Tunable pH-Responsive Chitosan-Poly(acrylic acid) Electrospun Fibers.

The macromolecular organization in system composed of anionic poly(acrylic acid) (PAA) and cationic chitosan (Cs), with different degrees of deacetylation (DD), under extensive elongational flow, is described. Cs/PAA nanofibers were obtained, and polyelectrolyte complexation only occurred when fibers were immersed in fluid media of a certain pH. Assembled polyelectrolytes complexes formed a pH-triggered system, as demonstrated by reversible change of the swelling degree, by 3 orders of magnitude, and a change on the elastic modulus, by 2 orders of magnitude. Both the swelling degree and the elastic modulus proved sensitive to the DD of Cs. Rheological measurements showed that increased DD of Cs resulted in a decrease in viscosity of both pure Cs and precursor Cs/PAA solutions, attributed to repulsive interactions between ionized amino groups in Cs. At the same time, a DD-dependent change in balance between hydrogen bonding and ion-dipole interactions between the components in Cs/PAA, was responsible for the more pronounced viscosity decrease in these solutions.