Nature Communications (Sep 2024)

High-throughput fluorescence lifetime imaging flow cytometry

  • Hiroshi Kanno,
  • Kotaro Hiramatsu,
  • Hideharu Mikami,
  • Atsushi Nakayashiki,
  • Shota Yamashita,
  • Arata Nagai,
  • Kohki Okabe,
  • Fan Li,
  • Fei Yin,
  • Keita Tominaga,
  • Omer Faruk Bicer,
  • Ryohei Noma,
  • Bahareh Kiani,
  • Olga Efa,
  • Martin Büscher,
  • Tetsuichi Wazawa,
  • Masahiro Sonoshita,
  • Hirofumi Shintaku,
  • Takeharu Nagai,
  • Sigurd Braun,
  • Jessica P. Houston,
  • Sherif Rashad,
  • Kuniyasu Niizuma,
  • Keisuke Goda

DOI
https://doi.org/10.1038/s41467-024-51125-y
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 15

Abstract

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Abstract Flow cytometry is a vital tool in biomedical research and laboratory medicine. However, its accuracy is often compromised by undesired fluctuations in fluorescence intensity. While fluorescence lifetime imaging microscopy (FLIM) bypasses this challenge as fluorescence lifetime remains unaffected by such fluctuations, the full integration of FLIM into flow cytometry has yet to be demonstrated due to speed limitations. Here we overcome the speed limitations in FLIM, thereby enabling high-throughput FLIM flow cytometry at a high rate of over 10,000 cells per second. This is made possible by using dual intensity-modulated continuous-wave beam arrays with complementary modulation frequency pairs for fluorophore excitation and acquiring fluorescence lifetime images of rapidly flowing cells. Moreover, our FLIM system distinguishes subpopulations in male rat glioma and captures dynamic changes in the cell nucleus induced by an anti-cancer drug. FLIM flow cytometry significantly enhances cellular analysis capabilities, providing detailed insights into cellular functions, interactions, and environments.