Lanthanide luminescence nanothermometer with working wavelength beyond 1500 nm for cerebrovascular temperature imaging in vivo

Nanothermometers enable the detection of temperature changes at the microscopic scale, which is crucial for elucidating biological mechanisms and guiding treatment strategies. However, temperature monitoring of micron-scale structures in vivo using luminescent nanothermometers remains challenging, p...

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Published inNature communications Vol. 15; no. 1; p. 2341
Main Authors Wu, Yukai, Li, Fang, Wu, Yanan, Wang, Hao, Gu, Liangtao, Zhang, Jieying, Qi, Yukun, Meng, Lingkai, Kong, Na, Chai, Yingjie, Hu, Qian, Xing, Zhenyu, Ren, Wuwei, Li, Fuyou, Zhu, Xingjun
Format Journal Article
LanguageEnglish
Published London Nature Publishing Group UK 15.03.2024
Nature Publishing Group
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Summary:Nanothermometers enable the detection of temperature changes at the microscopic scale, which is crucial for elucidating biological mechanisms and guiding treatment strategies. However, temperature monitoring of micron-scale structures in vivo using luminescent nanothermometers remains challenging, primarily due to the severe scattering effect of biological tissue that compromises the imaging resolution. Herein, a lanthanide luminescence nanothermometer with a working wavelength beyond 1500 nm is developed to achieve high-resolution temperature imaging in vivo. The energy transfer between lanthanide ions (Er 3+ and Yb 3+ ) and H 2 O molecules, called the environment quenching assisted downshifting process, is utilized to establish temperature-sensitive emissions at 1550 and 980 nm. Using an optimized thin active shell doped with Yb 3+ ions, the nanothermometer’s thermal sensitivity and the 1550 nm emission intensity are enhanced by modulating the environment quenching assisted downshifting process. Consequently, minimally invasive temperature imaging of the cerebrovascular system in mice with an imaging resolution of nearly 200 μm is achieved using the nanothermometer. This work points to a method for high-resolution temperature imaging of micron-level structures in vivo, potentially giving insights into research in temperature sensing, disease diagnosis, and treatment development. The strong scattering of biological tissue causes challenges when monitoring temperature changes at the microscale. Here, the authors propose a nanothermometer based on lanthanide luminescence, enabling minimally invasive imaging of the cerebrovascular system of mice at nearly 200 μm resolution.
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ISSN:2041-1723
2041-1723
DOI:10.1038/s41467-024-46727-5