Journal Articles

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    Emulsifying properties of hemp and whey protein complexes achieved by microparticulation
    (Elsevier Ltd, 2026-03-01) Ma S; Ye A; Singh H; Acevedo-Fani A
    Hemp is a sustainable source of protein. However, the utilisation of commercial hemp protein (HP) is limited due to its poor functionality. This study provided a microparticulation method to produce hybrid microparticles by complexing HP and whey protein isolate (WPI), and investigated their emulsifying potential. The emulsions, composed of 10 % oil and 0.25–1.8 % protein (non-microparticulated or microparticulated HP/WPI), were produced and the impact of microparticulation on the emulsifying ability of HP/WPI was explored using static light scattering, CLSM, TEM and SDS electrophoresis analysis. The results showed that non-microparticulated HP/WPI stabilised emulsions exhibited preferential whey protein adsorption at the oil-water interface, leading to sufficient protein coverage at most protein concentrations (0.25–1.8 %) with relatively small droplet size (∼0.5 μm) and minimal flocculation. In contrast, in the 'emulsifier-poor' regime (0.25–1 %), microparticulated HP/WPI stabilised emulsions displayed larger droplet size with clear signs of bridging flocculation. However, when the protein concentration was sufficient (≥1.5 % protein), it reached a similar droplet size as that of non-microparticulated HP/WPI emulsion with minimal flocculation. Microparticulation increased HP loading at the interface, while emulsions stabilised by non-microparticulated HP/WPI showed less HP adsorption. Transmission electron microscopy further confirmed the microparticle coverage. Moreover, the heat stability of microparticulated HP/WPI stabilised emulsions increased, compared with non-microparticulated HP/WPI. These findings highlight the potential of microparticulated HP/WPI systems in the application of emulsification and enhance HP applications in the food industry.
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    Heat-induced interactions of hemp protein particles formed by microfluidisation with β-lactoglobulin
    (Elsevier Ltd, 2024-07-01) Ma S; Acevedo-Fani A; Ye A; Singh H
    This study explored the effect of microfluidization on the dispersibility of hempseed protein (HP) and the interactions of microfluidised HP particles with β-lactoglobulin (β-lg) after heat treatment. Microfluidization increased the dispersible protein fraction from 10% (non-microfluidised) to a maximum of 58% (200 MPa, 6 passes) in HP dispersions. Dispersible HP particles were within the micro-sized range (d4,3 ≤ 2 μm) after microfluidization. Heat treatment (95 °C, 10–60 min) of HP particles with β-lactoglobulin (β-lg) induced protein association by sulphydryl-disulphide exchange reactions; β-lg association with HP particles initiated within the first 20 min. Additionally, the particle size (d4,3) values of co-heated HP particles with β-lg were significantly smaller than those found in HP particle dispersions heated alone, results that were in line with microscopy analysis. This suggests that β-lg could have restricted HP particle aggregation. In conclusion, combining microfluidization and heat treatment could offer a venue to modify the physical properties of plant/milk protein mixtures.