NIR‐I Activated Orthogonal NIR‐IIb/c Emissions in a Lanthanide‐Doped Nanoparticle for Fluorescence Imaging and Information Encryption

Applying the orthogonal principle for distinguishable second near‐infrared (NIR‐II) emissions has brought new dimensions for ratio fluorescence imaging (RFI) detection and information encryption, deepening the tissue detection depth and improving signal‐to‐noise ratio and information security. Howev...

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Bibliographic Details
Published in:Advanced science 2024-11, Vol.11 (44), p.e2408097-n/a
Main Authors: Li, Qiqing, Huang, Yuanping, Zhu, Haoyu, Zhu, Yaqi, Yi, Yuexi, Li, Xiaodan, Chen, Haoran, Li, Bin, Li, Dabing, Chang, Yulei
Format: Article
Language:English
Subjects:
Blood vessels
encryption
Energy
Information storage
lanthanides
Morphology
Nanoparticles
NIR‐II
orthogonal emission
ratiometric fluorescence imaging
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Summary:Applying the orthogonal principle for distinguishable second near‐infrared (NIR‐II) emissions has brought new dimensions for ratio fluorescence imaging (RFI) detection and information encryption, deepening the tissue detection depth and improving signal‐to‐noise ratio and information security. However, the orthogonal NIR‐II emissions underlying these advanced optical applications have been reported only in heterogeneous structures and mixtures, limiting their practicality and potential impact. Herein, NIR‐I‐activated orthogonal NIR‐IIb/c (1530/1825 nm) emissions nanoparticles (ONNPs) are developed by spatially separated doping of Tm3+ and Er3+ emitter upon switching 808 and 980 nm excitations. RFI techniques and orthogonal NIR‐II emission ONNPs are used to demonstrate vessel depth detection based on wavelength‐dependent optical attenuation properties in tissue. The superiority of the optical coding and encoding process in a 4 × 1 binary matrix is demonstrated for anticounterfeiting and decryption imaging of quick‐response (QR) code for information storage. The research progress of this NIR‐II orthogonal emissions probe will drive the development of biomedical sensing, imaging safety, and future biophotonics technologies. The orthogonal NIR‐IIb/c nanoparticles are designed by core‐shell‐shell‐shell structured Li‐based fluoride, producing independent emissions at 1825 and 1530 nm by switching the 808/980 nm excitation. According to their photo‐switchable NIR‐IIb/c emissions, this work demonstrates their great potential in ratiometric fluorescence imaging and optical information security.
ISSN:2198-3844
2198-3844
DOI:10.1002/advs.202408097