Diffraction tomography and angle recovery algorithms for 3D refractive index reconstruction of microorganisms

Jiang Wu; Mengya Li; Yunpeng Feng; Haobo Cheng; Xiajing Yu

doi:10.1364/AO.592368

Diffraction tomography and angle recovery algorithms for 3D refractive index reconstruction of microorganisms

Jiang Wu
, Mengya Li
, Yunpeng Feng^*
, Haobo Cheng
, Xiajing Yu

^*此作品的通讯作者

光电学院

Beijing Institute of Technology

科研成果: 期刊稿件 › 文章 › 同行评审

摘要

Monitoring aquatic microorganisms is essential for assessing water security, yet conventional microscopy suffers from a limited depth of field and invasive labeling. We report a label-free 3D platform combining microfluidics and off-axis digital holographic diffraction tomography for aquatic microorganism monitoring. By utilizing spontaneous Paramecium rolling, multi-angle holograms are acquired at 55 fps. An SSIM-based algorithm retrieves rolling angles for mechanical stage-free tomography. A GPU-accelerated framework based on the Fourier diffraction theorem, incorporating trilinear interpolation and positivity constraints, reconstructs 3D refractive index (RI) distributions. Results resolve subcellular organelles, including oral grooves (R I ≈ 1.32) and vacuoles (R I ≈ 1.35), with a 40-fold computational speedup. This system enables high-throughput, high-speed sensing of pristine biological specimens.

源语言	英语
页（从-至）	3671-3678
页数	8
期刊	Applied Optics
卷	65
期	11
DOI	https://doi.org/10.1364/AO.592368
出版状态	已出版 - 10 4月 2026

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title = "Diffraction tomography and angle recovery algorithms for 3D refractive index reconstruction of microorganisms",

abstract = "Monitoring aquatic microorganisms is essential for assessing water security, yet conventional microscopy suffers from a limited depth of field and invasive labeling. We report a label-free 3D platform combining microfluidics and off-axis digital holographic diffraction tomography for aquatic microorganism monitoring. By utilizing spontaneous Paramecium rolling, multi-angle holograms are acquired at 55 fps. An SSIM-based algorithm retrieves rolling angles for mechanical stage-free tomography. A GPU-accelerated framework based on the Fourier diffraction theorem, incorporating trilinear interpolation and positivity constraints, reconstructs 3D refractive index (RI) distributions. Results resolve subcellular organelles, including oral grooves (R I ≈ 1.32) and vacuoles (R I ≈ 1.35), with a 40-fold computational speedup. This system enables high-throughput, high-speed sensing of pristine biological specimens.",

author = "Jiang Wu and Mengya Li and Yunpeng Feng and Haobo Cheng and Xiajing Yu",

note = "Publisher Copyright: {\textcopyright} 2026 Optica Publishing Group. All rights, including for text and data mining (TDM), Artificial Intelligence (AI) training, and similar technologies, are reserved.",

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doi = "10.1364/AO.592368",

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AU - Wu, Jiang

AU - Li, Mengya

AU - Feng, Yunpeng

AU - Cheng, Haobo

AU - Yu, Xiajing

PY - 2026/4/10

Y1 - 2026/4/10

N2 - Monitoring aquatic microorganisms is essential for assessing water security, yet conventional microscopy suffers from a limited depth of field and invasive labeling. We report a label-free 3D platform combining microfluidics and off-axis digital holographic diffraction tomography for aquatic microorganism monitoring. By utilizing spontaneous Paramecium rolling, multi-angle holograms are acquired at 55 fps. An SSIM-based algorithm retrieves rolling angles for mechanical stage-free tomography. A GPU-accelerated framework based on the Fourier diffraction theorem, incorporating trilinear interpolation and positivity constraints, reconstructs 3D refractive index (RI) distributions. Results resolve subcellular organelles, including oral grooves (R I ≈ 1.32) and vacuoles (R I ≈ 1.35), with a 40-fold computational speedup. This system enables high-throughput, high-speed sensing of pristine biological specimens.

AB - Monitoring aquatic microorganisms is essential for assessing water security, yet conventional microscopy suffers from a limited depth of field and invasive labeling. We report a label-free 3D platform combining microfluidics and off-axis digital holographic diffraction tomography for aquatic microorganism monitoring. By utilizing spontaneous Paramecium rolling, multi-angle holograms are acquired at 55 fps. An SSIM-based algorithm retrieves rolling angles for mechanical stage-free tomography. A GPU-accelerated framework based on the Fourier diffraction theorem, incorporating trilinear interpolation and positivity constraints, reconstructs 3D refractive index (RI) distributions. Results resolve subcellular organelles, including oral grooves (R I ≈ 1.32) and vacuoles (R I ≈ 1.35), with a 40-fold computational speedup. This system enables high-throughput, high-speed sensing of pristine biological specimens.

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M3 - Article

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JO - Applied Optics

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ER -

Diffraction tomography and angle recovery algorithms for 3D refractive index reconstruction of microorganisms

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