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Published August 21, 2024 | Published
Journal Article Open

Sharp-peaked lanthanide nanocrystals for near-infrared photoacoustic multiplexed differential imaging

Loh, Kang Yong1, 2 ORCID icon
Li, Lei S.3, 4 ORCID icon
Fan, Jingyue5 ORCID icon
Goh, Yi Yiing5 ORCID icon
Liew, Weng Heng1
Davis, Samuel3 ORCID icon
Zhang, Yide3 ORCID icon
Li, Kai1, 6 ORCID icon
Liu, Jie7
Liang, Liangliang5 ORCID icon
Feng, Minjun8 ORCID icon
Yang, Ming9 ORCID icon
Zhang, Hang9 ORCID icon
Ma, Ping'an10 ORCID icon
Feng, Guangxue5 ORCID icon
Mu, Zhao8
Gao, Weibo8 ORCID icon
Sum, Tze Chien8 ORCID icon
Liu, Bin5 ORCID icon
Lin, Jun10 ORCID icon
Yao, Kui1 ORCID icon
Wang, Lihong V.3 ORCID icon
Liu, Xiaogang1, 5 ORCID icon
  • 1. ROR icon Institute of Materials Research and Engineering
  • 2. ROR icon Stanford University
  • 3. ROR icon California Institute of Technology
  • 4. ROR icon Rice University
  • 5. ROR icon National University of Singapore
  • 6. ROR icon Southern University of Science and Technology
  • 7. ROR icon Nanjing Tech University
  • 8. ROR icon Nanyang Technological University
  • 9. ROR icon Institute of Engineering Thermophysics
  • 10. ROR icon Changchun Institute of Applied Chemistry

Abstract

Photoacoustic tomography offers a powerful tool to visualize biologically relevant molecules and understand processes within living systems at high resolution in deep tissue, facilitated by the conversion of incident photons into low-scattering acoustic waves through non-radiative relaxation. Although current endogenous and exogenous photoacoustic contrast agents effectively enable molecular imaging within deep tissues, their broad absorption spectra in the visible to near-infrared (NIR) range limit photoacoustic multiplexed imaging. Here, we exploit the distinct ultrasharp NIR absorption peaks of lanthanides to engineer a series of NIR photoacoustic nanocrystals. This engineering involves precise host and dopant material composition, yielding nanocrystals with sharply peaked photoacoustic absorption spectra (~3.2 nm width) and a ~10-fold enhancement in NIR optical absorption for efficient deep tissue imaging. By combining photoacoustic tomography with these engineered nanocrystals, we demonstrate photoacoustic multiplexed differential imaging with substantially decreased background signals and enhanced precision and contrast.

Copyright and License

Copyright © 2024, The Author(s). This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. 

Acknowledgement

We are very grateful to Renzhe Bi and Xiuting Li for their assistance in the initial stages of testing our nanocrystals in PA experiments. We also like to thank Melgious Ang for his assistance in conducting cellular toxicity studies on the nanocrystals. We also like to express our gratitude to Ding Ding for provided technical insights and guidance on experimental interpretation. This work is supported by National Research Foundation, Prime Minister’s Office, Singapore under its Competitive Research Program (Award No. NRF-CRP23-2019-0002) and under its NRF Investigatorship Programme (Award No. NRF-NRFI05-2019-0003), the RIE2025 Manufacturing, Trade and Connectivity (MTC) Programmatic Fund (Award No. M21J9b0085), and National Institutes of Health, United States, grants U01 NS099717 (BRAIN Initiative) and R01 EB028277A, the internal fund F10000205 from Rice University, the Basic Science Center Program for Ordered Energy Conversion of the National Natural Science Foundation of China (No. 51888103), National Natural Science Foundation of China (51606192) and the CAS Pioneer Hundred Talents Program. Partial supports by A*STAR, Singapore, RIE2020 Advanced Manufacturing and Engineering (AME) Programmatic Fund (Grant No. A20G9b0135) are acknowledged.

Conflict of Interest

The authors declare the following competing interests: L.V.W. has financial interests in Microphotoacoustics, Inc., CalPACT, LLC, and Union Photoacoustic Technologies, Ltd., which did not support this work. L.S.L. has a financial interest in BLOCH Quantum Imaging Solutions, although they did not support this work. The other authors declare no competing interests.

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December 3, 2024
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