pH-responsive and antibacterial properties of self-assembled multilayer films based on chitosan and tannic acid.

Polyelectrolyte layer-by-layer (LbL) films that disintegrate under physiological conditions are intensively studied as coatings to enable the release of bioactive components. Herein, we report on the interactions and pH-stability of LbL films composed of chitosan (CH) or N-(2-hydroxypropyl)-3-trimethylammonium chitosan chloride (CMCH) and tannic acid (TA), employed to guarantee the film disintegration. The self-assembly of TA with CH and CMCH at pH 5 and with CMCH at pH 7.4 were proven by turbidimetric, surface plasmon resonance and UV-Vis analyses. The LbL films exhibited pH-dependent properties; CMCH/TA films prepared at pH 7.4 showed exponential growth as well as a higher layer thickness and surface roughness, whereas films prepared at pH 5 grew linearly and were smoother. The film stability varied with the pH used for film assembly; CH/TA films assembled at pH 5 were unstable at pH 8.5, whereas CMCH/TA films assembled at pH 7.4 disintegrated at pH 4. All films exhibited a similar disassembly at pH 7.4. The coatings reduced the adhesion of E. coli and S. aureus by approximately 80%. CMCH-terminated CMCH/TA films were more resistant to bacterial adhesion, whereas CH-terminated CH/TA films demonstrated stronger killing activity. The prepared pH-triggered decomposable LbL films could be used as degradable coatings that allow the release of therapeutics for biomedical applications and also prevent bacterial adhesion.