Dual modified ferritin nanocages for tumor-targeted and microenvironment-responsive drug delivery

Human heavy-chain ferritin (HFn) possesses a stable and uniform cage-like structure, tumor-targeting properties, self-assembly capabilities, and biocompatibility, rendering it an ideal candidate for drug delivery. Here, we developed a dual modified HFn-based nanocage (DFn) that targets the urokinase-type plasminogen activator receptor (uPAR) and, at the same time, is responsive to the tumor microenvironment for controlled extracellular drug release. This DFn was used to co-encapsulate a photosensitizer (CPZ) and a hypoxia-activated prodrug (TPZ), creating the multifunctional nanoparticles C/T@DFn. In vitro cellular assays demonstrated that C/T@DFn significantly outperformed both unmodified HFn-based nanoparticles and its counterpart without the uPAR-targeting motif in inhibiting tumor cell survival, proliferation, and migration, and showed enhanced tumor cell spheroids penetration. In vivo studies further demonstrated the improved tumor-specific accumulation and antitumor efficacy of the loaded cargo in the DFn nanocages in comparison with wild-type HFn. This improved therapeutic effect is achieved through receptor-mediated targeting and tumor microenvironment-responsive release of the cargo from the DFn nanocages, resulting in synergistic action of CPZ and TPZ within the tumor tissue. Overall, this study introduces an ideal ferritin-based nanoplatform for the efficient co-delivery of therapeutic agents, offering a promising strategy for targeted tumor therapy.

Antitumor; Ferritin nanocage; uPAR-targeting.