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Enhanced Near-Infrared-Excitable Organic Afterglow Nanoparticles for Deep-Tissue Multimodal Imaging via Singlet Oxygen-Mediated Energy Transfer

Yuzhen Yu, Zhe Li, Shiyi Liao, Baoli Yin, Qingpeng Zhang, Jiaqi Fu, Cheng Zhang, Ying Zhou, Guosheng Song

2025Research6 citationsDOIOpen Access PDF

Abstract

Afterglow imaging offers exceptional signal-to-background ratios (SBRs) by circumventing real-time excitation and autofluorescence, yet conventional systems rely on visible-light excitation, limiting tissue penetration and signal intensity. Here, we report near-infrared-excitable organic afterglow nanoparticles (NOANPs) that leverage singlet oxygen ( 1 O 2 )-mediated energy transfer to achieve prolonged, high-intensity emission with minimal photobleaching. The nanoparticles integrate a near-infrared-photoactive sensitizer (NAM-0), which generates abundant 1 O 2 under 808-nm laser excitation, and a triplenet-anthracene derivative (TD) as the afterglow substrate, which converts 1 O 2 into sustained luminescence. Co-encapsulation via one-step nanocoprecipitation ensures proximity between NAM-0 and TD, enabling efficient energy transfer and yielding exceptional afterglow brightness (>10 9 photons/s) at ultralow concentrations (10 μg/ml). NOANPs enable deep-tissue imaging (up to 3.0 cm ex vivo) by synergizing the superior penetration of near-infrared light with organic afterglow chemistry. The nanoparticles uniquely support three imaging modes: fluorescence, white light-activated afterglow, and near-infrared-triggered afterglow, which were validated in orthotopic murine models of pancreatic cancer and glioma. By synergizing near-infrared excitation with organic afterglow chemistry, this work overcomes longstanding limitations in penetration depth of excitation light, offering a versatile tool for precision imaging.

Topics & Concepts

AfterglowSinglet oxygenEnergy transferPhotochemistryMaterials scienceChemistryOxygenChemical physicsPhysicsAstrophysicsGamma-ray burstOrganic chemistryNanoplatforms for cancer theranosticsPhotoreceptor and optogenetics researchOptical Imaging and Spectroscopy Techniques
Enhanced Near-Infrared-Excitable Organic Afterglow Nanoparticles for Deep-Tissue Multimodal Imaging via Singlet Oxygen-Mediated Energy Transfer | Litcius