Tailoring the plasmonic properties of gold-liposome nanohybrids as a potential powerful tool for light-mediated therapies

Abstract

A fast and environmentally-friendly methodology has been developed by in situ synthesis of gold nanoparticles (AuNPs) on thermosensitive liposomes in different phase-states, obtaining nanohybrids with controllable and tunable plasmon modes within the visible/near-infrared region. Lipid phase, charge and synthesis temperature influence the final arrangement of AuNPs, so when the synthesis is performed on zwitterionic liposomes in fluid phase, discrete AuNPs with plasmon peaks in the visible region are obtained, while in gel phase AuNPs tend to aggregate forming nanoclusters, leading to plasmon bands gradually shifted to the infrared as the synthesis temperature decreases. The formed nanohybrids retain the physical properties of the liposomes (fluidity, degree of hydration, cooperativity) by maintaining the transition temperature in the mild-hyperthermia range, while preserving their light-to-heat conversion properties. Therefore, these nanohybrids can be considered excellent candidates as versatile photothermal agents with controlled drug delivery capacity, being powerful tools for light-mediated therapies.