Rheology and bread‐making performance of gluten‐free formulations affected by different levels of sugar beet fibre, hydroxypropylmethylcellulose and water

Summary This study investigated the application of hydroxypropylmethylcellulose (HPMC) (2%, 3%, 4%), sugar beet fibre (SBF) (3%, 5%, 7%) and water (210%, 220%, 230%) into maize‐based gluten‐free (GF) formulations and their effects on the GF batter rheology and bread quality. HPMC incorporation in hi...

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Veröffentlicht in:International journal of food science & technology 2018-08, Vol.53 (8), p.1832-1837
Hauptverfasser: Djordjević, Marijana, Šoronja‐Simović, Dragana, Nikolić, Ivana, Dokić, Ljubica, Djordjević, Miljana, Šereš, Zita, Šaranović, Žana
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Sprache:eng
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Zusammenfassung:Summary This study investigated the application of hydroxypropylmethylcellulose (HPMC) (2%, 3%, 4%), sugar beet fibre (SBF) (3%, 5%, 7%) and water (210%, 220%, 230%) into maize‐based gluten‐free (GF) formulations and their effects on the GF batter rheology and bread quality. HPMC incorporation in higher amounts reduced the compliance values of GF batter samples and increased the values of dynamic moduli indicating an improvement in the GF batter elastic characteristic. The same course of action with a less pronounced influence on mentioned rheological parameters had SBF addition. GF bread quality evaluation in terms of specific loaf volume and crumb texture (hardness, cohesiveness and springiness) reveals that HPMC and SBF incorporation at higher levels enhanced these quality parameters. The inclusion of HPMC and SBF coupled with adequate water content can improve the nutritional value of GF bread without negative influence on bread quality. Sugar beet fibre and hydroxypropylmethylcellulose inclusion in gluten free bread improves batter workability and bread quality. These positive changes occur mainly through the compensation of the structure loss associated with lack of gluten.
ISSN:0950-5423
1365-2621
DOI:10.1111/ijfs.13797