RESUMEN
Various physicochemical parameters of poly-l-lysine (PLL) solutions comprising the diffusion coefficient, the electrophoretic mobility, the density, and the intrinsic viscosity were determined for the pH range 3.0-9.2. This allowed us to calculate derivative parameters characterizing the PLL molecule such as: zeta potential, the number of electrokinetic charges, ionization degree, contour length, and cross section area. These data were exploited in theoretical calculations of PLL adsorption kinetics on solid substrates under diffusion transport. A hybrid approach was used comprising a blocking function derived from the random sequential adsorption (RSA) model. In experiments, the PLL adsorption on mica was studied using the streaming potential measurements and interpreted in terms of a general electrokinetic model. This confirmed a side-on adsorption mechanism of the macroion molecules at the examined pH range. Additionally, using this method, the stability of PLL monolayers was determined performing in situ desorption kinetic experiments. In this way, the equilibrium adsorption constant and the energy minimum depth were determined. It was confirmed that the monolayer stability decreases with pH following the decrease in the number of electrokinetic charges per molecule. This confirmed the electrostatic interaction driven adsorption mechanism of PLL. It is also predicted that at pH 5.7-7.4 the monolayers were stable under diffusion-controlled desorption over the time exceeding 100 h. In addition to their significance for basic science, the results obtained in this work can be exploited for developing procedures for preparing stable PLL monolayers of well controlled coverage and electrokinetic properties.
RESUMEN
Adsorption of human serum albumin (HSA), recombinant HSA (rHSA) and the albumin dimer (dHSA) at solid/electrolyte interfaces is reviewed with the emphasis put on quantitative analysis of this process. Initially, various physicochemical data characterizing bulk properties of albumin molecules are discussed such as electrophoretic mobility, electrokinetic charge, zeta potential and diffusion coefficient. Adsorption kinetics of HSA, rHSA and dHSA at mica derived from AFM, streaming potential and XPS measurements is analyzed. Maximum coverages of irreversibly adsorbed molecules under various ionic strengths and pHs are quantitatively interpreted in terms of the random sequential adsorption model. Thorough acid-basic characteristic of albumin monolayers of well-controlled coverage are also presented. The results derived from the colloid deposition method that unveil albumin molecule orientation and charge distribution are discussed and interpreted in terms of the random site theory. Subsequently, adsorption of albumins at negatively and positively charged polymeric microparticles studied by the electrokinetic and the AFM aided concentration depletion methods is analyzed. These results are theoretically interpreted by applying the bead model of HSA and dHSA molecules. Orientation of adsorbed molecules and the stability of albumin monolayers in respect to pH cyclic changes are discussed. A universal, electrostatic interaction driven, mechanism of albumin adsorption at macroscopic surfaces and polymer microparticles is confirmed.