-chlorophenyl-4-(D-erythro-glycerol-1-yl)-1,2,3-triazole-5-carboxylic acid hydrazide (7).  The controlled reaction of (3) with sodium hydroxide, followed by neutralization, gave 3-(D-erythro-glycerol-1-yl)-4,5-isoxazoline-5-(4H)-one-4-o-chlorophenyl hydrazone (8). Reaction of (3) with HBr-AcOH gave 5-O-acetyl-6-bromo-6-deoxy-D-erythro-2,3-hexodiulosono-1,4-lactone-2-(o-chlorophenyl hydrazone)-3-oxime (9); these were converted into 4-(2-O-acetyl-3-bromo-3-deoxy-l-threo-glycerol-l-yl)-2-aryl-1,2,3-triazole-5-carboxylic acid 5,41-lactones on treatment with acetic anhydride-pyridine. Compound (3) treatment with bromine-water caused its cyclization and bromination of the phenyl group to give carboxylic acid 5,1΄-lactone (10). Acetylation of (10) gave the diacetate (11), which upon treatment with hydrazine hydrate in methanol, afforded compound (12), mild acetylation of compound (12) gave the triacetate (13) boiling of (13) with acetic anhydride afforded hexa acetyl derivative (14). on the treatment of compound (11) with liquid ammonia in methanol deacetylation occurred to afford 1,2,3-triazole-5-carboxamide derivative (15). On the other hand, treatment of compound (3) with bromine-water for a short time yielded 3-oxime (16). Subsequent acetylation with boiling acetic anhydride afforded compound (11). In addition, acetylation of compound 3 afforded a diacetyl derivative assigned as 5,6-di-O-acetyl-D-erythro-2,3-hexodilusono-1,4-lactone-(2-o-chlorophenyl hydrazone)-3-acetoxime (17), which on boiling with acetic anhydride cyclization occurred giving compound (4). On the treatment of Dehydro-L-ascorbic acid-2-phenyl hydrazone (L-threo-2,3-hexodiulosono- 1,4-lactone 2-phenylhydrazone (19) with acetic anhydride/pyridine, afforded 5,6-di-O-acetyl-3-acetoxime (20) that upon treatment with boiling acetic anhydride, afforded the triazole derivative (21). Furthermore, treatment of the monophenyl hydrazone (18) with S-benzyl hydrazine carbodithiolate in the presence of acetic acid, afforded the bis-hydrazone, L-threo-2,3-hexodilusono-1,4-lactone-3-(S-benzylhydrazinocarbodithiolate)-2-phenylhydrazone (22). Acetylation of compound (22) with acetic anhydride and pyridine did not give the di-O-acetyl derivative expected but instead, elimination of a molecule of acetic acid and partial hydrolysis of a hydrazone residue took place to give compound (23). The structures of all the synthesized compounds were confirmed using elemental analysis and different spectral tools. Eight samples from the synthesized compounds, 2,3, 4,10.16,11,12,17 were tested for their antimicrobial activity and they showed no activities.
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D-erythro-2,3-hexodiuloso-1,4-lactone-2-(o-chlorophenyl hydrazone)-3-oxime 一些新杂环衍生物的简易合成、光谱鉴定和抗菌活性
通过 D-异抗坏血酸与邻氯苯肼的简单单分子缩合,制备出 D-赤式-2,3-己二酮-1,4-内酯 2-( 邻氯苯肼 (2)),从而制备出一系列新的不同杂环衍生物。(2)与羟胺反应后得到 2-(邻氯苯腙)-3-肟(3)。用沸腾的乙酰氯煮沸后,(3) 得到 2-邻氯苯基-4-(2,3-二-O-乙酰基-D-赤式甘油-1-基)-1,2,3-三唑-5-羧酸-5,1-́-内酯 (4)。在吡啶中用苯甲酰氯处理 (3) 时,也发生了同样的脱水环化反应,得到 2-邻氯苯基-4-(2,3-二邻苯甲酰氧基-D-赤式甘油-1-基)-1,2,3-三唑-5-羧酸-5,1΄-内酯 (5)。用甲醇中的液氨处理化合物 (4),在打开内酯环的同时发生脱乙酰化反应,得到 2-邻氯苯基-4-(D-赤式甘油-1-基)-1,2,3-三唑-5-甲酰胺 (6)。同样,用甲醇中的水合肼处理化合物 (4),得到 2-邻氯苯基-4-(D-赤式甘油-1-基)-1,2,3-三唑-5-甲酰肼 (7)。 将(3)与氢氧化钠控制反应,然后中和,得到 3-(D-赤式甘油-1-基)-4,5-异噁唑啉-5-(4H)-酮-4-邻氯苯腙(8)。(3)与 HBr-AcOH 反应生成 5-O-乙酰基-6-溴-6-脱氧-D-赤式-2,3-己二酮-1,4-内酯-2-(邻氯苯腙)-3-肟(9);这些化合物经乙酸酐-吡啶处理后转化为 4-(2-O-乙酰基-3-溴-3-脱氧-l-苏氨酰-甘油-l-基)-2-芳基-1,2,3-三唑-5-羧酸 5,41- 内酯。化合物(3)经溴水处理后,苯基发生环化和溴化反应,生成羧酸 5,1΄-内酯(10)。用甲醇中的液氨处理化合物(11),发生脱乙酰化反应,得到 1,2,3-三唑-5-甲酰胺衍生物(15)。另一方面,用溴水短时间处理化合物(3),可得到 3-肟(16)。随后用沸腾的乙酸酐进行乙酰化,得到化合物 (11)。此外,化合物 3 的乙酰化还产生了一种二乙酰基衍生物,即 5,6-二-O-乙酰基-D-赤式-2,3-己二酮-1,4-内酯-(2-邻氯苯腙)-3-乙酰肟(17),该衍生物与乙酸酐发生沸腾环化反应后得到化合物(4)。用乙酸酐/吡啶处理脱氢-L-抗坏血酸-2-苯基腙(L-硫代-2,3-己二酮-1,4-内酯 2-苯基腙(19)),可得到 5,6-二-O-乙酰基-3-乙酮肟(20),用沸腾的乙酸酐处理后,可得到三唑衍生物(21)。此外,在乙酸存在下,用 S-苄基肼二硫酸盐处理单苯基腙(18),可得到双腙,即 L-苏-2,3-己二酮-1,4-内酮-3-(S-苄基肼二硫酸盐)-2-苯基腙(22)。用乙酸酐和吡啶对化合物(22)进行乙酰化反应,并没有得到预期的二-O-乙酰基衍生物,而是消除了一分子乙酸并部分水解了一个腙残基,得到了化合物(23)。所有合成化合物的结构都通过元素分析和不同的光谱工具得到了确认。对合成化合物 2、3、4、10.16、11、12、17 中的八个样品进行了抗菌活性测试,结果显示它们没有活性。
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A Facile Synthesis, Spectroscopic Identification, and Antimicrobial Activities of Some New Heterocyclic Derivatives from D-erythro-2,3-hexodiuloso-1,4-lactone-2-(o-chlorophenyl hydrazone)-3-oxime The Paradox of Thermodynamic Instability Synthesis of 8-Methoxy-1-Tetralone Study of Activation Energy for Viscous Flow of Mixtures as a Measure of Dilution Efficiency for Heavy Oil-Diluent Systems Using Mean Oxidation Number of Organic Carbons to Count Theoretical Chemical Oxygen Demand
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