4.7 Article

Gelation of cowpea proteins induced by high hydrostatic pressure

Journal

FOOD HYDROCOLLOIDS
Volume 111, Issue -, Pages -

Publisher

ELSEVIER SCI LTD
DOI: 10.1016/j.foodhyd.2020.106191

Keywords

Cowpea protein isolate; High hydrostatic pressure; Gelation; Plant proteins; Protein structure during pressurization

Funding

  1. BEC

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The study found that both high hydrostatic pressure (HHP) and heat-induced gelation of cowpea protein can lead to gels with high water holding capacity (WHC), but there are significant differences in the physical properties and structures between them. HHP treatment causes partial protein dissociation and exposure to water, leading to fewer interactions and softer gels. In contrast, heat-induced gelation results in more strong interactions, resulting in firmer gels.
The gelation of isolated cowpea protein induced by high hydrostatic pressure (HHP, 400 or 600 MPa) was studied in terms of rheological behavior, texture, color, water holding capacity (WHC), scanning electron microscopy and exploration of the interactions that stabilized the gel matrices. Heat-induced gelation was also studied and compared with HHP-induced one. Moreover, absorption and fluorescence spectroscopy under HHP was carried out in order to assess the effect of HHP on cowpea protein structure during treatment and to hypothesize on the gelation mechanism. Both HHP- and heat-induced cowpea gels exhibited an outstandingly high WHC. The rheological behavior of HHP-treated dispersions was compatible with entangled solutions at the lowest protein concentrations (PC, 7.5-10.5% w/w) and with gels at the highest ones (12.0-13.5% w/w). Heating (70 or 90 degrees C) induced gelation at lower PC. HHP-induced gels were less hard and adhesive than heat-induced ones. At low PC (0.05% w/v), HHP provoked dissociation and exposition of aromatic amino acid residues to water, which was partially reversed during depressurization. These dissociated, unfolded and more hydrophobic polypeptides would establish mainly non-covalent interactions such as hydrophobic and hydrogen bonds, a part of these interactions would occur during depressurization. Heat-induced gels had a higher proportion of strong linkages than HHP-induced ones, which explained the rheological and textural differences. The principle of microscopic order probably prevents rearrangement of reactive sites, leading to HHP-induced gels having fewer interactions than heat-induced ones. HHP-treated CPI could give specific texture characteristics and allow incorporation of thermolabile compounds to food matrices.

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