Stuffed brushes: theory and experiment

The interaction between polymer brushes and mesoscopic particles is investi gated both theoretically and experimentally. We present an analytical mean- field theory for a polymer brush (a layer of long polymer chains end-grafte d to a substrate) with varying excluded volume interactions between monomer units. This system mimics the reversible adsorption of mesoscopic particle s, such as surfactant micelles or proteins, on the grafted chains. The equi librium structural properties of the brush (the brush thickness and overall degree of complexation) as well as the number of adsorbed particles per un it area, Gamma, are analysed as functions of the affinity between particle and chain, grafting density sigma and excluded volume interactions. In our model Gamma is found to have a maximum as a function of sigma. Experimental ly the adsorption of BSA on a hydrophobic substrate with grafted PEO chains is measured with reflectometry. In the case of short grafted chains the ad sorbed amount of BSA, Gamma, decreases continuously with increasing sigma w hich agrees with previous results and model calculations in the literature. In the case of long PEO chains, however, Gamma is found to have a maximum as a function of sigma: Qualitatively the experimental dependence of Gamma on sigma is found to agree with the results of our mean-held model. PEO cha ins show no affinity for BSA in the bulk, whereas in a grafted conformation an effective attraction is found. Some comments are made on the nature of this affinity, which is not yet fully understood.