Your search keyword '"polysaccharide (agar)"' showing total 4 results

1. Aqueous semisynthesis of C-glycoside glycamines from agarose

Author

Juliana C. Cunico Dallagnol, Alexandre Orsato, Diogo R. B. Ducatti, Miguel D. Noseda, Maria Eugênia R. Duarte, and Alan G. Gonçalves

Subjects

amino sugar, 3,6-anhydro-α-L-galactopyranose, polysaccharide (agar), protecting-group-free, reductive amination, Science, Organic chemistry, QD241-441

Abstract

Agarose was herein employed as starting material to produce primary, secondary and tertiary C-glycoside glycamines, including mono- and disaccharide structures. The semisynthetic approach utilized was generally based on polysaccharide-controlled hydrolysis followed by reductive amination. All reactions were conducted in aqueous media and without the need of hydroxyl group protection. We were able to identify optimal conditions for the reductive amination of agar hydrolysis products and to overcome the major difficulties related to this kind of reaction, also extending it to reducing anhydrosugars. The excess of ammonium acetate, methyl- or dimethylamine, and the use of a diluted basic (pH 11) reaction media were identified as important aspects to achieve improved yields, as well as to decrease the amount of byproducts commonly related to reductive amination of carbohydrates. This strategy allowed the transposition of the 3,6-anhydro-α-L-galactopyranose unit (naturally present in the agarose structure) to all glycamines synthesized, constituting an amino-substituted C-threofuranoside moiety, which is closely related to (+)-muscarine.

Published

2017

2. Aqueous semisynthesis of C-glycoside glycamines from agarose

Author

Maria Eugênia R. Duarte, Diogo R.B. Ducatti, Alan G. Gonçalves, Alexandre Orsato, Juliana C.C. Dallagnol, and Miguel D. Noseda

Subjects

010405 organic chemistry, Organic Chemistry, 3,6-anhydro-α-L-galactopyranose, Disaccharide, 010402 general chemistry, 01 natural sciences, Reductive amination, Semisynthesis, reductive amination, 0104 chemical sciences, lcsh:QD241-441, chemistry.chemical_compound, Hydrolysis, chemistry, lcsh:Organic chemistry, Moiety, Organic chemistry, Agarose, protecting-group-free, lcsh:Q, amino sugar, lcsh:Science, Ammonium acetate, Dimethylamine, polysaccharide (agar)

Abstract

Agarose was herein employed as starting material to produce primary, secondary and tertiary C-glycoside glycamines, including mono- and disaccharide structures. The semisynthetic approach utilized was generally based on polysaccharide-controlled hydrolysis followed by reductive amination. All reactions were conducted in aqueous media and without the need of hydroxyl group protection. We were able to identify optimal conditions for the reductive amination of agar hydrolysis products and to overcome the major difficulties related to this kind of reaction, also extending it to reducing anhydrosugars. The excess of ammonium acetate, methyl- or dimethylamine, and the use of a diluted basic (pH 11) reaction media were identified as important aspects to achieve improved yields, as well as to decrease the amount of byproducts commonly related to reductive amination of carbohydrates. This strategy allowed the transposition of the 3,6-anhydro-α-L-galactopyranose unit (naturally present in the agarose structure) to all glycamines synthesized, constituting an amino-substituted C-threofuranoside moiety, which is closely related to (+)-muscarine.

Published

2017

3. Aqueous semisynthesis of

Author

Juliana C Cunico, Dallagnol, Alexandre, Orsato, Diogo R B, Ducatti, Miguel D, Noseda, Maria Eugênia R, Duarte, and Alan G, Gonçalves

Subjects

Chemistry, Letter, Organic Chemistry, 3,6-anhydro-α-L-galactopyranose, protecting-group-free, amino sugar, reductive amination, polysaccharide (agar)

Abstract

Agarose was herein employed as starting material to produce primary, secondary and tertiary C-glycoside glycamines, including mono- and disaccharide structures. The semisynthetic approach utilized was generally based on polysaccharide-controlled hydrolysis followed by reductive amination. All reactions were conducted in aqueous media and without the need of hydroxyl group protection. We were able to identify optimal conditions for the reductive amination of agar hydrolysis products and to overcome the major difficulties related to this kind of reaction, also extending it to reducing anhydrosugars. The excess of ammonium acetate, methyl- or dimethylamine, and the use of a diluted basic (pH 11) reaction media were identified as important aspects to achieve improved yields, as well as to decrease the amount of byproducts commonly related to reductive amination of carbohydrates. This strategy allowed the transposition of the 3,6-anhydro-α-L-galactopyranose unit (naturally present in the agarose structure) to all glycamines synthesized, constituting an amino-substituted C-threofuranoside moiety, which is closely related to (+)-muscarine.

Published

2017

4. Aqueous semisynthesis of C -glycoside glycamines from agarose.

Author

Dallagnol JCC, Orsato A, Ducatti DRB, Noseda MD, Duarte MER, and Gonçalves AG

Abstract

Agarose was herein employed as starting material to produce primary, secondary and tertiary C -glycoside glycamines, including mono- and disaccharide structures. The semisynthetic approach utilized was generally based on polysaccharide-controlled hydrolysis followed by reductive amination. All reactions were conducted in aqueous media and without the need of hydroxyl group protection. We were able to identify optimal conditions for the reductive amination of agar hydrolysis products and to overcome the major difficulties related to this kind of reaction, also extending it to reducing anhydrosugars. The excess of ammonium acetate, methyl- or dimethylamine, and the use of a diluted basic (pH 11) reaction media were identified as important aspects to achieve improved yields, as well as to decrease the amount of byproducts commonly related to reductive amination of carbohydrates. This strategy allowed the transposition of the 3,6-anhydro-α-L-galactopyranose unit (naturally present in the agarose structure) to all glycamines synthesized, constituting an amino-substituted C -threofuranoside moiety, which is closely related to (+)-muscarine.

Published

2017