Multimodal imaging combining time-domain near-infrared optical tomography and continuous-wave fluorescence molecular tomography Articles uri icon

authors

  • REN, WUWEI
  • JIANG, JINGJING
  • DI COSTANZO MATA, ALDO
  • KALYANOV, ALEXANDER
  • RIPOLL LORENZO, JORGE
  • LINDNER, SCOTT
  • CHARBON, EDOARDO
  • ZHANG, CHAO
  • RUDIN, MARKUS
  • WOLF, MARTIN

publication date

  • March 2020

start page

  • 9860

end page

  • 9874

issue

  • 7

volume

  • 28

International Standard Serial Number (ISSN)

  • 1094-4087

abstract

  • Fluorescence molecular tomography (FMT) emerges as a powerful non-invasive imaging tool with the ability to resolve fluorescence signals from sources located deep in living tissues. Yet, the accuracy of FMT reconstruction depends on the deviation of the assumed optical properties from the actual values. In this work, we improved the accuracy of the initial optical properties required for FMT using a new-generation time-domain (TD) near-infrared optical tomography (NIROT) system, which effectively decouples scattering and absorption coefficients. We proposed a multimodal paradigm combining TD-NIROT and continuous-wave (CW) FMT. Both numerical simulation and experiments were performed on a heterogeneous phantom containing a fluorescent inclusion. The results demonstrate significant improvement in the FMT reconstruction by taking the NIROT-derived optical properties as prior information. The multimodal method is attractive for preclinical studies and tumor diagnostics since both functional and molecular information can be obtained.

subjects

  • Biology and Biomedicine
  • Electronics
  • Materials science and engineering
  • Mechanical Engineering