Impact of processing on the stability and bioaccessibility of Pro-Vitamin A Carotenoids in biofortified cassava roots (Manihot esculanta, Crantz)

Impact of processing on the stability and bioaccessibility of Pro-Vitamin A Carotenoids in biofortified cassava roots (Manihot esculanta, Crantz)

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Carotenoid content in cassava roots has been increased through biofortification programs as a strategy to combat vitamin A deficiency. However, incorporation of biofortified cassava into both traditional and industrial food processing has yet to be fully assessed. The objective of this study was to examine the impact of fermentation and thermal processing on the stability and bioaccessibility of pro-vitamin A carotenoids from distinct biofortified cassava roots. Unfermented (UF) and fermented (F) flours were produced from 10 biofortified cassava cultivars (Table 1 & Figure 2). Gari (G) flours were produced by toasting two of the fermented cultivars above at 150-160oC during 15-20 min. Test porridges were prepared with UF, F and G (22.2% W/V) in boiling water for 5 min. Bioaccessibility of pro-vitamin A carotenoids was then evaluated from finished products using a three-stage in vitro digestion model (Figure 3). Overall, cassava cultivars contained 23.1-42.7 μg of β-carotene equivalents (β-CE) / g on dry weight bases (DW). β-CE retention after fermentation was 72.5-96.6%; after oven-drying were 18.3-77.5% and 45.8-80.4% for UF and F roots, respectively; after toasting in Gari preparation was 67.3-69.2%; after cooking in porridge preparations were 42.5-74.5%, 20.7-77.3% and 87.2-115.3% for UF, F and G flours, respectively (Figure 4 & 5). Cassava flours, which involved fermentation showed higher β-CE retention (p=0.007) during oven-drying compared with UF flours. However, no significant differences were found in β-CE retention during porridge preparation (p=0.905). Test porridges made from UF, F and G flours ranged from 39-309, 58-343 and 223-323 μg β-CE / 100 g FW, respectively. Bioaccessibility ranged widely from 3.3-56.9 μg β-CE / 100 g FW with bioaccessible content among the cultivars within the porridges groups ranging from 3.3-43.4, 3.66-21.4 and 20.3-56.9 μg / 100 g FW for UF, F and G flours, respectively (Figure 6). In general, bioaccessible β-CE content from porridges prepared with UF and F flours were similar with levels of 14.5 +/- 4.2 and 12.7 +/- 1.8 μg / 100 g FW, (p = 0.700). Select cassava cultivars showed improved bioaccessibility of β- CE content with the fermentation process, these results suggest that genotype factor and/or another factors in the matrix merit further investigation as they may play a significant role in facilitating bioaccessibility of carotenoids from biofortified cassava products.

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Main Authors: Aragón Gallego, Ingrid J., Dufour, D.L., Escobar Salamanca, Andrés F., Calle, Fernando, Ferruzzi, Mario G.
Format: Poster biblioteca
Language:English
Published: 2016
Subjects:manihot esculenta, food fortification, carotenoids, flours, fermentation, cassava, fortificación de alimentos, carotenoides, harinas, fermentación, yuca,
Online Access:https://hdl.handle.net/10568/73219
https://agritrop.cirad.fr/580186/1/AFF%20Impact%20of%20processing%20Dufour%202016.pdf
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spelling dig-cgspace-10568-732192017-04-23T00:02:33Z Impact of processing on the stability and bioaccessibility of Pro-Vitamin A Carotenoids in biofortified cassava roots (Manihot esculanta, Crantz) Aragón Gallego, Ingrid J. Dufour, D.L. Escobar Salamanca, Andrés F. Calle, Fernando Ferruzzi, Mario G. manihot esculenta food fortification carotenoids flours fermentation cassava fortificación de alimentos carotenoides harinas fermentación yuca Carotenoid content in cassava roots has been increased through biofortification programs as a strategy to combat vitamin A deficiency. However, incorporation of biofortified cassava into both traditional and industrial food processing has yet to be fully assessed. The objective of this study was to examine the impact of fermentation and thermal processing on the stability and bioaccessibility of pro-vitamin A carotenoids from distinct biofortified cassava roots. Unfermented (UF) and fermented (F) flours were produced from 10 biofortified cassava cultivars (Table 1 & Figure 2). Gari (G) flours were produced by toasting two of the fermented cultivars above at 150-160oC during 15-20 min. Test porridges were prepared with UF, F and G (22.2% W/V) in boiling water for 5 min. Bioaccessibility of pro-vitamin A carotenoids was then evaluated from finished products using a three-stage in vitro digestion model (Figure 3). Overall, cassava cultivars contained 23.1-42.7 μg of β-carotene equivalents (β-CE) / g on dry weight bases (DW). β-CE retention after fermentation was 72.5-96.6%; after oven-drying were 18.3-77.5% and 45.8-80.4% for UF and F roots, respectively; after toasting in Gari preparation was 67.3-69.2%; after cooking in porridge preparations were 42.5-74.5%, 20.7-77.3% and 87.2-115.3% for UF, F and G flours, respectively (Figure 4 & 5). Cassava flours, which involved fermentation showed higher β-CE retention (p=0.007) during oven-drying compared with UF flours. However, no significant differences were found in β-CE retention during porridge preparation (p=0.905). Test porridges made from UF, F and G flours ranged from 39-309, 58-343 and 223-323 μg β-CE / 100 g FW, respectively. Bioaccessibility ranged widely from 3.3-56.9 μg β-CE / 100 g FW with bioaccessible content among the cultivars within the porridges groups ranging from 3.3-43.4, 3.66-21.4 and 20.3-56.9 μg / 100 g FW for UF, F and G flours, respectively (Figure 6). In general, bioaccessible β-CE content from porridges prepared with UF and F flours were similar with levels of 14.5 +/- 4.2 and 12.7 +/- 1.8 μg / 100 g FW, (p = 0.700). Select cassava cultivars showed improved bioaccessibility of β- CE content with the fermentation process, these results suggest that genotype factor and/or another factors in the matrix merit further investigation as they may play a significant role in facilitating bioaccessibility of carotenoids from biofortified cassava products. 2016 2016-04-26T19:05:47Z 2016-04-26T19:05:47Z Poster Aragon, Ingrid; Dufour, Dominique; Escobar, Andres Felipe; Calle, Fernando; Ceballos, Hernan; Ferruzzi, Mario G.. 2016. Impact of processing on the stability and bioaccessibility of Pro-Vitamin A Carotenoids in biofortified cassava roots (Manihot esculanta, Crantz) 1 p. (Poster presented at Experimental Biology conference (EB) in San Diego (April 2-6/2016). Accepted Abstract 5331. Session 914. CARIG: Biofortification of staple crops with micronutrients). https://hdl.handle.net/10568/73219 https://agritrop.cirad.fr/580186/1/AFF%20Impact%20of%20processing%20Dufour%202016.pdf en Open Access 1 p. application/pdf
institution CGIAR
collection DSpace
country Francia
countrycode FR
component Bibliográfico
access En linea
databasecode dig-cgspace
tag biblioteca
region Europa del Oeste
libraryname Biblioteca del CGIAR
language English
topic manihot esculenta
food fortification
carotenoids
flours
fermentation
cassava
fortificación de alimentos
carotenoides
harinas
fermentación
yuca
manihot esculenta
food fortification
carotenoids
flours
fermentation
cassava
fortificación de alimentos
carotenoides
harinas
fermentación
yuca
spellingShingle manihot esculenta
food fortification
carotenoids
flours
fermentation
cassava
fortificación de alimentos
carotenoides
harinas
fermentación
yuca
manihot esculenta
food fortification
carotenoids
flours
fermentation
cassava
fortificación de alimentos
carotenoides
harinas
fermentación
yuca
Aragón Gallego, Ingrid J.
Dufour, D.L.
Escobar Salamanca, Andrés F.
Calle, Fernando
Ferruzzi, Mario G.
Impact of processing on the stability and bioaccessibility of Pro-Vitamin A Carotenoids in biofortified cassava roots (Manihot esculanta, Crantz)
description Carotenoid content in cassava roots has been increased through biofortification programs as a strategy to combat vitamin A deficiency. However, incorporation of biofortified cassava into both traditional and industrial food processing has yet to be fully assessed. The objective of this study was to examine the impact of fermentation and thermal processing on the stability and bioaccessibility of pro-vitamin A carotenoids from distinct biofortified cassava roots. Unfermented (UF) and fermented (F) flours were produced from 10 biofortified cassava cultivars (Table 1 & Figure 2). Gari (G) flours were produced by toasting two of the fermented cultivars above at 150-160oC during 15-20 min. Test porridges were prepared with UF, F and G (22.2% W/V) in boiling water for 5 min. Bioaccessibility of pro-vitamin A carotenoids was then evaluated from finished products using a three-stage in vitro digestion model (Figure 3). Overall, cassava cultivars contained 23.1-42.7 μg of β-carotene equivalents (β-CE) / g on dry weight bases (DW). β-CE retention after fermentation was 72.5-96.6%; after oven-drying were 18.3-77.5% and 45.8-80.4% for UF and F roots, respectively; after toasting in Gari preparation was 67.3-69.2%; after cooking in porridge preparations were 42.5-74.5%, 20.7-77.3% and 87.2-115.3% for UF, F and G flours, respectively (Figure 4 & 5). Cassava flours, which involved fermentation showed higher β-CE retention (p=0.007) during oven-drying compared with UF flours. However, no significant differences were found in β-CE retention during porridge preparation (p=0.905). Test porridges made from UF, F and G flours ranged from 39-309, 58-343 and 223-323 μg β-CE / 100 g FW, respectively. Bioaccessibility ranged widely from 3.3-56.9 μg β-CE / 100 g FW with bioaccessible content among the cultivars within the porridges groups ranging from 3.3-43.4, 3.66-21.4 and 20.3-56.9 μg / 100 g FW for UF, F and G flours, respectively (Figure 6). In general, bioaccessible β-CE content from porridges prepared with UF and F flours were similar with levels of 14.5 +/- 4.2 and 12.7 +/- 1.8 μg / 100 g FW, (p = 0.700). Select cassava cultivars showed improved bioaccessibility of β- CE content with the fermentation process, these results suggest that genotype factor and/or another factors in the matrix merit further investigation as they may play a significant role in facilitating bioaccessibility of carotenoids from biofortified cassava products.
format Poster
topic_facet manihot esculenta
food fortification
carotenoids
flours
fermentation
cassava
fortificación de alimentos
carotenoides
harinas
fermentación
yuca
author Aragón Gallego, Ingrid J.
Dufour, D.L.
Escobar Salamanca, Andrés F.
Calle, Fernando
Ferruzzi, Mario G.
author_facet Aragón Gallego, Ingrid J.
Dufour, D.L.
Escobar Salamanca, Andrés F.
Calle, Fernando
Ferruzzi, Mario G.
author_sort Aragón Gallego, Ingrid J.
title Impact of processing on the stability and bioaccessibility of Pro-Vitamin A Carotenoids in biofortified cassava roots (Manihot esculanta, Crantz)
title_short Impact of processing on the stability and bioaccessibility of Pro-Vitamin A Carotenoids in biofortified cassava roots (Manihot esculanta, Crantz)
title_full Impact of processing on the stability and bioaccessibility of Pro-Vitamin A Carotenoids in biofortified cassava roots (Manihot esculanta, Crantz)
title_fullStr Impact of processing on the stability and bioaccessibility of Pro-Vitamin A Carotenoids in biofortified cassava roots (Manihot esculanta, Crantz)
title_full_unstemmed Impact of processing on the stability and bioaccessibility of Pro-Vitamin A Carotenoids in biofortified cassava roots (Manihot esculanta, Crantz)
title_sort impact of processing on the stability and bioaccessibility of pro-vitamin a carotenoids in biofortified cassava roots (manihot esculanta, crantz)
publishDate 2016
url https://hdl.handle.net/10568/73219
https://agritrop.cirad.fr/580186/1/AFF%20Impact%20of%20processing%20Dufour%202016.pdf
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