Biodegradable Nanobowls with Controlled Dents

Abstract

Nanobowls show promising potential in biomedical applications, such as bioimaging, cargo delivery, and disease theranostics, due to their unique concave structure and interior cavities. However, the lack of biodegradable nanobowls with manipulable size (especially the dent size) still exists as an obstacle for their in-depth exploration and application in biomedical fields. Herein, polypeptide-based nanobowls are successfully obtained by the self-assembly of a graft polypeptide [named TPE-P(GAAzo₂₁-stat-GA₂₉)] via a solvent-switch method. Through the synergistic effect between the hydrogen bonding and π–π stacking interactions, the size of nanobowls and the corresponding dents can be facilely controlled by altering either the initial polypeptide concentration or the cosolvents in self-assembly. Furthermore, such polypeptide-based nanobowls are demonstrated to be biocompatible and biodegradable in vitro, which may promote the development of biomedical nanobowls in the future.