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Optimizing Energy Transfer in Nanostructures Enables In Vivo Cancer Lesion Tracking via Near‐Infrared Excited Hypoxia Imaging

Yantao Li, Jiaming Liu, Zuochao Wang, Jun‐O Jin, Yaling Liu, Chunying Chen, Zhiyong Tang

2020Advanced Materials57 citationsDOIOpen Access PDF

Abstract

Abstract To explore highly sensitive and low‐toxicity techniques for tracking and evaluation of non‐small‐cell lung cancer (NSCLC), one of the most mortal tumors in the world, it is utterly imperative for doctors to select the appropriate treatment strategies. Herein, developing near‐infrared (NIR) excited nanosensors, in which the donor and acceptor pairs within a biological metal–organic framework (bio‐MOF) matrix are precisely controlled to rationalize upconversion Förster resonance energy transfer (FRET), is suggested for detecting the O 2 concentration inside tumors with reduced signal disturbance and health detriment. Under NIR excitation, as‐fabricated core/satellite nanosensors exhibit much improved FRET efficiency and reversible hypoxic response with high sensitivity, which are effective both in vitro and in vivo (zebrafish) for cycling normoxia–hypoxia imaging. Significantly, combined with a reliable preclinical genetically engineered murine model, such nanosensors successfully realize tracking of in vivo NSCLC lesions upon clear and gradient hypoxia signals without apparent long‐term biotoxicity, illustrating their exciting potential for efficient NSCLC evaluation and prognosis.

Topics & Concepts

NanosensorFörster resonance energy transferMaterials scienceIn vivoPhoton upconversionNanotechnologyZebrafishHypoxia (environmental)FluorescenceOptoelectronicsBiophysicsLuminescenceBiologyChemistryOpticsOxygenOrganic chemistryBiochemistryGeneBiotechnologyPhysicsNanoplatforms for cancer theranosticsLuminescence and Fluorescent MaterialsSulfur Compounds in Biology
Optimizing Energy Transfer in Nanostructures Enables In Vivo Cancer Lesion Tracking via Near‐Infrared Excited Hypoxia Imaging | Litcius