Reversible swelling of chitosan and quaternary ammonium modified chitosan brush layers: effects of pH and counter anion size and functionality

This study investigates the swelling of grafted polycationic brushes as a function of pH and anion type. The brushes are chitosan (CH) and chitosans with 27% and 51% degrees of substitution (DS) of quaternary ammonium salts, denoted as CH-Q(25) and CH-Q(50), respectively. The water content and swelling behaviors are monitored using in situ quartz-crystal microbalance with dissipation (QCM-D). The pH varies from similar to 3.5 to 8.5, and the counter anion types include chloride, acetate, and citrate. At fixed pH, the water content and brush swelling increase as the DS increases. While the CH-Q(50) brush layer shows symmetric swelling with a minimum near pH = 4.5, the swelling of CH and CH-Q(25) is relatively constant as pH decreases from 8.2 to 5.5, and then begins to increase near pH 4. These studies indicate that the symmetric swelling of CH-Q(50) is likely attributed to increasing protonation of primary amines at pH values below 6.5 and the quaternary ammonium salts above pH 6.5. At pH 4, the swelling of the CH brush increases upon exchanging the smaller chloride with bulkier acetate anions, which is less effective in screening intra/inter-molecular repulsion. In contrast, upon exchanging the acetate with trifunctional citrate anions, CH and CH-Q(25) brushes collapse by 53 and 42%, respectively, because the citrate anions form ionic cross-links. To test antibacterial properties, silicon oxide, CH and CH-Q(50) brush layers are exposed to 10(7)-10(8) cfu ml(-1) of S. aureus for two days at 37 degrees C and to stepped shear stresses at 2 min intervals. While an S. aureus biofilm adheres strongly to silicon oxide and CH for stresses up to 12 dyne per cm(2), biofilms on CH-Q(50) detach at a relatively low shear stress, 1.5 dyne per cm(2). Due to their high degree of swelling that can be tuned via pH, counterion size and type, chitosan and quaternary modified chitosans have potential as responsive coatings for applications including MEMS/NEMS devices and drug eluting implants.