Alginate utility in edible and non edible film development and the influence of its macromolecular structure in the antioxidant activity of a pharmaceutical/food interface

Edible films and coatings are mostly investigated as an interesting alternative for food packaging. Edible films habitually developed for food protection are very good barriers to gases but not to water vapor because polysaccharides and proteins have to be used for their development. Nowadays, there...

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Detalles Bibliográficos
Autores principales: De'Nobili, M.D., Curto, L.M., Delfino, J.M., Pérez, C.D., Bernhardt, D., Gerschenson, L.N., Fissore, E.N., Rojas, A.M.
Formato: CHAP
Materias:
Alginate edible films
Antioxidant interface
Ascorbic acid hydrolysis
Blends and composites
Copolymer composition
Water
Antioxidants
Ascorbic acid
Beverages
Biocompatibility
Biomechanics
Calcium
Cell culture
Encapsulation
Food preservation
Food preservatives
Gas permeable membranes
Hydrogen bonds
Macromolecules
mHealth
Rate constants
Sodium alginate
Targeted drug delivery
Tissue engineering
Water vapor
Acid hydrolysis
Copolymer compositions
Edible films
Food and beverage industry
Macromolecular structures
Pharmaceutical formulation
Pharmaceutical industry
Physical and mechanical properties
Controlled drug delivery
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_97816346_v_n_p119_DeNobili
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id todo:paper_97816346_v_n_p119_DeNobili
record_format dspace
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic Alginate edible films
Antioxidant interface
Ascorbic acid hydrolysis
Blends and composites
Copolymer composition
Water
Antioxidants
Ascorbic acid
Beverages
Biocompatibility
Biomechanics
Calcium
Cell culture
Encapsulation
Food preservation
Food preservatives
Gas permeable membranes
Hydrogen bonds
Macromolecules
mHealth
Rate constants
Sodium alginate
Targeted drug delivery
Tissue engineering
Water
Water vapor
Acid hydrolysis
Copolymer compositions
Edible films
Food and beverage industry
Macromolecular structures
Pharmaceutical formulation
Pharmaceutical industry
Physical and mechanical properties
Controlled drug delivery
spellingShingle Alginate edible films
Antioxidant interface
Ascorbic acid hydrolysis
Blends and composites
Copolymer composition
Water
Antioxidants
Ascorbic acid
Beverages
Biocompatibility
Biomechanics
Calcium
Cell culture
Encapsulation
Food preservation
Food preservatives
Gas permeable membranes
Hydrogen bonds
Macromolecules
mHealth
Rate constants
Sodium alginate
Targeted drug delivery
Tissue engineering
Water
Water vapor
Acid hydrolysis
Copolymer compositions
Edible films
Food and beverage industry
Macromolecular structures
Pharmaceutical formulation
Pharmaceutical industry
Physical and mechanical properties
Controlled drug delivery
De'Nobili, M.D.
Curto, L.M.
Delfino, J.M.
Pérez, C.D.
Bernhardt, D.
Gerschenson, L.N.
Fissore, E.N.
Rojas, A.M.
Alginate utility in edible and non edible film development and the influence of its macromolecular structure in the antioxidant activity of a pharmaceutical/food interface
topic_facet Alginate edible films
Antioxidant interface
Ascorbic acid hydrolysis
Blends and composites
Copolymer composition
Water
Antioxidants
Ascorbic acid
Beverages
Biocompatibility
Biomechanics
Calcium
Cell culture
Encapsulation
Food preservation
Food preservatives
Gas permeable membranes
Hydrogen bonds
Macromolecules
mHealth
Rate constants
Sodium alginate
Targeted drug delivery
Tissue engineering
Water
Water vapor
Acid hydrolysis
Copolymer compositions
Edible films
Food and beverage industry
Macromolecular structures
Pharmaceutical formulation
Pharmaceutical industry
Physical and mechanical properties
Controlled drug delivery
description Edible films and coatings are mostly investigated as an interesting alternative for food packaging. Edible films habitually developed for food protection are very good barriers to gases but not to water vapor because polysaccharides and proteins have to be used for their development. Nowadays, there are many research works which look for decreasing film permeability to water vapor. Beyond this fact, edible films are much studied matrices since they can be also applied as a technological hurdle for food preservation because their microstructure can be used to carry, stabilize, localize the activity and control the release of food preservatives (antimicrobials, antioxidants) at interfaces. For non edible purposes, films can be also applied for wound dressings as drug delivery systems to improve wound healing. Also, to tissue engineering. Alginate polymers have long been used in the food and beverage industries as thickenners, gel- forming and colloidal stabilizing agents. Alginates are also used in the pharmaceutical industry as matrices for drug encapsulation, as substrates for cell culture, as binders for medical tablets and for many applications of controlled drug delivery. Alginic acid is a natural unbranched binary copolymer constituted by (1,4)-linked β-D-mannuronic acid (MM-block) and α-L-(1,4)-linked guluronic acid (GG-block), as well as by sequences of alternating β-D-mannuronic and α-L-guluronic acid (MG- and GM-blocks), producing different macromolecular structures of alginates. Physical and mechanical properties as well as biocompatibility of alginate materials are highly dependent on the relative content of L-guluronic to D-mannuronic acids. Calcium ions can replace in part the hydrogen bonding, zipping guluronate (but not mannuronate) chains together in an 'egg-box' conformation. A decrease in the swelling rate constant with elevated calcium concentration was determined. As a consequence, the release of embodied active compounds in alginate matrices will be also delayed, allowing these systems to be used in controlled release of drugs and food preservatives. This fact makes of alginic acid an interesting biopolymer for being applied to film development. This chapter reviews in recent literature, the utilization of alginates to the development of films applied to food and pharmaceutical formulation. Since it is generally observed that researchers rarely know and consider the composition of the alginate that they used for film development, a study where the influence of the alginate copolymer composition on the stability of the L- (+)-ascorbic acid supported in films is also reported. They were obtained for acting as controlled delivery systems for nutritional supplementation, therapy or antioxidant activity at interfaces. © 2015 by Nova Science Publishers, Inc. All rights reserved.
format CHAP
author De'Nobili, M.D.
Curto, L.M.
Delfino, J.M.
Pérez, C.D.
Bernhardt, D.
Gerschenson, L.N.
Fissore, E.N.
Rojas, A.M.
author_facet De'Nobili, M.D.
Curto, L.M.
Delfino, J.M.
Pérez, C.D.
Bernhardt, D.
Gerschenson, L.N.
Fissore, E.N.
Rojas, A.M.
author_sort De'Nobili, M.D.
title Alginate utility in edible and non edible film development and the influence of its macromolecular structure in the antioxidant activity of a pharmaceutical/food interface
title_short Alginate utility in edible and non edible film development and the influence of its macromolecular structure in the antioxidant activity of a pharmaceutical/food interface
title_full Alginate utility in edible and non edible film development and the influence of its macromolecular structure in the antioxidant activity of a pharmaceutical/food interface
title_fullStr Alginate utility in edible and non edible film development and the influence of its macromolecular structure in the antioxidant activity of a pharmaceutical/food interface
title_full_unstemmed Alginate utility in edible and non edible film development and the influence of its macromolecular structure in the antioxidant activity of a pharmaceutical/food interface
title_sort alginate utility in edible and non edible film development and the influence of its macromolecular structure in the antioxidant activity of a pharmaceutical/food interface
url http://hdl.handle.net/20.500.12110/paper_97816346_v_n_p119_DeNobili
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spelling todo:paper_97816346_v_n_p119_DeNobili2023-10-03T16:44:37Z Alginate utility in edible and non edible film development and the influence of its macromolecular structure in the antioxidant activity of a pharmaceutical/food interface De'Nobili, M.D. Curto, L.M. Delfino, J.M. Pérez, C.D. Bernhardt, D. Gerschenson, L.N. Fissore, E.N. Rojas, A.M. Alginate edible films Antioxidant interface Ascorbic acid hydrolysis Blends and composites Copolymer composition Water Antioxidants Ascorbic acid Beverages Biocompatibility Biomechanics Calcium Cell culture Encapsulation Food preservation Food preservatives Gas permeable membranes Hydrogen bonds Macromolecules mHealth Rate constants Sodium alginate Targeted drug delivery Tissue engineering Water Water vapor Acid hydrolysis Copolymer compositions Edible films Food and beverage industry Macromolecular structures Pharmaceutical formulation Pharmaceutical industry Physical and mechanical properties Controlled drug delivery Edible films and coatings are mostly investigated as an interesting alternative for food packaging. Edible films habitually developed for food protection are very good barriers to gases but not to water vapor because polysaccharides and proteins have to be used for their development. Nowadays, there are many research works which look for decreasing film permeability to water vapor. Beyond this fact, edible films are much studied matrices since they can be also applied as a technological hurdle for food preservation because their microstructure can be used to carry, stabilize, localize the activity and control the release of food preservatives (antimicrobials, antioxidants) at interfaces. For non edible purposes, films can be also applied for wound dressings as drug delivery systems to improve wound healing. Also, to tissue engineering. Alginate polymers have long been used in the food and beverage industries as thickenners, gel- forming and colloidal stabilizing agents. Alginates are also used in the pharmaceutical industry as matrices for drug encapsulation, as substrates for cell culture, as binders for medical tablets and for many applications of controlled drug delivery. Alginic acid is a natural unbranched binary copolymer constituted by (1,4)-linked β-D-mannuronic acid (MM-block) and α-L-(1,4)-linked guluronic acid (GG-block), as well as by sequences of alternating β-D-mannuronic and α-L-guluronic acid (MG- and GM-blocks), producing different macromolecular structures of alginates. Physical and mechanical properties as well as biocompatibility of alginate materials are highly dependent on the relative content of L-guluronic to D-mannuronic acids. Calcium ions can replace in part the hydrogen bonding, zipping guluronate (but not mannuronate) chains together in an 'egg-box' conformation. A decrease in the swelling rate constant with elevated calcium concentration was determined. As a consequence, the release of embodied active compounds in alginate matrices will be also delayed, allowing these systems to be used in controlled release of drugs and food preservatives. This fact makes of alginic acid an interesting biopolymer for being applied to film development. This chapter reviews in recent literature, the utilization of alginates to the development of films applied to food and pharmaceutical formulation. Since it is generally observed that researchers rarely know and consider the composition of the alginate that they used for film development, a study where the influence of the alginate copolymer composition on the stability of the L- (+)-ascorbic acid supported in films is also reported. They were obtained for acting as controlled delivery systems for nutritional supplementation, therapy or antioxidant activity at interfaces. © 2015 by Nova Science Publishers, Inc. All rights reserved. Fil:Pérez, C.D. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Gerschenson, L.N. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Fissore, E.N. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Rojas, A.M. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. CHAP info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_97816346_v_n_p119_DeNobili

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