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Physicochemical and functional characterization of plant protein isolates and their influence on plant-based mozzarella cheese performance

Laura Hanley, Stacie Dobson, Jarvis Stobbs, Alejandro G. Marangoni

2025Food Hydrocolloids20 citationsDOIOpen Access PDF

Abstract

Consumer demand for plant-based cheese alternatives has highlighted major gaps in existing products, particularly regarding functionality and protein content. This study examined the properties of commercial plant protein isolates from pea (PP1, PP2, PP3), lentil (LP1), faba (FP1), and soy (SP1), which were then incorporated into cheese analogs (∼8.0% w/w) with coconut oil and waxy maize starch. Protein isolates were characterized through protein solubility, water-holding capacity, emulsion stability, and ζ-potential measurements. Protein secondary structures and particle size distributions were determined by Fourier-transform infrared (FTIR) spectroscopy and static light scattering, respectively. Viscoelastic properties, thermo-rheological behavior, and results from functionality experiments ( e.g. , TPA hardness, melt, oil loss) were compared to commercial dairy and plant-based mozzarella products. Differences in tan δ (G’/G”) at 95°C were relatively minor between protein isolate cheese analogs (0.48-0.68), as thermo-reversibility was predominantly influenced by the waxy starch component. Analogs made with PP3, FP1, and SP1 showed good melting behavior, with modified Schreiber test spreads of 108-114%. However, oil loss varied significantly between samples. Synchrotron-radiation X-ray microcomputed tomography (SR-μCT) revealed differences in oil droplet size distribution affecting oil loss and other functional properties, with LP1 and FP1 showing higher densities of small oil droplets correlating to reduced oil expulsion. PP3 analogs exhibited optimized performance, with PP3 proteins possessing the highest water-holding capacity (2.8 g/g), good emulsion stability, and the widest size distribution. Ball milling was also explored for modifying protein particle size distributions and evaluating the influence of structural changes on various protein properties and cheese analog performance. Analog functionality was found to be highly dependent on protein interactions, starch gelatinization, and oil body distribution. All plant-based cheese analogs were found to outperform commercial plant-based mozzarella, showing promise for the enhancement of functionality in dairy mozzarella mimetics using low-solubility protein isolates. • Insoluble proteins act passively to improve plant-based cheese functionality. • Physicochemical properties of plant proteins impact melt behavior and oil loss in cheese analogs. • Waxy starch networks maintain adequate structure while enabling thermo-reversibility. • Ball-milling alters protein structure, affecting starch and oil interactions.

Topics & Concepts

Mozzarella cheeseFood scienceCharacterization (materials science)ChemistryCheesemakingMaterials scienceNanotechnologyProbiotics and Fermented FoodsProteins in Food SystemsFood composition and properties