Abstract
The complexity and high sensitivity of proteins to environmental factors give rise to a multitude of variables, which affect the stabilization mechanisms in protein foams. Interfacial and foaming properties of proteins have been widely studied, but the reported unique effect of pH, which can be of great interest to applications, has been investigated to a lesser extent. In this paper, we focus on the impact of pH on the stability of black foam films and corresponding foams obtained from solutions of a model globular protein—the whey β-lactoglobulin (BLG). Foam stability was analyzed utilizing three characteristic parameters (deviation time, transition time and half-lifetime) for monitoring the foam decay, while foam film stability was measured in terms of the critical disjoining pressure of film rupture. We attempt to explain correlations between the macroscopic properties of a foam system and those of its major building blocks (foam films and interfaces), and thus, to identify structure-property relationships in foam. Good correlations were found between the stabilities of black foam films and foams, while relations to the properties of adsorption layers appeared to be intricate. That is because pH-dependent interfacial properties of proteins usually exhibit an extremum around the isoelectric point (pI), but the stability of BLG foam films increases with increasing pH (3–7), which is well reflected in the foam stability. We discuss the possible reasons behind these intriguingly different behaviors on the basis of pH-induced changes in the molecular properties of BLG, which seem to be determining the mechanism of film rupture at the critical disjoining pressure.
Highlights
Foams are dispersed systems of gas in a liquid matrix
Foam films of the Newton black films (NBF) type are readily obtainable at pH 5 and at low disjoining pressures, while at pH values away from pI, common black films’ (CBF) are obtained
Good correlations between the foam film and foam stabilities were found in the present study, and we discuss these in more detail in the following
Summary
Foams are dispersed systems of gas in a liquid matrix. Foams are found in nature and are widely used in various technologies; they are of continuous interest to science sinceMinerals 2020, 10, 636; doi:10.3390/min10070636 www.mdpi.com/journal/mineralsMinerals 2020, 10, 636 the works of Plateau in the 19th century [1,2]. Foams are dispersed systems of gas in a liquid matrix. Foams are found in nature and are widely used in various technologies; they are of continuous interest to science since. A general theory to describe foam behavior is still lacking. This is because the formation of foam and its further existence involves a multitude of phenomena at different length scales, among which interfacial phenomena play crucial roles [1,2,3,4,5,6,7,8,9,10,11,12,13,14]. Once the foam is being created, its evolution towards decaying properties is determined by different destabilizing mechanisms (syneresis, coarsening, coalescence [4,5,6,7]), but the foam can reach a quasi-static state under hydrostatic equilibrium (dry foam)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
