Fermented Wheat Bran as a Functional Ingredient in Baking

Katina, Kati; Juvonen, Riikka; Laitila, Arja; Flander, Laura; Nordlund, Emilia; Kariluoto, Susanna; Piironen, Vieno; Poutanen, Kaisa

doi:10.1094/cchem-08-11-0106

Cited by 141 publications

(101 citation statements)

References 48 publications

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“…Fermentation of wholegrain flour or bran in optimized conditions can also improve the volume, texture and shelf-life of wholegrain or fibre-enriched breads (Katina, Heiniö, Autio, & Poutanen, 2006, Katina et al, 2012, Coda et al, 2014a, 2014b. This has been assumed to be due to partial degradation of bran cell walls and solubilization of arabinoxylan, causing improved rheological properties of wheat doughs enriched with wheat bran (Hartikainen, Poutanen, & Katina, 2014).…”

Section: Bioprocessingmentioning

confidence: 99%

“…Inferior texture formation properties of wholegrain flour can be compensated by adding standard baking aids such as gluten, emulsifiers, enzymes and by optimisation of the baking process (Flander et al 2012). A widely used way to reduce the negative effects of bran is by compensations made in the bread formula by addition of vital gluten, or the use of surfactants (Shogren, Pomeranz, & Finney, 1981).…”

Section: Use Of Ingredients To Mask Bitterness Of Wholegrainmentioning

confidence: 99%

See 1 more Smart Citation

Sensory characteristics of wholegrain and bran-rich cereal foods – A review

Heiniö

Noort

Katina

et al. 2016

Trends in Food Science & Technology

217

153

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Wholegrain foods are known to be health-beneficial but their sensory characteristics may be a limiting factor for consumption. Many cereals like rye, oats, barley and sorghum are actually used mainly as wholegrain, whereas for wheat the situation is the opposite. This review deals with factors that differentiate the sensory properties of wholegrain and bran-rich foods from those of refined cereal foods. Hitherto established means of modulating sensory quality and thus improving acceptability of wholegrain foods are also presented. Key words Highlights Most sensory attributes of wholegrain foods are formed during processing  Phenolics, peptides, Maillard reaction products and lipids are the major compounds determining the specific flavour of wholegrain foods  Bran particle size, surface interactions and water binding are key factors in affecting texture formation  Milling, fractionation, bioprocessing and choice of raw materials are among the tools to improve the sensory characteristics of wholegrain foods

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Section: Bioprocessingmentioning

confidence: 99%

Section: Use Of Ingredients To Mask Bitterness Of Wholegrainmentioning

confidence: 99%

Sensory characteristics of wholegrain and bran-rich cereal foods – A review

Heiniö

Noort

Katina

et al. 2016

Trends in Food Science & Technology

217

153

View full text Add to dashboard Cite

show abstract

“…However, researchers have studied and reported the nutritional importance of fermented cereal bran and sourdough fermentation, and their potentials in improving the quality of bran substituted baked foods (Salmenkallio-Marttila et al, 2001;Poutanen et al, 2009;Katina et al, 2012). Lactic acid bacteria (LAB) and yeasts have been successfully used for bran fermentation (Coda et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Influence of starter culture on the physicochemical properties of rice bran sourdough and physical quality of sourdough bread

Hanis-Syazwani¹,

Bolarinwa²,

Lasekan³

et al. 2018

Food Res.

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The effect of mixed strain culture of lactic acid bacteria (LAB) and Yeast, and yeast or L. brevis, L. plantarum, or L. sanfranciscencis on the physicochemical properties (pH, TTA, organic acid, ethanol, and sugar content) of rice bran sourdough was investigated. Starter culture with optimum physicochemical properties was used to ferment rice and wheat bran for sourdough production. Rice and wheat bran sourdough and non-fermented rice and wheat bran were mixed with wheat flour at 10% substitution level for bread production. Results showed that rice bran fermented with L. plantarum had the best physicochemical properties compared to rice bran sourdough produced by other LAB or mixed culture. The specific volume of bread sample made with rice bran sourdough (4.65 cm 3 /g) was higher than that of the bread samples made from wheat bran sourdough (4.32 cm 3 /g) and nonfermented bran (3.74 -4.24 cm 3 /g), but not significantly different from the control (100% wheat) bread (4.85 cm 3 /g). The crumb colour of the rice bran and rice bran sourdough substituted bread was lighter than that of the other bread samples. Crust colour of all the bread samples was not significantly different (p > 0.05). At the end of 6 days storage period, bread samples from control and wheat bran sourdough were firmer than that from rice bran sourdough, however, crumb firmness values were highest in non-fermented bran substituted bread. Sensory analysis result revealed that rice bran sourdough bread was more acceptable than wheat bran sourdough bread, and non-fermented rice and wheat bran substituted bread.

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“…Improvement of structural and technological properties of bread [29 ] Yeast fermentation and xylanases Improvement of physical and chemical properties of dough and bread texture [30 ] Yeast fermentation followed by cell-wall hydrolysing enzymes Increase of soluble fiber content, increase of soluble protein content and in vitro digestibility, release of short chain fatty acids [23] Sourdough fermentation Improvement of technological and nutritional properties, overall flavor and sensory aspect; decrease of the starch digestibility and low glycemic response [27] Lactobacillus sanfranciscensis and Lactobacillus plantarum fermentation Increase of free amino acids, total phenols, dietary fiber, phytase and antioxidant activities. Improvement of nutritional, textural and sensory properties of breads and decreased the value of hydrolysis index (HI) hydrolyze internal b-1,4 bonds in the main-chain, generating soluble xylooligosaccharides which are suitable substrates for b-xylosidases and leading to the formation of AX oligosaccharides.…”

Section: Bran Bioprocessing Effects Referencesmentioning

confidence: 99%