Encoder-decoder deep learning network for simultaneous reconstruction of fluorescence yield and lifetime distributions

Jiaju Cheng; Peng Zhang; Fei Liu; Jie Liu; Hui Hui; Jie Tian; Jianwen Luo

doi:10.1364/BOE.466349

Encoder-decoder deep learning network for simultaneous reconstruction of fluorescence yield and lifetime distributions

Jiaju Cheng
, Peng Zhang
, Fei Liu
, Jie Liu
, Hui Hui
, Jie Tian
, Jianwen Luo^*

^*Corresponding author for this work

School of Engineering Medicine

Tsinghua University
Beijing Jiaotong University
CAS - Institute of Automation
Beijing Information Science & Technology University

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

A time-domain fluorescence molecular tomography in reflective geometry (TD-rFMT) has been proposed to circumvent the penetration limit and reconstruct fluorescence distribution within a 2.5-cm depth regardless of the object size. In this paper, an end-to-end encoder-decoder network is proposed to further enhance the reconstruction performance of TD-rFMT. The network reconstructs both the fluorescence yield and lifetime distributions directly from the time-resolved fluorescent signals. According to the properties of TD-rFMT, proper noise was added to the simulation training data and a customized loss function was adopted for self-supervised and supervised joint training. Simulations and phantom experiments demonstrate that the proposed network can significantly improve the spatial resolution, positioning accuracy, and accuracy of lifetime values.

Original language	English
Pages (from-to)	4693-4705
Number of pages	13
Journal	Biomedical Optics Express
Volume	13
Issue number	9
DOIs	https://doi.org/10.1364/BOE.466349
State	Published - 1 Sep 2022

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10.1364/BOE.466349

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title = "Encoder-decoder deep learning network for simultaneous reconstruction of fluorescence yield and lifetime distributions",

abstract = "A time-domain fluorescence molecular tomography in reflective geometry (TD-rFMT) has been proposed to circumvent the penetration limit and reconstruct fluorescence distribution within a 2.5-cm depth regardless of the object size. In this paper, an end-to-end encoder-decoder network is proposed to further enhance the reconstruction performance of TD-rFMT. The network reconstructs both the fluorescence yield and lifetime distributions directly from the time-resolved fluorescent signals. According to the properties of TD-rFMT, proper noise was added to the simulation training data and a customized loss function was adopted for self-supervised and supervised joint training. Simulations and phantom experiments demonstrate that the proposed network can significantly improve the spatial resolution, positioning accuracy, and accuracy of lifetime values.",

author = "Jiaju Cheng and Peng Zhang and Fei Liu and Jie Liu and Hui Hui and Jie Tian and Jianwen Luo",

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T1 - Encoder-decoder deep learning network for simultaneous reconstruction of fluorescence yield and lifetime distributions

AU - Cheng, Jiaju

AU - Zhang, Peng

AU - Liu, Fei

AU - Liu, Jie

AU - Hui, Hui

AU - Tian, Jie

AU - Luo, Jianwen

PY - 2022/9/1

Y1 - 2022/9/1

N2 - A time-domain fluorescence molecular tomography in reflective geometry (TD-rFMT) has been proposed to circumvent the penetration limit and reconstruct fluorescence distribution within a 2.5-cm depth regardless of the object size. In this paper, an end-to-end encoder-decoder network is proposed to further enhance the reconstruction performance of TD-rFMT. The network reconstructs both the fluorescence yield and lifetime distributions directly from the time-resolved fluorescent signals. According to the properties of TD-rFMT, proper noise was added to the simulation training data and a customized loss function was adopted for self-supervised and supervised joint training. Simulations and phantom experiments demonstrate that the proposed network can significantly improve the spatial resolution, positioning accuracy, and accuracy of lifetime values.

AB - A time-domain fluorescence molecular tomography in reflective geometry (TD-rFMT) has been proposed to circumvent the penetration limit and reconstruct fluorescence distribution within a 2.5-cm depth regardless of the object size. In this paper, an end-to-end encoder-decoder network is proposed to further enhance the reconstruction performance of TD-rFMT. The network reconstructs both the fluorescence yield and lifetime distributions directly from the time-resolved fluorescent signals. According to the properties of TD-rFMT, proper noise was added to the simulation training data and a customized loss function was adopted for self-supervised and supervised joint training. Simulations and phantom experiments demonstrate that the proposed network can significantly improve the spatial resolution, positioning accuracy, and accuracy of lifetime values.

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DO - 10.1364/BOE.466349

M3 - 文章

AN - SCOPUS:85137708846

SN - 2156-7085

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SP - 4693

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JO - Biomedical Optics Express

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ER -

Encoder-decoder deep learning network for simultaneous reconstruction of fluorescence yield and lifetime distributions

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