Influence of traditional cooking methods on proximate composition, dietary fibre, keeping quality and consumer preference of biofortified fermented cassava fufu

Amadi, Joy Adaku; Njoku, Sylvarlene M.

doi:10.4314/jafs.v17i1.2

Cited by 3 publications

(2 citation statements)

References 15 publications

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“…The low protein content of fufu has been confirmed in the nutritional composition of cassava roots, where carbohydrates are the major nutrient, 80% of which is starch (Purseglove, 2009). However, the protein content in this study was lower than the results of (Etudaiye et al, 2012), which he ranged from 2.10% to 2.46% and similar to the results of (Amadi et al, 2019). The low protein content of fufu is not a serious problem, as fufu is usually consumed with a variety of protein sources, both animal and vegetable, from a variety of soups (Montagnac & Davis, 2009).…”

Section: Physiochemical Composition Of Freshly Prepared Fufu and Reta...supporting

confidence: 80%

Level of Microbial Contamination of Freshly Prepared Fufu and Retailed Fufu

Omorodion J.P.,

Beniye D

2023

JSRMBS

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Fufu is an acid-fermented products produced through submerged fermentation of cassava root in water for days. The study was set to determine the microbiological quality and the physiochemical composition of freshly prepared fufu (FF) and retailed fufu (RF). A standard microbiological method was used in enumerating and identify bacteria and fungi species isolated. The total heterotrophic bacteria count ranges from Log10 cfu/g 2.14 to 6.18 and 3.56 to 7.06 for retailed fufu and freshly prepared fufu respectively. Predominant bacteria found in the samples studied and their percentage of distribution were Lactobacillus 17(23%), Escherichia coli and Staphylococcus sp. 14(19%), Bacillus sp. 13(18%), Micrococcus sp. 5(7%), Enterobacter and Corynebacterium were 4(5%) and Proteus has the least 3(4%). Among the fungi were Mucor sp. and Candida sp. were 6(26.1%), Aspergillus niger 4(17.4%), Saccharomyces sp. 5(21.7%), and Rhizopus sp.2(8.7). The proximate analysis revealed an insignificant difference in crude protein ranging from 1.36% in FF to 1.24 in RF, carbohydrates content 82.88% to83.12% in RF and FF, ash content is higher in FF ranging 7.33% to 1.53% RF, while the moisture content is higher in RF with 9.47% and 1.78% in FF. Magnesium ranges from 38.4mg/ml in FF to 35.3mg/ml in RF .The results obtained showed that the fufu samples that were retailed were more contaminated than the freshly prepared fufu which might pose risk to health. Therefore, there is a need for proper sanitary conditions and best processing and production especially during packing is recommended.

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Section: Physiochemical Composition Of Freshly Prepared Fufu and Reta...supporting

confidence: 80%

Level of Microbial Contamination of Freshly Prepared Fufu and Retailed Fufu

Omorodion J.P.,

Beniye D

2023

JSRMBS

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“…Fufu , a fermented cassava mash, in wet or dry form, is a popular product from cassava consumed by most people in southeast Nigeria 3,4 . The unit operations for fufu production are root peeling, washing, cutting into pieces, steeping in water for 3–4 days to ret or soften (i.e., ferment), sieving of retted root pieces to remove fiber and, finally, extracting starch by pressing through a muslin cloth.…”

Section: Introductionmentioning

confidence: 99%

Cassava retting ability and textural attributes of fufu for demand‐driven cassava breeding

Chijioke,

Abah,

Achonwa

et al. 2024

J Sci Food Agric

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BackgroundCassava retting ability and the textural qualities of cooked fufu are important quality traits. Cassava retting is a complex process in which soaking causes tissue breakdown, starch release, and softening. The rate at which various traits linked to it evolve varies greatly during fufu processing. According to the literature, there is no standard approach for determining retting ability. The retting indices and textural properties of fufu were measured using both manual and instrumental approaches.ResultsDifferent protocols were developed to classify 64 and 11 cassava genotypes into various groups based on retting ability and textural qualities, respectively. The retting protocols revealed considerable genetic dissimilarities in genotype classification: foaming ability and water clarity should be measured at 24 h, while penetrometer, hardness, turbidity, pH, and total titratable acidity data are best collected after 36 h. The stepwise regression model revealed that pH, foaming ability, and dry matter content are the best multivariates (with the highest R2) for predicting cassava retting. These predictors were used to develop an index for assessing the retting ability of cassava genotypes. The retting index developed showed a significant relationship with dry matter content and fufu yield. The study also showed significant correlations between instrumental cohesiveness and sensory smoothness (r = −0.75), moldability (r = −0.62), and stretchability (r = 0.78). Instrumental cohesiveness can correctly estimate fufu smoothness (R2 = 0.56, P = 0.008) and stretchability (R2 = 0.60, P = 0.005).ConclusionsIn conclusion, pH, foaming ability, and dry matter content are the best traits for predicting cassava retting ability, while instrumental cohesiveness can effectively estimate fufu smoothness and stretchability.This article is protected by copyright. All rights reserved.

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