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dc.contributor.authorAdesokan, M.
dc.contributor.authorAlamu, E.O.
dc.contributor.authorFawole, S.
dc.contributor.authorMaziya-Dixon, B.
dc.date.accessioned2023-06-20T11:04:58Z
dc.date.available2023-06-20T11:04:58Z
dc.date.issued2023-05-10
dc.identifier.citationAdesokan, M., Alamu, E.O., Fawole, S. & Maziya-Dixon, B. (2023). Prediction of functional characteristics of gari (cassava flakes) using near-infrared reflectance spectrometry. Frontiers in Chemistry, 11: 1156718, 1-9.
dc.identifier.issn2296-2646
dc.identifier.urihttps://hdl.handle.net/20.500.12478/8209
dc.description.abstractGari is a creamy, granular flour obtained from roasting fermented cassava mash. Its preparation involves several unit operations, including fermentation, which is essential in gari production. Fermentation brings about specific biochemical changes in cassava starch due to the actions of lactic acid bacteria. Consequently, it gives rise to organic acids and a significant reduction in the pH. Consumer preferences for gari are influenced by these changes and impact specific functional characteristics, which are often linked to cassava genotypes. Measurement of these functional characteristics is time-consuming and expensive. Therefore, this study aimed to develop high-throughput and less expensive prediction models for water absorption capacity, swelling power, bulk density, and dispersibility using Near-Infrared Reflectance Spectroscopy (NIRS). Gari was produced from 63 cassava genotypes using the standard method developed in the RTB foods project. The prediction model was developed by dividing the gari samples into two sets of 48 samples for calibration and 15 samples as the validation set. The gari samples were transferred into a ring cell cup and scanned on the NIRS machine within the Vis-NIR range of 400–2,498 nm wavelength, though only the NIR range of 800–2,400 nm was used to build the model. Calibration models were developed using partial least regression algorithms after spectra preprocessing. Also, the gari samples were analysed in the laboratory for their functional properties to generate reference data. Results showed an excellent coefficient of determination in calibrations (R2 Cal) of 0.99, 0.97, 0.97, and 0.89 for bulk density, swelling power, dispersibility, and water absorption capacity, respectively. Also, the performances of the prediction models were tested using an independent set of 15 gari samples. A good prediction coefficient (R2 pred) and low standard error of prediction (SEP) was obtained as follows: Bulk density (0.98), Swelling power (0.93), WAC (0.68), Dispersibility (0.65), and solubility index (0.62), respectively. Therefore, NIRS prediction models in this study could provide a rapid screening tool for cassava breeding programs and food scientists to determine the food quality of cassava granular products (Gari).
dc.description.sponsorshipFrench Agricultural Research Centre for International Development
dc.description.sponsorshipBill & Melinda Gates Foundation
dc.format.extent1-9
dc.language.isoen
dc.subjectCassava
dc.subjectGari
dc.subjectProperties
dc.subjectInfrared Spectrophotometry
dc.subjectForecasting
dc.titlePrediction of functional characteristics of gari (cassava flakes) using near-infrared reflectance spectrometry
dc.typeJournal Article
cg.contributor.crpAgriculture for Nutrition and Health
cg.contributor.crpMaize
cg.contributor.crpRoots, Tubers and Bananas
cg.contributor.affiliationInternational Institute of Tropical Agriculture
cg.coverage.regionAfrica
cg.coverage.regionWest Africa
cg.coverage.countryNigeria
cg.coverage.hubSouthern Africa Hub
cg.coverage.hubHeadquarters and Western Africa Hub
cg.researchthemeNutrition and Human Health
cg.identifier.bibtexciteidADESOKAN:2023a
cg.isijournalISI Journal
cg.authorship.typesCGIAR Single Centre
cg.iitasubjectCassava
cg.iitasubjectFood Security
cg.iitasubjectNutrition
cg.iitasubjectPost-Harvesting Technology
cg.iitasubjectValue Chains
cg.journalFrontiers in Chemistry
cg.notesOpen Access Journal; Published online: 10 May 2023
cg.accessibilitystatusOpen Access
cg.reviewstatusPeer Review
cg.usagerightslicenseCreative Commons Attribution 4.0 (CC BY 0.0)
cg.targetaudienceScientists
cg.identifier.doihttps://doi.org/10.3389/fchem.2023.1156718
cg.iitaauthor.identifierMichael Adesokan: 0000-0002-1361-6408
cg.iitaauthor.identifierAlamu Emmanuel Oladeji: 0000-0001-6263-1359
cg.iitaauthor.identifierBusie Maziya-Dixon: 0000-0003-2014-2201
cg.futureupdate.requiredNo
cg.identifier.issue1156718
cg.identifier.volume11


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