完整後設資料紀錄
DC 欄位語言
dc.contributor.author木翔亦en_US
dc.contributor.authorMulani, Shaheen Kasimen_US
dc.contributor.author蒙國光en_US
dc.contributor.authorMong, Kwok Kong Tonyen_US
dc.date.accessioned2015-11-26T00:55:34Z-
dc.date.available2015-11-26T00:55:34Z-
dc.date.issued2015en_US
dc.identifier.urihttp://140.113.39.130/cdrfb3/record/nctu/#GT079825824en_US
dc.identifier.urihttp://hdl.handle.net/11536/125866-
dc.description.abstractThis dissertation comprises of two chapters: Chapter-I discusses the asymmetric synthesis of uncommon sugars including higher carbon and rare six carbon sugars. Higher carbon sugars are monosaccharides containing seven or more carbon atoms. Typical preparation of the higher carbon sugar involves the elongation of carbon chain and introduction of a hydroxyl group. Due to wide variation of sugar structure, there is no general synthetic strategy for high carbon sugars. The challenge stems from the variable stereochemical control when introducing of hydroxyl group. In this thesis, we have developed a strategy for asymmetric synthesis of higher carbon sugars by combination of (i) MOM Wittig homologation and (ii) proline-catalyzed a-aminoxylation. Based on this strategy, a series of L- and D-glycero heptosdies were obtained from available hexose substrates and proline catalyst. Extended application of the strategy was demonstrated in the syntehsis of rare sugars such as D-altrose, L-galactose, and L-idose. Such sugars could readily be obtained from a five-carbon sugar precursor by using the same strategy. As the stereochemical control of the proline-catalyzed aminoxylation is reagent-controlled, the stereoselectivity of introduction of hydroxyl group is fully controlled and does not suffer from a change in sugar structure and/or it’s protecting group patterns, thus enjoying a wide scope of application. Chapter-II reported a general strategy for total synthesis of a series of phenylethanoid glycosides (PhGs), namely echinacoside (1), acteoside (2), calceolarioside-A (3), calceolarioside-B (4), syringalide-B (5), and grayanoside-A (6). The PhG compounds occur naturally and they are secondary metabolites of various flowering plants. Based on the number of glycoside residues present, these compounds are classified as monosaccharide, disaccharide, trisaccharide PhGs, etc. Nearly all of the PhG compounds contain an ester and alkene functions, and therefore hydroxyl protecting groups such as benzyl and acyl groups that commonly used in carbohydrate context are incompatible to the synthesis of the PhG compounds. As a consequence, previous synthesis of monosaccharide and disaccharide PhGs suffer from poor yield and total synthesis of trisaccharide PhG has not been reported in literature. The strategy discussed in my thesis features (i) the use of naphthylmethyl ether and silyl ether hydroxyl protecting groups; (ii) application of the low concentration glycosylation method to effect the 1,2-trans a-glycosidic bond formation; and (iii) recruitment of one-pot glycosylation method for assembly of oligosaccharide. Furthermore the antiproliferation property of the synthesized PhG compounds on prostatic cancer cell lines were also studies. The data indicated that the size of the glycoside component and the position of the cinnamic acid affect the antiproliferation capacity of the PhG compounds.zh_TW
dc.description.abstractThis dissertation comprises of two chapters: Chapter-I discusses the asymmetric synthesis of uncommon sugars including higher carbon and rare six carbon sugars. Higher carbon sugars are monosaccharides containing seven or more carbon atoms. Typical preparation of the higher carbon sugar involves the elongation of carbon chain and introduction of a hydroxyl group. Due to wide variation of sugar structure, there is no general synthetic strategy for high carbon sugars. The challenge stems from the variable stereochemical control when introducing of hydroxyl group. In this thesis, we have developed a strategy for asymmetric synthesis of higher carbon sugars by combination of (i) MOM Wittig homologation and (ii) proline-catalyzed a-aminoxylation. Based on this strategy, a series of L- and D-glycero heptosdies were obtained from available hexose substrates and proline catalyst. Extended application of the strategy was demonstrated in the syntehsis of rare sugars such as D-altrose, L-galactose, and L-idose. Such sugars could readily be obtained from a five-carbon sugar precursor by using the same strategy. As the stereochemical control of the proline-catalyzed aminoxylation is reagent-controlled, the stereoselectivity of introduction of hydroxyl group is fully controlled and does not suffer from a change in sugar structure and/or it’s protecting group patterns, thus enjoying a wide scope of application. Chapter-II reported a general strategy for total synthesis of a series of phenylethanoid glycosides (PhGs), namely echinacoside (1), acteoside (2), calceolarioside-A (3), calceolarioside-B (4), syringalide-B (5), and grayanoside-A (6). The PhG compounds occur naturally and they are secondary metabolites of various flowering plants. Based on the number of glycoside residues present, these compounds are classified as monosaccharide, disaccharide, trisaccharide PhGs, etc. Nearly all of the PhG compounds contain an ester and alkene functions, and therefore hydroxyl protecting groups such as benzyl and acyl groups that commonly used in carbohydrate context are incompatible to the synthesis of the PhG compounds. As a consequence, previous synthesis of monosaccharide and disaccharide PhGs suffer from poor yield and total synthesis of trisaccharide PhG has not been reported in literature. The strategy discussed in my thesis features (i) the use of naphthylmethyl ether and silyl ether hydroxyl protecting groups; (ii) application of the low concentration glycosylation method to effect the 1,2-trans a-glycosidic bond formation; and (iii) recruitment of one-pot glycosylation method for assembly of oligosaccharide. Furthermore the antiproliferation property of the synthesized PhG compounds on prostatic cancer cell lines were also studies. The data indicated that the size of the glycoside component and the position of the cinnamic acid affect the antiproliferation capacity of the PhG compounds.en_US
dc.language.isoen_USen_US
dc.subject合成higher carbon sugarszh_TW
dc.subject合成phenylethanoid glycosideszh_TW
dc.subjectHigh carbon Sugars,en_US
dc.subjectproline catalyzed reactionen_US
dc.subjectPhenyl ethanoiden_US
dc.title合成higher carbon sugars與phenylethanoid glycosideszh_TW
dc.titleSynthesis of Higher Carbon Sugars and Phenylethanoid Glycosidesen_US
dc.typeThesisen_US
dc.contributor.department應用化學系碩博士班zh_TW
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