Rheology, microstructure and phase behavior of potato starch-protein fibril mixed gel

•Whey protein fibrils added to potato starch gels at neutral and acid pH.•Fibrils increase gel storage modulus in acid conditions.•Fibrils shorten and aggregate more during heating at neutral pH.•Phase separation of fibrils and starch dominates at neutral pH.•Composition and charge indicate fibril-s...

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Bibliographic Details
Published in:Carbohydrate polymers 2020-07, Vol.239, p.116247-116247, Article 116247
Main Authors: Chen, Da, Fang, Fang, Federici, Enrico, Campanella, Osvaldo, Jones, Owen Griffith
Format: Article
Language:English
Subjects:
Atomic force microscopy
Calorimetry
Fibrils
Gels - chemistry
Hydrogen-Ion Concentration
Interactions
Particle Size
Rheology
Solanum tuberosum - chemistry
Starch - chemistry
Starch gel
Surface Properties
Temperature
Whey protein
Whey Proteins - chemistry
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Summary:•Whey protein fibrils added to potato starch gels at neutral and acid pH.•Fibrils increase gel storage modulus in acid conditions.•Fibrils shorten and aggregate more during heating at neutral pH.•Phase separation of fibrils and starch dominates at neutral pH.•Composition and charge indicate fibril-starch association in acid condition. Effects of adding whey protein fibrils to gels of potato starch with 8 % solids content were determined by rheology, microscopy, and calorimetry. Adding fibrils to starch at 50 % content (w/w) increased starch gelatinization temperature by 1.5 °C but decreased associated enthalpy. Fibril addition consistently reduced gel viscosity. Storage modulus (G’) of gels increased with fibril content when prepared at pH3.5 but not at pH6.8. Fibrils were dispersed within imaged gels at pH3.5 for contents below 50 %, while separated phases were observed within pH3.5 gels for 50 % fibril content and within pH6.8 gels for all fibril contents. Dilution of gels led to sedimentation of predominantly starch, and both starch and protein content of sediment increased with overall fibril content. Results indicated that associative interactions between fibrils and starch contributed to synergistic increases in gel elasticity at low pH but not at neutral pH conditions under which starch and protein were poorly compatible.
ISSN:0144-8617
1879-1344
DOI:10.1016/j.carbpol.2020.116247