Nanotheranostic agents (NTAs) that integrate diagnostic capabilities and therapeutic functions have great potential for personalized medicine, yet poor tumor specificity severely restricts further clinical applications of NTAs. Here, a pro-NTA (precursor of nanotheranostic agent) activation strategy is reported for in situ NTA synthesis at tumor tissues to enhance the specificity of tumor therapy. This pro-NTA, also called PBAM, is composed of an MIL-100 (Fe)-coated Prussian blue (PB) analogue (K2 Mn[Fe(CN)6 ]) with negligible absorption in the near-infrared region and spatial confinement of Mn2+ ions. In a mildly acidic tumor microenvironment (TME), PBAM can be specifically activated to synthesize the photothermal agent PB nanoparticles, with release of free Mn2+ ions due to the internal fast ion exchange, resulting in the "ON" state of both T1 -weighted magnetic resonance imaging and photoacoustic signals. In addition, the combined Mn2+ -mediated chemodynamic therapy in the TME and PB-mediated photothermal therapy guarantee a more efficient therapeutic performance compared to monotherapy. In vivo data further show that the pro-NTA activation strategy could selectively brighten solid tumors and detect invisible lymph node metastases with high specificity.
Keywords: Prussian blue nanoparticles; chemodynamic therapy; ion exchange; metal-organic frameworks; photothermal therapy; tumor therapy.
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