An in Situ Infrared Spectroscopic Investigation of Lysine Peptide and Polylysine Adsorption to TiO₂ from Aqueous Solutions

Abstract

An in situ infrared spectroscopic study of the adsorption of lysine peptides with n = 2–5 lysine units and polylysine (n = 169) on hydrous TiO₂ particle films is reported. Using attenuated total reflection infrared spectroscopy, it was found that dilysine adsorption to negatively charged TiO₂ from aqueous solutions pH 7.4 arose from electrostatic interactions. Increasing the number of lysine units to n = 3–5 resulted in infrared spectra which were changed, compared to solution species, upon adsorption to TiO₂. This indicated that the carboxylate group was involved in the peptide/TiO₂ interaction. Binding constants (K) for lysine peptide adsorption to TiO₂ were calculated by applying the Langmuir isotherm model. The K values obtained supported the onset of a stronger peptide–TiO₂ interaction going from dilysine to trilysine. Polylysine also adsorbed to TiO₂ from aqueous pH 7.4 solutions. Prolonged exposure of polylysine to TiO₂ (16.5 h) resulted in changed infrared spectra, implying that the secondary structure of polylysine was affected by adsorption. In contrast, the lysine peptides and polylysine did not adsorb to the hydrophobic ZnSe surface or positively charged chromium(III) oxide–hydroxide films, under the same experimental conditions. This indicates that electrostatic interactions of the lysine peptides with the adsorbent are of main importance to adsorption.