Husks of Zea mays as a potential source of biopolymers for food additives and materials' development

Husks of Zea mays as a potential source of biopolymers for food additives and materials' development

Maize husks, an agricultural and industrial residue generated in a large volume, were investigated as a potential source of useful biopolymers. Thus, their chemical composition was firstly studied, after which two biopolymer products were obtained and characterized. Maize husks were dried and milled...

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Main Authors: Dana C. Bernhardt, Nora M.A. Ponce, Maria F. Basanta, Carlos A. Stortz, Ana M. Rojas
Format: Article
Language:English
Published: Elsevier 2019-03-01
Series:Heliyon
Subjects:
Food science
Online Access:http://www.sciencedirect.com/science/article/pii/S2405844018369779
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spelling doaj-9176686deacb44d4b8fad8a4dedf72d72020-11-25T02:09:50ZengElsevierHeliyon2405-84402019-03-0153e01313Husks of Zea mays as a potential source of biopolymers for food additives and materials' developmentDana C. Bernhardt0Nora M.A. Ponce1Maria F. Basanta2Carlos A. Stortz3Ana M. Rojas4Departamento de Industrias-ITAPROQ, Argentina; CONICET, ArgentinaDepartamento de Química Orgánica-CIHIDECAR, Facultad de Ciencias Exactas y Naturales, Universidad de Buenos Aires, Ciudad Universitaria, C1428BGA Buenos Aires, Argentina; CONICET, ArgentinaDepartamento de Industrias-ITAPROQ, Argentina; CONICET, ArgentinaDepartamento de Química Orgánica-CIHIDECAR, Facultad de Ciencias Exactas y Naturales, Universidad de Buenos Aires, Ciudad Universitaria, C1428BGA Buenos Aires, Argentina; CONICET, ArgentinaDepartamento de Industrias-ITAPROQ, Argentina; CONICET, Argentina; Corresponding author.Maize husks, an agricultural and industrial residue generated in a large volume, were investigated as a potential source of useful biopolymers. Thus, their chemical composition was firstly studied, after which two biopolymer products were obtained and characterized. Maize husks were dried and milled, obtaining a 210 μm-main particle size powder (MHP). It contained carotenes (4 mg/100 g), and exhibited antioxidant capacity (≈195 mg ascorbic acid/100 g MHP) coming also from extractable coumaric and cinnamic acids-derivatives (14 mg/100 g). A 31% of the MPH was water-soluble at room temperature, mainly constituted by fructose, glucose, and sorbitol of mesophylls' intracellular origin. The water insoluble fiber (WIF, ≈70%), which showed antioxidant capacity (≈25–33 mg ascorbic acid/100 g WIF), was almost entirely constituted by the cell wall biopolymers or alcohol insoluble residue (AIR) of the MPH, mostly arabinoxylans (≈26%) crosslinked by ferulic residues (18.6 mg/100 g MPH), and cellulose (26%). Low levels of pectins (5.5%) and lignin (7%) were found. Hence, a 1.25%-sulfur nanocellulose (NCC) was directly obtained with sulfuric acid (−15 mV Zeta-potential; 147 °C onset of thermal-degradation) without the necessity of previous delignification. On the other hand, a water soluble arabinoxylan enriched fraction (AX-EF) with pseudoplastic behavior in water and sensibility to calcium ions (≈3 Pa⋅s initial Newtonian-viscosity) was isolated by alkaline hydrolysis of diferulate bridges. Despite a 56% of crystallinity, NCC showed the highest water absorption capacity when compared to that of the AX-EF and AIR. Maize husks constitute an important source of biopolymers for development of materials and food additives/ingredients with relevant hydration and antioxidant properties.http://www.sciencedirect.com/science/article/pii/S2405844018369779Food science
collection DOAJ
language English
format Article
sources DOAJ
author Dana C. Bernhardt
Nora M.A. Ponce
Maria F. Basanta
Carlos A. Stortz
Ana M. Rojas
spellingShingle Dana C. Bernhardt
Nora M.A. Ponce
Maria F. Basanta
Carlos A. Stortz
Ana M. Rojas
Husks of Zea mays as a potential source of biopolymers for food additives and materials' development
Heliyon
Food science
author_facet Dana C. Bernhardt
Nora M.A. Ponce
Maria F. Basanta
Carlos A. Stortz
Ana M. Rojas
author_sort Dana C. Bernhardt
title Husks of Zea mays as a potential source of biopolymers for food additives and materials' development
title_short Husks of Zea mays as a potential source of biopolymers for food additives and materials' development
title_full Husks of Zea mays as a potential source of biopolymers for food additives and materials' development
title_fullStr Husks of Zea mays as a potential source of biopolymers for food additives and materials' development
title_full_unstemmed Husks of Zea mays as a potential source of biopolymers for food additives and materials' development
title_sort husks of zea mays as a potential source of biopolymers for food additives and materials' development
publisher Elsevier
series Heliyon
issn 2405-8440
publishDate 2019-03-01
description Maize husks, an agricultural and industrial residue generated in a large volume, were investigated as a potential source of useful biopolymers. Thus, their chemical composition was firstly studied, after which two biopolymer products were obtained and characterized. Maize husks were dried and milled, obtaining a 210 μm-main particle size powder (MHP). It contained carotenes (4 mg/100 g), and exhibited antioxidant capacity (≈195 mg ascorbic acid/100 g MHP) coming also from extractable coumaric and cinnamic acids-derivatives (14 mg/100 g). A 31% of the MPH was water-soluble at room temperature, mainly constituted by fructose, glucose, and sorbitol of mesophylls' intracellular origin. The water insoluble fiber (WIF, ≈70%), which showed antioxidant capacity (≈25–33 mg ascorbic acid/100 g WIF), was almost entirely constituted by the cell wall biopolymers or alcohol insoluble residue (AIR) of the MPH, mostly arabinoxylans (≈26%) crosslinked by ferulic residues (18.6 mg/100 g MPH), and cellulose (26%). Low levels of pectins (5.5%) and lignin (7%) were found. Hence, a 1.25%-sulfur nanocellulose (NCC) was directly obtained with sulfuric acid (−15 mV Zeta-potential; 147 °C onset of thermal-degradation) without the necessity of previous delignification. On the other hand, a water soluble arabinoxylan enriched fraction (AX-EF) with pseudoplastic behavior in water and sensibility to calcium ions (≈3 Pa⋅s initial Newtonian-viscosity) was isolated by alkaline hydrolysis of diferulate bridges. Despite a 56% of crystallinity, NCC showed the highest water absorption capacity when compared to that of the AX-EF and AIR. Maize husks constitute an important source of biopolymers for development of materials and food additives/ingredients with relevant hydration and antioxidant properties.
topic Food science
url http://www.sciencedirect.com/science/article/pii/S2405844018369779
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