Extrusion Processing of Rapeseed Press Cake-Starch Blends: Effect of Starch Type and Treatment Temperature on Protein, Fiber and Starch Solubility

Extrusion Processing of Rapeseed Press Cake-Starch Blends: Effect of Starch Type and Treatment Temperature on Protein, Fiber and Starch Solubility

For the valorization of oilseed press cakes into food products, extrusion can be used. A common way of applying the protein- and fiber-rich press cakes in directly expanded products is the combination thereof with starch, since starch gives a favourable texture, which correlates directly to expansio...

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Main Authors: Anna Martin, Susanne Naumann, Raffael Osen, Heike Petra Karbstein, M. Azad Emin
Format: Article
Language:English
Published: MDPI AG 2021-05-01
Series:Foods
Subjects:
canola
protein solubility
dietary fiber
starch gelatinization
extrusion
expansion
Online Access:https://www.mdpi.com/2304-8158/10/6/1160
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spelling doaj-7ef9190c5ff24dc89da9b91e63d6572b2021-06-01T00:43:40ZengMDPI AGFoods2304-81582021-05-01101160116010.3390/foods10061160Extrusion Processing of Rapeseed Press Cake-Starch Blends: Effect of Starch Type and Treatment Temperature on Protein, Fiber and Starch SolubilityAnna Martin0Susanne Naumann1Raffael Osen2Heike Petra Karbstein3M. Azad Emin4Department of Food Process Development, Fraunhofer Institute for Process Engineering and Packaging IVV, 85354 Freising, GermanyDepartment of Food Process Development, Fraunhofer Institute for Process Engineering and Packaging IVV, 85354 Freising, GermanySingapore Institute of Food and Biotechnology Innovation, Agency for Science, Technology and Research (A*STAR), Singapore 138669, SingaporeInstitute of Process Engineering in Life Sciences, Chair of Food Process Engineering, Karlsruhe Institute of Technology, 76131 Karlsruhe, GermanyInstitute of Process Engineering in Life Sciences, Chair of Food Process Engineering, Karlsruhe Institute of Technology, 76131 Karlsruhe, GermanyFor the valorization of oilseed press cakes into food products, extrusion can be used. A common way of applying the protein- and fiber-rich press cakes in directly expanded products is the combination thereof with starch, since starch gives a favourable texture, which correlates directly to expansion. To control product properties like expansion of protein and fiber-rich extruded products, the underlying physicochemical changes of proteins, fibers and starch due to thermomechanical input need to be comprehensively described. In this study, rapeseed press cake (RPC) was extruded and treated under defined thermomechanical conditions in a closed-cavity rheometer, pure and in combination with four starches. The impact of starch type (potato PS, waxy potato WPS, maize MS, high-amylose maize HAMS) and temperature (20/25, 80, 100, 120, 140 °C) on protein solubility, starch gelatinization (D<sub>gel</sub>), starch hydrolysis (S<sub>H</sub>) and fiber solubility of the blends was evaluated. The extrusion process conditions were significantly affected by the starch type. In the extruded blends, the starch type had a significant impact on the protein solubility which decreased with increasing barrel temperature. Increasing barrel temperatures significantly increased the amount of soluble fiber fractions in the blends. At defined thermomechanical conditions, the starch type showed no significant impact on the protein solubility of the blends. Therefore, the observed effects of starch type on the protein solubility of extruded blends could be attributed to the indistinct process conditions due to differences in the rheological properties of the starches rather than to molecular interactions of the starches with the rapeseed proteins in the blends.https://www.mdpi.com/2304-8158/10/6/1160canolaprotein solubilitydietary fiberstarch gelatinizationextrusionexpansion
collection DOAJ
language English
format Article
sources DOAJ
author Anna Martin
Susanne Naumann
Raffael Osen
Heike Petra Karbstein
M. Azad Emin
spellingShingle Anna Martin
Susanne Naumann
Raffael Osen
Heike Petra Karbstein
M. Azad Emin
Extrusion Processing of Rapeseed Press Cake-Starch Blends: Effect of Starch Type and Treatment Temperature on Protein, Fiber and Starch Solubility
Foods
canola
protein solubility
dietary fiber
starch gelatinization
extrusion
expansion
author_facet Anna Martin
Susanne Naumann
Raffael Osen
Heike Petra Karbstein
M. Azad Emin
author_sort Anna Martin
title Extrusion Processing of Rapeseed Press Cake-Starch Blends: Effect of Starch Type and Treatment Temperature on Protein, Fiber and Starch Solubility
title_short Extrusion Processing of Rapeseed Press Cake-Starch Blends: Effect of Starch Type and Treatment Temperature on Protein, Fiber and Starch Solubility
title_full Extrusion Processing of Rapeseed Press Cake-Starch Blends: Effect of Starch Type and Treatment Temperature on Protein, Fiber and Starch Solubility
title_fullStr Extrusion Processing of Rapeseed Press Cake-Starch Blends: Effect of Starch Type and Treatment Temperature on Protein, Fiber and Starch Solubility
title_full_unstemmed Extrusion Processing of Rapeseed Press Cake-Starch Blends: Effect of Starch Type and Treatment Temperature on Protein, Fiber and Starch Solubility
title_sort extrusion processing of rapeseed press cake-starch blends: effect of starch type and treatment temperature on protein, fiber and starch solubility
publisher MDPI AG
series Foods
issn 2304-8158
publishDate 2021-05-01
description For the valorization of oilseed press cakes into food products, extrusion can be used. A common way of applying the protein- and fiber-rich press cakes in directly expanded products is the combination thereof with starch, since starch gives a favourable texture, which correlates directly to expansion. To control product properties like expansion of protein and fiber-rich extruded products, the underlying physicochemical changes of proteins, fibers and starch due to thermomechanical input need to be comprehensively described. In this study, rapeseed press cake (RPC) was extruded and treated under defined thermomechanical conditions in a closed-cavity rheometer, pure and in combination with four starches. The impact of starch type (potato PS, waxy potato WPS, maize MS, high-amylose maize HAMS) and temperature (20/25, 80, 100, 120, 140 °C) on protein solubility, starch gelatinization (D<sub>gel</sub>), starch hydrolysis (S<sub>H</sub>) and fiber solubility of the blends was evaluated. The extrusion process conditions were significantly affected by the starch type. In the extruded blends, the starch type had a significant impact on the protein solubility which decreased with increasing barrel temperature. Increasing barrel temperatures significantly increased the amount of soluble fiber fractions in the blends. At defined thermomechanical conditions, the starch type showed no significant impact on the protein solubility of the blends. Therefore, the observed effects of starch type on the protein solubility of extruded blends could be attributed to the indistinct process conditions due to differences in the rheological properties of the starches rather than to molecular interactions of the starches with the rapeseed proteins in the blends.
topic canola
protein solubility
dietary fiber
starch gelatinization
extrusion
expansion
url https://www.mdpi.com/2304-8158/10/6/1160
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