Preparation of High Bran Arabic Bread with Low Phytic Acid Content

Phytic acid has been considered to be an antinutrient due to its ability to bind minerals and proteins, either directly or indirectly, thus changing their solubility, functionality, absorption, and digestibility. In this study, the influence of the flour type (type 500, type 850, and whole meal flour) and three different breadmaking procedures (direct, indirect, and with sourdough addition) on phytic acid was investigated. The results showed that the flour type influenced the phytic acid content. The phytic acid contents of flour type 500, type 850, and whole meal flour was 0.4380, 0.5756, and 0.9460 g/100 g dm, respectively. The dough and bread prepared from flour with a higher phytic acid content also contained higher amount of phytic acid. During fermentation and baking, degradation of phytic acid occurred. Phytic acid was also influenced by pH. Samples of lower pH had a lower phytic acid content. Dough prepared from flour type 500 and type 850 with 10% addition of sourdough had especially low phytic acid contents, and the bread prepared from the respective dough contained no phytic acid at all.

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Iron, Zinc and Phytic Acid Retention of Biofortified, Low Phytic Acid, and Conventional Bean Varieties When Preparing Common Household Recipes

Nutrients ◽

10.3390/nu12030658 ◽

2020 ◽

Vol 12 (3) ◽

pp. 658 ◽

Cited By ~ 4

Author(s):

Marijke Hummel ◽

Elise F. Talsma ◽

Victor Taleon ◽

Luis Londoño ◽

Galina Brychkova ◽

...

Keyword(s):

Phytic Acid ◽

Acid Content ◽

Mineral Content ◽

The Other ◽

Nutritional Intake ◽

Nutritional Content ◽

Mineral Absorption ◽

Phytic Acid Content ◽

Low Phytic Acid ◽

Nutritional Benefits

Biofortification is an effective method to improve the nutritional content of crops and nutritional intake. Breeding for higher micronutrient mineral content in beans is correlated with an increase in phytic acid, a main inhibitor of mineral absorption in humans. Low phytic acid (lpa) beans have a 90% lower phytic acid content compared to conventional beans. This is the first study to investigate mineral and total phytic acid retention after preparing common household recipes from conventional, biofortified and lpa beans. Mineral retention was determined for two conventional, three biofortified and two lpa bean genotypes. Treatments included soaking, boiling (boiled beans) and refrying (bean paste). The average true retention of iron after boiling was 77.2–91.3%; for zinc 41.2–84.0%; and for phytic acid 49.9–85.9%. Soaking led to a significant decrease in zinc and total phytic acid after boiling and refrying, whereas for iron no significant differences were found. lpa beans did not exhibit a consistent pattern of difference in iron and phytic acid retention compared to the other groups of beans. However, lpa beans had a significantly lower retention of zinc compared to conventional and biofortified varieties (p < 0.05). More research is needed to understand the underlying factors responsible for the differences in retention between the groups of beans, especially the low retention of zinc. Combining the lpa and biofortification traits could further improve the nutritional benefits of biofortified beans, by decreasing the phytic acid:iron and zinc ratio in beans.

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Effect of combined germination, dehulling and boiling on mineral, sucrose, stachyose, fibrulose, and phytic acid content of different chickpea cultivars.

African Journal of Food, Agriculture, Nutrition and Development ◽

10.18697/ajfand.55.10610 ◽

2012 ◽

Vol 12 (55) ◽

pp. 6853-6867

Author(s):

LN Malunga LN ◽

◽

S Barel-Dadon ◽

Z Berkovich ◽

S Abbo ◽

...

Keyword(s):

Phytic Acid ◽

Acid Content ◽

Seed Weight ◽

Child Nutrition ◽

Antinutritional Factors ◽

Nutrient Loss ◽

Mineral Density ◽

Phytic Acid Content ◽

Low Phytic Acid ◽

Traditional Technologies

Chickpea is a good source of high quality protein, carbohydrates, vitamins (thiamine and niacin), and minerals. However, its use in industry has been limited by variation in composition with cultivar and also the presence of oligosaccharides, trypsin inhibitors, phytic acids, tannin, and haemagglutinin. Different technologies have been studied to eliminate or minimise the undesirable factors in chickpeas. None of the studied traditional technologies has been found to effectively eliminate or minimise all the undesirable factors in chickpeas. It is not clear whether a combination of these traditional technologies, more especially cooking of germinated and dehulled chickpeas, will significantly reduce all the antinutritional factors . The physical characteristics, stachyose, sucrose, phytic acid, fibrulose, and mineral content of different chickpeas cultivar were determined and compared with reference to infant and child nutrition. The selected cultivars were (1) dehulled and boiled before drying; (2) dehulled followed by soaking and boiling before drying; (3) boiled without dehulling before drying; and germinated, boiled followed by drying and dehulling . The effects of the processing on mineral, sugar, dietary fibre content were evaluated. Desi were found to have lower seed weight, hydration capacity and swelling capacity compared to kabuli . Seed density, hydration index and swelling index did not vary with cultivar. The mineral density, stachyose, fibrulose, and hull content increased significantly (p<0.05) with the decrease of seed weight whereas phytic acid content did not vary. All processes resulted in an increase in calcium, phosphorous, zinc, and phytic acid and a decrease in potassium, iron, magnesium, sucrose, stachyose and fibrulose content regardless of cultivar type. Germination for 72 hrs followed by boiling, drying and dehulling resulted in highest reduction in antinutritional factors with minimal nutrient loss. It is feasible to use chickpeas as an excellent source of infant follow -on formula/weaning food with minimal mineral fortification and use of low phytic acid cultivars.

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Impact of mips1, lpa1 , and lpa2 Alleles for Low Phytic Acid Content on Agronomic, Seed Quality, and Seed Composition Traits of Soybean

Crop Science ◽

10.2135/cropsci2016.12.1028 ◽

2017 ◽

Vol 57 (5) ◽

pp. 2490-2499 ◽

Cited By ~ 7

Author(s):

Benjamin Averitt ◽

Chao Shang ◽

Luciana Rosso ◽

Jun Qin ◽

Mengchen Zhang ◽

...

Keyword(s):

Phytic Acid ◽

Acid Content ◽

Seed Quality ◽

Seed Composition ◽

Phytic Acid Content ◽

Low Phytic Acid

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Probing Phosphorus Efficient Low Phytic Acid Content Soybean Genotypes with Phosphorus Starvation in Hydroponics Growth System

Applied Biochemistry and Biotechnology ◽

10.1007/s12010-015-1773-1 ◽

2015 ◽

Vol 177 (3) ◽

pp. 689-699 ◽

Cited By ~ 6

Author(s):

Varun Kumar ◽

Tiratha Raj Singh ◽

Alkesh Hada ◽

Monica Jolly ◽

Andy Ganapathi ◽

...

Keyword(s):

Phytic Acid ◽

Acid Content ◽

Phosphorus Starvation ◽

Phytic Acid Content ◽

Low Phytic Acid ◽

Soybean Genotypes ◽

Growth System

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Production of soy protein isolates with low phytic acid content by membrane technologies: Impact of the extraction and ultrafiltration/diafiltration conditions

Journal of Food Engineering ◽

10.1016/j.jfoodeng.2012.08.012 ◽

2013 ◽

Vol 114 (2) ◽

pp. 221-227 ◽

Cited By ~ 6

Author(s):

Yung Priscilla Lai ◽

Martin Mondor ◽

Christine Moresoli ◽

Hélène Drolet ◽

Michel Gros-Louis ◽

...

Keyword(s):

Phytic Acid ◽

Soy Protein ◽

Acid Content ◽

Phytic Acid Content ◽

Protein Isolates ◽

Low Phytic Acid ◽

Soy Protein Isolates ◽

Membrane Technologies

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Genetic Analysis and Molecular Mapping of the Quantitative Trait Loci Governing Low Phytic Acid Content in a Novel LPA Rice Mutant, PLM11

Plants ◽

10.3390/plants9121728 ◽

2020 ◽

Vol 9 (12) ◽

pp. 1728

Author(s):

Prem Chand Gyani ◽

Haritha Bollinedi ◽

Subbaiyan Gopala Krishnan ◽

Kunnummal Kurungara Vinod ◽

Archana Sachdeva ◽

...

Keyword(s):

Phytic Acid ◽

Acid Content ◽

Molecular Mapping ◽

Physical Map ◽

Rice Variety ◽

In Silico Analysis ◽

Chromosome 8 ◽

Rice Varieties ◽

Phytic Acid Content ◽

Low Phytic Acid

Breeding rice varieties with a low phytic acid (LPA) content is an effective strategy to overcome micronutrient deficiency in a population which consume rice as a staple food. An LPA mutant, Pusa LPA Mutant 11 (PLM11), was identified from an ethyl methane sulfonate (EMS)-induced population of Nagina 22. The present study was carried out to map the loci governing the LPA trait in PLM11 using an F2:3 population derived from a cross between a high phytic acid rice variety, Pusa Basmati 6, with PLM11. The genotyping of the F2 population with 78 polymorphic SSR markers followed by the estimation of phytic acid content in the seeds harvested from 176 F2 plants helped in mapping a major QTL, qLPA8.1, explaining a 22.2% phenotypic variation on Chromosome 8. The QTL was delimited to a 1.96 cM region flanked by the markers RM25 and RM22832. Since there are no previous reports of a QTL/gene governing the LPA content in rice in this region, the QTL qLPA8.1 is a novel QTL. In silico analysis based on the annotated physical map of rice suggested the possible involvement of a locus, Os08g0274775, encoding for a protein similar to a phosphatidylinositol 3- and 4-kinase family member. This needs further validation and fine mapping. Since this QTL is currently specific to PLM11, the linked markers can be utilized for the development of rice varieties with reduced phytic acid (PA) content using PLM11 as the donor, thus enhancing the bioavailability of mineral micronutrients in humans.

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Effect of Fermentation Methods on Phytic acid Content in Wheat Flour Bread

Basrah Journal of Agricultural Sciences ◽

10.33762/bagrs.2014.112578 ◽

2014 ◽

Vol 27 (1) ◽

pp. 128-142

Author(s):

Ali A. Sahi ◽

Ali H. Abdul-Kareem ◽

Basim A. Jaber

Keyword(s):

Phytic Acid ◽

Wheat Flour ◽

Acid Content ◽

Phytic Acid Content

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