Zwitterionic Nanocapsules with Salt- and Thermo-Responsiveness for Controlled Encapsulation and Release

Intelligent polymer nanocapsules that can not only encapsulate substances efficiently but also release them in a controllable manner hold great potential in many applications. To date, although intensive efforts have been made to develop intelligent polymer nanocapsules, how to construct the well-defined core/shell structure with high stability via a straightforward method remains a considerable challenge. In this work, the target novel zwitterionic nanocapsules (ZN(C)s) with a stable hollow structure were synthesized by inverse reversible addition fragmentation transfer (RAFT) miniemulsion interfacial polymerization. The shell gradually grew from the water/oil interface due to the interfacial polymerization, accompanied by the cross-linking of the polyzwitterionic networks, where the core/shell structure could be well-tuned by adjusting the precursor compositions. The resultant ZN(C)s exhibited a salt-/thermoinduced swelling behavior through the phase transition of the external zwitterionic polymers. To further investigate the functions of ZN(C)s, different substances, such as methyl orange and bovine serum albumin (BSA), were encapsulated into the ZN(C)s with a high encapsulation efficiency of 89.3 and 93.6%, respectively. Interestingly, the loaded substances can be controllably released in aqueous solution triggered by salt or temperature variations, and such responsiveness also can be utilized to bounce off the bacteria adhered on target surfaces. We believe that these designed salt- and thermo-responsive intelligent polymer nanocapsules with well-defined core/shell structures and antifouling surfaces should be a promising platform for biomedical and saline related applications.

Automated summary

Intelligent zwitterionic nanocapsules were synthesized using inverse reversible addition fragmentation transfer (RAFT) technique, allowing controlled release of encapsulated substances triggered by salt or temperature variations. The designed nanocapsules with defined core/shell structures and antifouling surfaces show promising applications in biomedical and saline related fields.