Use of polyamino acid analogs of biomineral proteins in dispersion of inorganic particulates important to water treatment

Abstract

Synthetic polyamino acids (peptides) based on the structure and activity of matrix proteins isolated from oyster shell and other biomineral structures have been identified for use in the prevention of mineral scaling. Matrix proteins are polyanionic and are thought to act as regulators of crystallization during the development of skeletal and other mineral structures. These proteins and their synthetic analogs also contain hydrophobic regions that may enhance their surface-active properties. The dispersion activity of a variety of polyamino acids that are matrix protein analogs has been evaluated in bench-top tests using inorganic mineral particles. Dispersion activities were measured using particles of iron oxide, kaolin, calcium carbonate, and calcium phosphate (hydroxyapatite). The activity was measured by increases in the spectrophotometric absorbance of test particle suspensions in the presence of dispersants. The increases in absorbance were due to turbidity resulting from the production of smaller particle sizes or slower rates of settling. The results suggest that biopolymers composed of polyanionic polyamino acids may be effective as dispersants. Polyamino acids containing a hydrophobic or phosphorylated domain attached to a polyaspartate backbone demonstrate enhanced activity over polyaspartate. These polyamino acids display comparable activity to commercially available hydrocarbon-based polymeric dispersants. An economical process for the manufacture of polyamino acids by thermal polycondensation is under development. Clearly, non-toxic and biodegradable polyamino acids present a desirable alternative to toxic non-biodegradable polymers in a number of applications such as detergents and cooling tower additives.