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Abstract
This study explores the development of thermosensitive nanostructured coacervates formed by mixing ABA and AB block copolymers. Coacervates are liquid–liquid phase separation systems that can concentrate specific biomolecules, making them useful for biomedical applications such as sustained drug release. This study focuses on creating complex coacervates using ABA-type triblock copolymers that can bridge isolated polyion complex (PIC) domains, enabling the formation of well-ordered assemblies of polyethylene glycol (PEG)-conjugated PIC nanoparticles. These coacervates exhibit reversible responses to temperature changes and morphological hysteresis upon cooling, allowing for the controlled release of PIC micelles at physiological temperatures in the zero-order kinetics. This study demonstrates that the degree of bridging of PIC domains can be tuned simply by adjusting the blend ratio of diblock to triblock copolymers, which affects their physical properties and responsiveness. Real-time and snapshot observations of the assembling behaviors upon heating clarify the formation process of coacervates from both nano- and microscale viewpoints. The successful sustained release of a model protein, green fluorescent protein, is also confirmed to occur in a zero-order manner. These findings suggest that these coacervates are promising depot formulations for nanomedicine, offering a novel model for studying intracellular biomolecular condensates and an intervention method for condensates.
