Temporally Programmed Disassembly and Reassembly of C3Ms

Responsive materials, which can adapt and operate autonomously under dynamic conditions, are a stepping stone towards functional, life‐like systems inspired by fueled self‐assembly processes in nature. Complex coacervate core micelles (C3Ms) comprising oppositely charged macromolecules constitute a novel class of polymeric micelles ideally suited for use as responsive nanoscopic delivery vehicles of hydrophilic and hydrophobic cargo. To fully exploit their potential, it is important that the C3Ms form and fall apart in an autonomous fashion as orchestrated by dynamic cues in their environment. Herein a means to temporally program the self‐regulated C3M coassembly pathway, using a modulated base‐catalyzed feedback system, is presented. Incorporated in the C3Ms is a pH responsive polyfluorene‐based conjugated polyelectrolyte (CPF) as a building block and trace amounts of a molecular sensor (doxorubicin HCl) as cargo, both of which report on micellar coassembly and disassembly via binding‐induced fluorescence quenching. CPF additionally reports on the pH of its microenvironment as its pH‐dependent conformational states are mirrored in the transitions of its vibronic bands. This experimental design enables one to monitor solution pH, C3M disassembly and reassembly, as well as cargo release and recapture noninvasively in a closed system with real time florescence experiments. Herein, temporally programmed, self‐regulating disassembly and reassembly of C3Ms in a modulated base‐catalyzed feedback system is presented. The C3Ms comprise a pH responsive polyfluorene‐based conjugated polyelectrolyte as a building block and trace amounts of a molecular sensor (doxorubicin HCl) as cargo, both of which report on micellar assembly states via their unique fluorescence response.