Photothermal treatment, a new approach for inactivation of bacteria and pathogens that does not depend on traditional therapeutic approaches, has recently received much attention. In this study, a new type of nanoplatform (PDA@Fe3O4 + PES) was fabricated by using polydopamine (PDA, a photothermal conversion agent) to encapsulate Fe3O4 (a magnetic nanoparticle) and support 2-phenylethynesulfonamide (PES, an inhibitor of heat shock protein 70 (HSP70)). Upon near-infrared light irradiation, the increased temperature weakens π-π and hydrogen bonding interactions, and PES is released from the PDA@Fe3O4 + PES. The released PES inhibits the function of HSP70, reducing bacterial tolerance to photothermal therapy and improving the therapeutic effect against infectious bacterial pathogens. After treatment, PDA@Fe3O4 + PES can be recovered using the magnetic property of the Fe3O4 cores. Consequently, PDA@Fe3O4 + PES possesses the potential to be a recyclable photothermal agent for enhanced photothermal bacterial inactivation without causing secondary pollution.
Keywords: HSP70 inhibitor; bacteria; magnetic nanoparticles; photothermal; polydopamine.