Development of iron-rich whey protein hydrogels following application of ohmic heating – Effects of moderate electric fields

The influence that ohmic heating technology and its associated moderate electric fields (MEF) have upon production of whey protein isolate cold-set gels mediated by iron addition was investigated. Results have shown that combining heating treatments (90°C, 5min) with different MEF intensities let hydrogels with distinctive micro and macro properties – i.e. particle size distribution, physical stability, rheological behavior and microstructure. Resulting hydrogels were characterized (at nano-scale) by an intensity-weighted mean particle diameter of 145nm, a volume mean of 240nm. Optimal conditions for production of stable whey protein gels were attained when ohmic heating treatment at a MEF of 3V∙cm−1 was combined with a cold gelation step using 33mmol∙L−1 of Fe2+. The consistency index of hydrogels correlated negatively to MEF intensity, but a shear thickening behavior was observed when MEF intensity was increased up to 10V∙cm−1. According to transmission electron microscopy, ohmic heating gave rise to a more homogenous and compact fine-stranded whey protein-iron microstructure. Ohmic heating appears to be a promising technique, suitable to tailor properties of whey protein gels and with potential for development of innovative functional foods. [Display omitted] •A new method for the production iron-rich whey protein hydrogels is proposed.•Ohmic heating and iron cold-gelation were combined to produce protein hydrogels•Incorporation of significant amounts of iron within protein network were allowed•Electrical heating influenced properties iron-rich whey protein hydrogels