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Synthesis of polyacetylene glycosides and thioglycosidesPan, Yanqing Unknown Date
No description available.
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Synthesis of polyacetylene glycosides and thioglycosidesPan, Yanqing 11 1900 (has links)
Polyacetylene glycosides are natural products isolated from a variety of natural sources, primarily terrestrial plants and fungi. Polyacetylene glycosides isolated to date feature a linear and conjugated polyacetylene chain and a mono di-, or trisaccharide group in their structures. These compounds have been shown to possess a host of different biological activities, including anti-inflammatory effects, inhibition of nitric oxide production and histamine release, anti-bacterial activity, and the ability to inhibit the enzyme 12-lipoxygenase. The project described in this thesis focuses on polyacetylene glycosides and polyacetylene thioglycosides by glycosylating or thioglycosylating mono-, di-, or triyne alcohols, which have been synthesized using the Cadiot-Chodkiewicz reaction and Fritcsh-Buttenberg-Wiechell rearrangement. Twenty-seven polyacetylene glycosides and thioglycosides have been synthesized. Given the structural similarity of these compounds to bioactive natural products, we expected the molecules should have interesting biological activities. Thirty compounds have thus been assayed for cytotoxicity against MCF-7 breast lines, as well as anti-bacterial activity.
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Application of HOF.CH3CN to the synthesis of glycosyl sulphonesRibeiro Morais, Goreti, Humphrey, Andrew J., Falconer, Robert A. January 2008 (has links)
No / A fast, complete and clean conversion of thioglycosides into glycosyl sulfones under mild acidic conditions is described, using the HOF·CH3CN complex at room temperature. This methodology affords glycosyl sulfones in high yields and in excellent purity.
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The S-Xanthenyl group: potential for application in the synthesis of thioglycosides.Falconer, Robert A. January 2002 (has links)
No / The S-xanthenyl (Xan) group was demonstrated to have potential as a convenient protecting group for 1-thiosugars in the synthesis of thioglycosides. Easily introduced by reaction of a 1-thiosugar with 9-hydroxyxanthene in the presence of catalytic TFA, the S-Xan group is compatible with a wide range of functionalities and protecting groups.
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Nouvelles réactions métallocatalyées pour la création de liaisons C-N et C-S : applications à la synthèse d'inhibiteurs de la Hsp90 / Development of new metal-catalyzed reactions to form C-heteroatom bonds : application to the synthesis of Hsp90 inhibitorsBrachet, Etienne 22 November 2013 (has links)
Les travaux rapportés dans ce mémoire concernent le développement de nouvelles réactions métallo-catalysées pour la création de liaison carbone-hétéroatomes ainsi que leurs applications à la synthèse d’inhibiteurs de la protéine de choc thermique 90.Au cours de ce travail, l’étude de la réactivité d’hétérocycles de type quinoxalinones et N-aminoazoles vis-à-vis du couplage de Buchwald-Hartwig a été réalisée. Des conditions ont ainsi pu être développées pour créer la liaison carbone-azote entre des 3-chloroquinoxalinones et des partenaires nucléophiles azotés (amides, azoles…) afin de construire une bibliothèque d’analogues du 6BrCaQ en série quinoxalinone. Par ailleurs, la création de la liaison carbone-azote de motifs N-aminoazoles avec des partenaires hétérocycliques halogénés (coumarines, quinoléines…) ou aromatiques halogénés a été étudiée. Celle-ci a permis l’accès à une chimiothèque d’analogues du 6BrCaQ ainsi que le développement du couplage permettant la mono- ou di-substitutions des motifs N-aminoazoles.Dans le dernier chapitre de ce manuscrit, la création de la liaison carbone-soufre en série glycosidique métallo-catalysés (Pd et Ni) entre des thioglycosides et divers aglycones électrophiles (halogénures (hétéro)aromatiques, vinyliques et acétyleniques) a été examiné. Tous les composés obtenus lors de ce travail sont en cours d’évaluation biologique. / The development of new metal-catalyzed reactions to form carbon-heteroatom bonds have been studied in order to access to hsp90 inhibitors. For this purpose, reactivity of various 3-chloroquinoxalinone have been explored towards Pd-catalyzed Buchwald-Hartwig reaction with nitrogen nucleophiles (amides, azoles…) which allow access to a serie of 6BrCaQ analogues. In the same objective, the reactivity of N-aminoazole moieties in a Buchwald-Hartwig cross-coupling reaction has been also performed. This methodology led to the synthesis of new 6BrCaQ analogues. Moreover, conditions have been defined to access mono- or di-arylated N-aminoazoles structures starting from aryl chlorides. Finally, reactivity studies on metal-catalyzed carbon-sulfur bond forming reaction between thioglycosides as new nucleophiles partners with various aglycon halides ((hetero)aromatics, alkenyls and alkynyls halides) have been performed. Thanks to a nickel- or a palladium-catalysis, we have been able to introduce these thiosugars on various electrophiles partners and complex molecules. Thioglycosylated 6BrCaQ has been thus obtained.Biological evaluations of new synthesized compounds are currently in progress.
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Synthesis and Antitumor Activities of Aquayamycin and Analogues of Derhodinosylurdamycin A and Synthesis of S-Linked Trisaccharide Glycal of Derhodinosylurdamycin AAcharya, Padam Prasad 18 November 2019 (has links)
No description available.
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Studies On 2,3-Unsaturated Sugars : Reactivity Switching, Rearrangements And Conjugate AdditionsMukherjee, Arunima 09 1900 (has links) (PDF)
Unsaturated sugars constitute as an important category of carbohydrate precursors in synthesis. Specifically, 1,2- and 2,3-unsaturated glycosides are excellent intermediates to derivatize monosaccharides and as building blocks in organic synthesis. For example, a major utility of 1,2-unsaturated sugars, namely glycals, is the addition reactions to afford 2-deoxy glycosides under acidic conditions and rearrangement reactions to produce 2,3-unsaturated glycosides. Lewis acids favour the formation of 2,3-unsaturated glycosides, whereas, Brønsted acids lead to normal addition products. A mixture of both the product is obtained often, depending on the nucleophiles and the stereochemistry of glycal. Chapter 1 of the thesis describes (i) reactivities of glycals under acidic condition and (ii) a general survey of reactions involving on C2-C3 carbons of monosaccharides.
Glycals are useful precursors to derive a number of functionalized monosaccharide derivatives. A well-known acid catalyzed reaction of glycals is their conversion to 2,3¬unsaturated glycosides, known as the Ferrier products. In a research programme, reactivity switching and selective activation of C-1 or C-3 of 2,3-unsaturated thioglycosides under acid catalyzed condition was undertaken. Thioglycosides are excellent glycosyl donors and can be activated easily. In identifying the reactivities of 2,3-unsaturated thioglycosides, obtained through Ce(IV)-mediated reaction of a glycal, it was intended to study the glycosylation reaction and also the reactivity control of C1-C3 carbons during a glycosylation reaction. Experiments showed that a reactivity switching was possible through activation of either C-1 or C-3. Thus, C-1 glycosylation with alcohol acceptors occurred in the presence of NIS/TfOH, without the acceptors reacting at C-3. On the other hand, reaction of 2,3-unsaturated thioglycosides with alcohols mediated by triflic acid alone led to a transposition of C-1 ethylthio-moiety to C-3 intramolecularly, to form 3-ethylthio-glycals. Resulting glycals underwent glycosylation with alcohols to afford 3-ethylthio-2-deoxy glycosides. However, when thiol was used as an acceptor, only a stereoselective addition at C-3 resulted, so as to form C-1, C-3 dithio-substituted 2-deoxypyranosides. Oxocarbenium ion is the reactive intermediate during activation of a glycosyl donor, and in the case of a 2,3-unsaturated thioglycosides, the oxocarbenium ion may stabilize further by the presence of a C2-C3 unsaturation. Reaction of a nucleophile with allylic oxocarbenium ion may lead to two regio-isomers. Initially, NIS/TfOH was attempted on 2,3–unsaturated sugar with various alcohols and it was found that C-1 was the preferred reactive centre (Scheme 1)
Scheme 1
In order to optimize the reaction for selective nucleophilic attack at C-3, further study was continued by using stoichiometric TfOH, in presence of acceptors alcohols with the intension to activate the double bond. The reaction led to the formation of 2-deoxy O-glycosides with the concomitant transposition of C-1 ethylthio-moiety to C-3 (Scheme 2).
Scheme 2
An important observation was that the transposition of thioethyl group from C-1 to C-3 was highly regioselective. For example, with thiocresol as the nucleophile, there was an addition across the C-2-C-3 double bond to afford C-1, C-3-dithio derivative (Scheme 2). Thus, hard-soft nature of the nucleophiles, as well as, carbon centres helped to rationalize the reactivites.
It was also observed that the intramolecular transposition of thioethyl group is highly stereo-controlled by equatorial C-4 acetoxy group. Thus, thioethyl nucleophile approached selectively at C-3 and afforded trans-diequatorial products. This rationalization was further confirmed through (i) reaction of benzyl protected 2,3-unsaturated thioglycoside, wherein a C-3 epimeric mixture was observed in 1:1 ratio; (ii) galactosyl derivative under similar reaction condition afforded anomeric mixture of 3-(4-methylphenylthio)-O-glycosides, with trans-diaxial orientation of substituent at C-3 (Scheme 3).
Scheme 3
These reactions confirmed the role of C-4 substituent on the carbocation at C-3, through the presence or absence of a neighbouring group participation. In summary, in Chapter 2 the selective activation of either anomeric carbon or C-3 with proper choice of activation and reactivity control at each carbon will be described.
Thioglycosides are excellent glyosyl donor and their glycosylation reactions were well explored. Upon indentifying the intramolecular transposition of thioalkyl/aryl functionality from C-1 to C-3, further investigations was undertaken to utilize the newly formed carbon sulfur bonds at C-3. Realizing a potential for such 3-alkyl/aryl thio 2-deoxy sugar, the Pummerer rearrangement was investigated. For this purpose, the thioalkyl/aryl moiety at C-3 was oxidized first to a sulfoxide. The resulting sulfoxide was allowed to undergo Pummerer rearrangement to afford vinyl sulfide (Scheme 4), resulting from the elimination of HOAc in the thioacetal formed in situ. Having implemented Pummerer rearrangement on a sugar substrate, synthetic utility of the rearrangement product, namely vinyl sulfide was undertaken.
An effort to implement conjugate addition reaction was undertaken, which required the conversion of vinyl sulfide to vinyl sulfoxide in the first step. The conjugate addition reactions were first conducted with alkoxide nucleophiles. The reaction showed that addition of nucleophiles occurred from axial face to furnish manno-configured derivatives as a single diastereomer at sulfinyl sulfur in a moderate yield along with O-deacetylated product. It was also found that O-benzyl protected sugar vinyl sulfoxide was totally resistant to the conjugate addition reaction (Scheme 4).
Scheme 4
In order to find the influence of the substituents in sulfoxide moiety in the addition of nucleophiles, additional study was conducted in which a less hindered thioethyl moiety was installed in place of p-tolylthio moiety. To install ethylthio moiety, a similar sequence of reaction was undertaken as described previously in Scheme 4. Conjugate addition reaction with alkoxide nucleophiles was conducted and analysis of the reaction showed that the addition of alkoxides remained similar, leading to the formation of manno-configuration of substituents (Scheme 5).
Scheme 5
The configuration of the Michael adducts were ascertained from 1H NMR, as well as 2D NMR spectroscopies. H-1 of all adducts appeared as an apparent singlet, consistent with very small J1,2 values. Aryl vinyl sulfoxide afforded conjugate addition product at much higher ratio than corresponding alkyl vinyl sulfoxide. Thus, among aryl and alkyl vinyl sulfoxides, conjugate addition occurred better with the aryl vinyl sulfoxide, indicating a strong electronic effect of aryl group in stabilizing the conjugate anion which would form in situ during nucleophilic addition with vinyl sulfoxide. Therefore, p-tolylthio substituted vinyl sulfoxide served as a more efficient Michael acceptor when compared to the thioethyl substituted vinyl sulfoxide.
Asymmetric environment of vinyl sulfoxides play a vital role during the reaction. Vinyl sulfoxides can exist in two stereochemically distinct conformation which makes the vinyl group electronically dissimilar. In one of the conformer S-O and C-C bonds are coplanar, whereas in the other conformation, these two bonds are opposite to each other. It is agreed generally that vinyl sulfoxides generally try to adopt the most reactive conformer during the reaction in which the C-C and S-O bonds are syn to each other. Thus, the preference for an axial attack would originate from a face anti to the lone pair of electrons on the sulfur of sulfoxide functionality, leading to the formation of the product with manno-configuration. As O-deacetylated vinyl sulfoxide was obtained along with the Michael adducts, it was assumed that one of the epimers of vinyl sulfoxide appeared to be more reactive when compared to the other. Chapter 3 describes implementation of a Pummerer rearrangement in order to synthesize a sugar vinyl sulfoxide and its conjugate addition reactions with alkoxide nucleophiles.
The nucleophilic addition reactions of vinyl sulfoxide with other nucleophiles were studied further. The effect of the substituents of chiral sulfoxides in conjugate addition reactions was also incorporated in the course of reactions. Reactions of amines, carbon and sulfur nucleophiles were undertaken with p-tolylthio-substituted vinyl sulfoxides. The reactions showed formation of the addition-elimination products (Scheme 6). All primary amines, carbon and sulfur nucleophiles afforded C-2 axial epimer, namely, threo-epimer exclusively, wherein secondary amines furnished the equatorial vs axial epimer in 3:1 ratio.
Scheme 6
In order to assess the course of the reaction, vinyl sulfoxide presenting a p-cumenethio¬moiety was installed in place of p-tolylthio moiety. Conjugate addition reactions were performed with both primary as well as secondary amines that showed formation of the C-2 epimeric mixtures. With both the primary and secondary amines C-2 equatorial epimer was found to be as the major product (Scheme 7).
Scheme 7
In conjugate addition of vinyl sulfoxides, nucleophiles approach the olefinic face preferentially, which is anti to the electron rich sulfur lone pair of electrons and syn to the bulky aryl group. Therefore, C-2 axial epimer was observed as most favourable product. However, secondary amines remarkably influenced the pattern as well as selectivity of the reaction. Steric considerations were likely to dictate the overall reactivity with secondary amines which was even more pronounced when using p-cumenethio-substituted vinyl sulfoxide. Chapter 4 describes the conjugate additions as well as remote effect of aryl substituent on the selectivity of addition of amines on sugar sulfoxide
In summary, the Thesis establishes:
A new reactivity of switching and a selective activation of 2,3-unsaturated thioglycoside; A Pummerer rearrangement route in order to synthesize sugar vinyl sulfide for the first time, which on selective oxidation furnish a sugar vinyl sulfoxide, a useful precursor for conjugate addition reactions; An assessment of the stereoelectronic, as well as, steric effect of the chiral vinyl sulfoxide with various nucleophiles in conjugate addition reactions; Influence of the protecting groups were also studied in conjugate addition reactions.
Overall the study presented in the Thesis provides a new insight to unsaturated sugars. The salient features of the present findings also showed that the intermediates such as C-3 substituted thioalkyl/aryl glycosides, vinyl sulfides, a variety of new C-2 substituted vinyl sulfoxides are also the potential sites for many types of modifications in monosaccharides.
(For structural formula pl see the pdf file)
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Synthesis of Orthogonally Functionalized Oligosaccharides for Self-assembled Monolayers and as Multimodal Tools in Chemical BiologyFyrner, Timmy January 2012 (has links)
This thesis covers different topics in the field of synthetic organic chemistry combined with the field of surface science and glycobiology. First, the text presents a series of orthogonally protected oligosaccharides (tri-, penta-, and heptasaccharides) of varying length and structures, which are synthesized with the aim of developing novel heterobifunctional biocompatible cross-linkers. Successful conjugation with different chemical handles is also described and used to illustrate the potential implementation of defined carbohydrate based compounds have potential use in biosensing applications. The results of incubation experiments using living cells indicate that the linker is incorporated into cell surfaces and enriched in microdomains. Second, synthesis of various saccharide-terminated alkane thiols immobilized on gold surfaces is reported. The protein adsorption and antifouling characteristics of these surfaces were investigated using model proteins and the common fouling organisms, Ulva linza and Balanus amphitrite. Further, oligo(lactose)-based thiols (di-, tetra-, and hexasaccharides) were synthesized and immobilized on gold nanoparticles to investigate how well these rigid, rod-like oligosaccharides can stabilize such nanoparticles for future use in constructing hybrid nanoparticles. Finally, the thesis describes synthesis of a systematic series of oligo(ethylene) glycols possessing either hydrogen- or methyl-terminated groups. Investigation of the fundamental characteristics of self-assembled monolayers, will give important insights into the design of protein repellant surfaces.
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Synthesis Of 2-Deoxy-1-Thioglycosides And Establishing Their Efficient Glycosyl Donor Properties To Prepare Aryl 2-Deoxy Glycosides And 2-Deoxy OligosaccharidesPaul, Somak 01 May 2008 (has links)
Carbohydrates are a family of polyfunctional natural products and can be chemically modified in numerous ways. The primary significance of carbohydrates rests in their importance in biological functions. A particular class of sugars, namely, 2-deoxy or C-2 modified sugars has received a special attention, due to their importance in biological functions. These sugars are defined as carbohydrates carrying a hetero-atom, other than the hydroxyl group, and their derivatives. There is an ever-leading requirement to synthesize various carbohydrates-containing natural and un-natural products, such as, oligonucleotides, glycopeptides, antitumor drugs and cardiac glycosides, having C-2 modified sugars. Chapter 1 describes various synthetic modifications, particularly at the C-2 of a monosaccharide, as relevant to the work presented in this Thesis.
1, 2-Unsaturated glycopyranosides, namely, glycals, are versatile synthetic intermediates for the elaboration to a number of functionalized glycosyl derivatives. A major utility of the glycals is their conversion to the 2-deoxy glycosyl derivatives. In a programme, it was desired to identify a synthetic method to prepare 2-deoxy sugar derivatives that are endowed with an anomeric activation. In particular, a thioglycoside activation was desired. In the event, a methodology was identified, which allowed the synthesis of activated 2-deoxy-1-thioglycosides.The method involved reaction of a glycal with EtSH, in the presence of ceric ammonium nitrate (CAN) as the catalyst. The reaction was applicable to different epimeric glycals. Apart from the 2-deoxy-1-thioglycosides, formation of the 2, 3-unsaturated enoses, corresponding to the Ferrier product, also observed. Optimal conditions for the formation of the 2-deoxy-1-thioglycosides were identified (Scheme 1) and the reaction was proposed to proceed through a radical oxocarbenium ion and a thiolate intermediate.
(Fig)
Scheme1
Upon synthesis of 2-deoxy-1-thioglycosides, few glycosylation reactions with both aglycosyl and glycosyl acceptors were performed and the α-anomeric 2-deoxy glycosides were obtained exclusively.
Chapter 2 summarizes synthesis, characterization of 2-deoxy-1-thioglycosides and their glycosyl donor properties towards several glycosyl acceptors.
Many naturally-occurring antibiotic and antitumor drugs contain 2-deoxy glycosides as important structural components. For example, 2,6-dideoxy-hexopyranoses are common structural units of chromomycin A3, olivomycin A and mithramycin. The most common structural features of these molecules are: (i) the presence of 2-deoxy sugar residues and (ii) the sugar residues are connected to the aromatic moiety, through a β-glycosidic linkage. The synthesis of these biologically important 2-deoxy glycosides encounters difficulties, due to the absence of stereoelectronic influences at C-2 of the 2-deoxy glycosyl derivatives.
Direct glycosylation of phenols and naphthols with activated 2-deoxy-1-thio-glycosides, in the presence of the thiophilic activator N-iodosuccinimide/triflic acid (NIS/TfOH), lead to the formation of the α-anomer, as the major glycosylated product (Scheme 2).
(Fig)
An effort was under taken to identify methods to prepare the 2-deoxy aryl glycosides, in the β-anomeric configuration. A nucleophilic substitution reaction was anticipated to lead to the formation of β-anomeric glycosides. A halide substitution at C-1 for an effective nucleophilic substitution was adopted. Thus, conversion of the activated 2-deoxy-1-thioglycosides with Br2 in the first step, followed by reaction of the resulting bromide with aryloxy anions, led to the facile conversion to 2-deoxy glycosides in a nearly quantitative f-anomeric configuration at C-1(Scheme 3).
Scheme 3 (Fig)
Chapter 3 presents details of the methodologies that allow a facile preparation of each of the anomers of aryl 2-deoxy-D-glycosides from a common precursor, namely, 2-deoxy-1-thio-glycosides.
An easy access to activated 2-deoxy-1-thioglycosides from the 1, 2-unsaturated sugar and their synthetic utility towards various glycosyl and aglycosyl acceptors led towards synthesis of 2-deoxy disaccharides. Synthesis of six new 2-deoxy-arabino-hexopyranosyl and 2-deoxy-lyxo-hexopyranosyl sugar containing disaccharides were accomplished. These are: (i) 2-deoxy-α-D-arabino-hexopyranosyl-(1→4)-D-glucopyranose (2'-deoxy maltose); (ii) 2-deoxy-α-D-lyxo-hexopyranosyl-(1→4)-D-glucopyranose; (iii) 2-deoxy-α-D-arabino-hexopyranosyl-(1→4)-2-deoxy-D-arabino-hexopyranose (2,2'-dideoxy maltose); (iv) 2-deoxy-α-D-lyxo- hexopyranosyl-(1→4)-2-deoxy-D-arabino-hexopyranose; (v) α-D-glucopyranosyl-(1→4)-2 deoxy-D-arabino-hexopyranose (2-deoxy maltose) and (vi) β-D-galactopyranosyl-(1→4)- deoxy-D-arabino-hexopyranoside (2-deoxy lactose).
The 2'-deoxy and 2, 2'-dideoxydisaccharides were synthesized using a 2-deoxy glycosyl donor and a normal glycosyl acceptor (in case of 2'-deoxy disaccharides) and a 2-deoxy glycosyl acceptor (in case of 2, 2'-dideoxy disaccharides) with a free OH group at C-4, while the remaining hydroxyl groups protected suitably (Scheme 4).
Scheme 4 (Fig)
On the other hand, the syntheses of 2-deoxy disaccharides were initiated from a D-maltose and D-lactose, respectively. The conversion of these disaccharides to a disaccharide glycals was targeted first and conversion of these glycals to a 2-deoxy-1-thioglycosides or a 2-deoxy-1-acetates, followed by a hydrolysis of the thiol moiety or the acetate group, afforded the 2-deoxy disaccharides (Scheme 5). (Fig)
Chapter 4 describes synthesis, characterization of 2-deoxy, 2,2'-dideoxy and 2'-deoxy disaccharides.
Continuing the efforts to establish the utility of 2-deoxy-1-thioglycosides as potential glycosyl donor, synthesis of 2-deoxy cyclic and linear oligosaccharides was undertaken. Prominent among cyclic oligosaccharides are the cyclodextrins. Due to their unique structural and physical properties, cyclodextrins find manifold applications. Known methods to synthesize cyclic oligosaccharides are (i) the cyclization of linear oligosaccharides to produce the cyclic oligosaccharides and (ii) the synthesis of designed monomers and subjecting them to cyclooligomerization protocols. The cyclooligomerization was adopted to synthesize new types of 2-deoxy cyclic-and linear oligosaccharides. After a series of trials, a disaccharide monomer, namely, ethyl 4-O-(6-O-benzoyl-2,3-di-O-methyl-α-D-glucopyranosyl)-2-deoxy-3,6-di-O-methyl-arabino-hexopyranoside (1), was identified as a suitable monomer for thecyclooligomerization protocol. For an effective oligomerization, the concentration of the monomer and the choice of the reagents are important.
The reaction was conducted at three different monomer concentrations, 2 mM, 10 mM and 25 mM, using two thiophilic activators, namely, (i) NIS/TfOH and (ii) NIS/AgOTf. Better yields of the cyclic oligosaccharides, namely, the cyclic tetrasaccharide (2) (40 %) and cyclic hexasaccharide (3) (25 %), were isolated when the monomer (1) concentration was 25 mM and NIS/TfOH acid was used as the promoter (Scheme 6). The formation of linear disaccharide (4) (10 %) and tetrasaccharide (5) (18 %) was also observed at this concentration.
On the other hand, when the reaction of the monomer was performed in the presence of NIS/AgOTf, the oligomerization reaction led to the formation of linear oligosaccharides, consisting of di-to eicosa-saccharides. Synthesis of different monomers, their characterization and oligomerization reaction using these monomers through a polycondensation protocol are
discussed in Chapter 5.
Scheme 6(fig)
In summary, the Thesis establishes the chemistry of 2-deoxy sugars, formation of activated 2-deoxy sugars, formation of alkyl and aryl glycosides, 2-deoxy disaccharides, 2-deoxy cyclic and linear oligosaccharides. Routine physical methods were used to characterize the newly formed 2-deoxy sugars and the oligosaccharides. Single crystal X-ray structural determination was performed for an aryl 2-deoxyglycosides, which provided the solid state configurational features of the 2-deoxy pyranose.
(For structural formula pl see the pdf file)
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Novel Synthetic Strategies towards Acetylenic Biscarbamates/Biscarbonates and Organochalcogen DerivativesCheerladinne, Venkateshwarlu January 2013 (has links) (PDF)
Bisacetylenic cabamates/carbonates are most useful compounds in finger mark development, for the synthesis of polymeric gels and other material applications. Organochalogen derivatives are the organic compounds containing chalcogen (S, Se) atoms. They have been used as chiral ligands for enatioselective catalysis, glycosyl donors and in the synthesis of heterocyclic compounds etc. This thesis describes our efforts towards synthesis of bisacetylenic cabamates/carbonates and development new synthetic strategies using rongalite (Na+HOCH2SO2-) and benzyltriethyl ammonium tetrathiomolybate [BnEt3N]2MoS4 as a reducing agents led to obtain various organochalcogen derivatives.
We developed a new reagent, hexa-2,4-diyne-1,6-bisoxycarbonyl chloride [Hbc Cl] for the synthesis of symmetrical diacetylenic biscarbamates/biscarbonates and further studied the solid state structures using X-ray crystallography. Later we described a stereoselective method for the hydrothiolation of buta-1,3-diynes derivatives using diaryldichalcogenides in the presence of rongalite and K2CO3. The buta-1,3-diynes underwent stereoselective addition reaction with in situ generated chalocgenate anion from diaryl dichalcogenides which afforded the corresponding (Z)-chalcogenynes. The reactivity of buta-1,3-diynes with diaryl dichalcogenides was further studied at higher temperature led to a mixture of mono chalcogenated and bischalcogenated products. Then an efficient method was developed for the synthesis of enatiopure β-amino sulfides/selenides via ring opening of sulfamidates using diarylchalcogenides with rongalite as reducing agent. Further we synthesized chalcogeno derivatives of sugars from glycosyl halides and diaryl dichalcogenides in the presence rongalite. In addition, the synthesis of mixed glycosyl dichalcogenides has been demonstrated using [BnEt3N]2MoS4 as sulfur transfer agent as well as reducing agent. Finally the reactivity of [BnEt3N]2MoS4 was studied in detail with various isatioc anhydrides which led to the formation of S-benzyl 2-aminobenzothioate derivatives. Further we synthesized S-alkyl/aryl 2-aminobenzothioate derivatives via ring opening of isatoic anhydrides and diaryl/dialkyl chalcogenides by mean of [BnEt3N]2MoS4 as a reducing agent. We extended this method in a one-pot, tandem fashion with various alkyl halides. In this thesis, details of all of the above studies have been described.
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