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Grabowska, K J.; Tekidou, S; Boom, R M.; van der Goot, A-Jan
Food Research International 64: 743-751
2014
ISSN/ISBN: 0963-9969 DOI:10.1016/j.foodres.2014.08.010Accession:064569847
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Summary
The concept of shear-induced structuring was applied to concentrated blends of soy protein isolate (SPI) and wheat gluten (WG) to create novel semi-solid food textures. Concurrent simple shear deformation and heating (95°C) of the protein blends generated original structures consisting of fibers or layers. The ratio of SPI to vital WG and the final concentration determined the morphology of the structure. It is hypothesized that the spatial distribution of the SPI-rich phase and the WG-rich phase in a blend was altered by the shear flow. When both phases became aligned horizontally in the shear cell, a fibrous structure was formed; when they became aligned vertically in the shear cell, a layered structure was formed. The structures obtained were analyzed visually and using texture analysis and scanning electron microscopy.Related References
Grabowska, K.J.; Tekidou, S.; Boom, R.M.; van der Goot, A.-J. 2014: Shear structuring as a new method to make anisotropic structures from soy-gluten blends Food Research International 64: 743-751
Grabowska, K.J.; Zhu, S.; Dekkers, B.L.; de Ruijter, N.C. A.; Gieteling, J.; van der Goot, A.J. 2016: Shear-induced structuring as a tool to make anisotropic materials using soy protein concentrate Journal of Food Engineering 188: 77-86
Sulym, H.T.; Pasternak, I.M. 2010: Application of the boundary element method for analysis of the antiplane shear of anisotropic bodies containing thin-walled structures Journal of Mathematical Sciences 167(2): 162-172
Lyngaaejrgensen, J.; Utracki, L.A. 2003: Structuring polymer blends with bicontinuous phase morphology. Part II. Tailoring blends with ultralow critical volume fraction Polymer (Guildford) 44(5): 1661-1669
Mateus, JEL; Huesca, MAR; Lavielle, F.M.; Aguilar, E.G. 2023: Morphology of Anisotropic Banded Structures in an Emulsion under Simple Shear Fluids 8(9): 240
Jang, W.; Chang, S.; Han, J.W. 2024: Seismic Analysis Method Using the Multi-level Homogenization Method and the Sub-structuring Method for Structures with Multi-scale Repeated Patterns Transactions of the Korean Society of Mechanical Engineers a 48(2)
Takahashi, Y.; Noda, I. 1995: Domain Structures and Viscoelastic Properties of Immiscible Polymer Blends Under Shear Flow ACS Symposium Series: 140-152
Tahaei Yaghoubi, S.; Mousavi, S.M.; Paavola, J. 2016: Size effects on centrosymmetric anisotropic shear deformable beam structures ZAMM - Journal of Applied Mathematics and Mechanics / Zeitschrift für Angewandte Mathematik und Mechanik 97(5): 586-601
Baxter, S.C.; Horgan, C.O. 1997: Anti-plane shear deformations of anisotropic sandwich structures: End effects International Journal of Solids and Structures 34(1): 79-98
Ziegler, V.E.; Wolf, B.A. 2005: Morphology of PEO/PDMS blends during shear : Coexistence of two droplet/matrix structures and additive effects Polymer (Guildford) 46(25): 11396-11406
Ishigami, A.; Kodama, Y.; Wagatsuma, T.; Ito, H. 2017: Evaluation of Structures and Morphologies of Recycled PC/PET Blends Fabricated by High-Shear Kneading Processing International Polymer Processing 32(5): 568-573
W.A. Hussein 1972: Analysis of multi-bay shear wall structures by the shear connection method Building Science 7(1): 69-73
Van Landuyt, J.; De Ridder, R.; Gevers, R.; Amelinckx, S. 1970: Diffraction effects due to shear structures: a new method for determining the shear vector Materials Research Bulletin 5(5): 353-362
Gnitetskaya, T.N.; Ivanova, E.B. 2012: The Content Structuring of Chemistry with the Semantic Structures Method Advanced Materials Research 550-553: 3425-3428
Longere, P.; Dragon, A.; Trumel, H.; Deprince, X. 2006: Modelling and simulation of dynamic anisotropic degradation of structures under adiabatic shear banding J. Phys., Iv 134: 139-145
Takahashi, Y.; Imura, N.; Miyanishi, K.; Kitade, S.; Noda, I. 2003: Domain structures and rheological properties of immiscible polymer blends under shear flow in parallel plates Materials Science Research International 9(4): 278-281
Kitade, S.; Ichikawa, A.; Imura, N.; Takahashi, Y.; Noda, I. 1997: Rheological properties and domain structures of immiscible polymer blends under steady and oscillatory shear flows Journal of Rheology 41(5): 1039-1060
Osuji, C.O.; Weitz, D.A. 2008: Highly anisotropic vorticity aligned structures in a shear thickening attractive colloidal system Soft Matter 4(7): 1388-1392
Sano, H.; Matsuda, M.; Satou, H.; Nomura, T. 1999: Formation of morphological structures in polypropylene and ethylene-α-olefin rubber blends via shear-dependent mixing and demixing Kobunshi Ronbunshu (Tokyo) 56(10): 693-701
Zinno, R.; Barbero, E.J. 1994: A three-dimensional layer-wise constant shear element for general anisotropic shell-type structures International Journal for Numerical Methods in Engineering 37(14): 2445-2470
