Acrylamide bioaccessibility in potato and veggie chips. Impact of in vitro colonic fermentation on the non-bioaccessible fraction

[Display omitted] •In vitro acrylamide bioaccessibility of potato and veggie chips was monitored.•In vitro fermentation of the non-bioaccessible fraction was also evaluated.•Potentially absorbable acrylamide increased in sweet potatoes in the children group.•Fibre fermentation could release acrylami...

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Published in:Food research international 2023-02, Vol.164, p.112409-112409, Article 112409
Main Authors: González-Mulero, L., Mesías, M., Morales, F.J., Navajas-Porras, B., Rufián-Henares, J.A., Delgado-Andrade, C.
Format: Article
Language:English
Subjects:
Acrylamide
Acrylamide - analysis
acrylamides
Adolescent
Adult
beets
Bioaccessible fraction
bioavailability
carrots
Child
Colonic fermentation
Daucus carota
digestion
Fermentation
Food Handling
food matrix
food research
gastrointestinal system
Humans
In vitro digestion
microorganisms
Non-bioaccessible fraction
Potato chips
potatoes
risk assessment
Snack products
Solanum tuberosum
sweet potatoes
Vegetables
Veggie chips
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Summary:[Display omitted] •In vitro acrylamide bioaccessibility of potato and veggie chips was monitored.•In vitro fermentation of the non-bioaccessible fraction was also evaluated.•Potentially absorbable acrylamide increased in sweet potatoes in the children group.•Fibre fermentation could release acrylamide at colonic level.•Food matrix and microbiota composition could affect acrylamide absorption. Potato-based products contribute largely to the daily intake of acrylamide. In addition to potato crisps, the European Commission has included veggie crisps in the list of foods that should be monitored for their acrylamide content. In the present study, acrylamide content in potato and veggie chips (sweet potato, beetroot and carrot) and their bioaccessibility after in vitro digestion was assessed. The non-bioaccessible fraction was also submitted to in vitro fermentation under colonic conditions. Faecal samples from volunteers of three age groups (children, adolescents and adults) were used to evaluate the microbiota effect on the acrylamide availability. Sweet potato chips exhibited the highest acrylamide content (2342 µg/kg), followed by carrot (1279 µg/kg), beetroot (947 µg/kg) and potato chips (524 µg/kg). After in vitro digestion, acrylamide bioaccessibility was significantly lower in veggie chips (59.7–60.4 %) than in potato chips (71.7 %). Potato and sweet potato chips showed the significantly lowest acrylamide content in the non-bioaccessible fraction (22.8 and 24.1 %, respectively) as compared with beetroot chips (28.4 %). After the fermentation step, acrylamide percentage in the soluble fraction of veggie chips ranged from 43.03 to 71.89 %, the highest values being observed in sweet potato chips fermented with microbiota from children. This fact would involve that the acrylamide was released from the non-bioaccessible fractions by the microbiota. These findings point out that the levels of potentially absorbable acrylamide after the complete gastrointestinal process could be modulated by both the food matrix composition and the microbiota. These factors should be further considered for a more precise risk assessment of dietary acrylamide in humans.
ISSN:0963-9969
1873-7145
DOI:10.1016/j.foodres.2022.112409