Fast fit-free analysis of fluorescence lifetime imaging via deep learning.
Jason T SmithRuoyang YaoNattawut SinsuebphonAlena RudkouskayaNathan UnJoseph MazurkiewiczMargarida M BarrosoPingkun YanXavier IntesPublished in: Proceedings of the National Academy of Sciences of the United States of America (2019)
Fluorescence lifetime imaging (FLI) provides unique quantitative information in biomedical and molecular biology studies but relies on complex data-fitting techniques to derive the quantities of interest. Herein, we propose a fit-free approach in FLI image formation that is based on deep learning (DL) to quantify fluorescence decays simultaneously over a whole image and at fast speeds. We report on a deep neural network (DNN) architecture, named fluorescence lifetime imaging network (FLI-Net) that is designed and trained for different classes of experiments, including visible FLI and near-infrared (NIR) FLI microscopy (FLIM) and NIR gated macroscopy FLI (MFLI). FLI-Net outputs quantitatively the spatially resolved lifetime-based parameters that are typically employed in the field. We validate the utility of the FLI-Net framework by performing quantitative microscopic and preclinical lifetime-based studies across the visible and NIR spectra, as well as across the 2 main data acquisition technologies. These results demonstrate that FLI-Net is well suited to accurately quantify complex fluorescence lifetimes in cells and, in real time, in intact animals without any parameter settings. Hence, FLI-Net paves the way to reproducible and quantitative lifetime studies at unprecedented speeds, for improved dissemination and impact of FLI in many important biomedical applications ranging from fundamental discoveries in molecular and cellular biology to clinical translation.
Keyphrases
- deep learning
- high resolution
- single molecule
- photodynamic therapy
- fluorescence imaging
- neural network
- energy transfer
- artificial intelligence
- stem cells
- healthcare
- machine learning
- electronic health record
- drug release
- convolutional neural network
- drug delivery
- big data
- resistance training
- cell death
- bone marrow
- cell therapy
- molecular dynamics
- mass spectrometry
- signaling pathway
- cell cycle arrest
- quantum dots