走向实时漫射光学断层扫描与手持扫描探头。

IF 2.9 2区医学 Q2 BIOCHEMICAL RESEARCH METHODS

Biomedical optics express Pub Date : 2025-03-26 eCollection Date: 2025-04-01 DOI:10.1364/BOE.549880

Robin Dale, Nicholas Ross, Scott Howard, Thomas D O'Sullivan, Hamid Dehghani

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引用次数: 0

摘要

利用深度学习进行的弥漫性光学断层扫描（DOT）可以实现组织光学特性的高速重建，从而可以实现图像引导扫描，例如增强临床乳腺成像。以前发布的模型是特定于几何的，因此，需要为每个用例生成大量的数据和训练，限制了使用点上的扫描协议。本文提出了一种基于变压器的结构来克服这些对空间非结构化DOT测量进行编码的障碍，使单个训练模型能够处理任意扫描路径和测量密度。利用乳腺组织模拟数据和模拟数据对该模型进行了验证，在24 mm深吸收（μ a）和减少散射（μ s’）图像中，平均rmse分别为0.0095±0.0023 cm-1和1.95±0.78 cm-1， s ørensen- dice系数分别为0.55±0.12和0.67±0.1，异常对比度分别为地面真值对比度的79±10%和93.3±4.6%，有效成像速度为14 Hz。均匀模拟样例的平均绝对μ a和μ s值与真实值相差在10%以内。

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Towards real-time diffuse optical tomography with a handheld scanning probe.

Diffuse optical tomography (DOT) performed using deep-learning allows high-speed reconstruction of tissue optical properties and could thereby enable image-guided scanning, e.g., to enhance clinical breast imaging. Previously published models are geometry-specific and, therefore, require extensive data generation and training for each use case, restricting the scanning protocol at the point of use. A transformer-based architecture is proposed to overcome these obstacles that encode spatially unstructured DOT measurements, enabling a single trained model to handle arbitrary scanning pathways and measurement density. The model is demonstrated with breast tissue-emulating simulated and phantom data, yielding - for 24 mm-deep absorptions (μ _a ) and reduced scattering (μ _s ') images, respectively - average RMSEs of 0.0095±0.0023 cm^-1 and 1.95±0.78 cm^-1, Sørensen-Dice coefficients of 0.55±0.12 and 0.67±0.1, and anomaly contrast of 79±10% and 93.3±4.6% of the ground-truth contrast, with an effective imaging speed of 14 Hz. The average absolute μ _a and μ _s ' values of homogeneous simulated examples were within 10% of the true values.

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来源期刊

Biomedical optics express BIOCHEMICAL RESEARCH METHODS-OPTICS

CiteScore

6.80

自引率

11.80%

发文量

633

审稿时长

1 months

期刊介绍： The journal''s scope encompasses fundamental research, technology development, biomedical studies and clinical applications. BOEx focuses on the leading edge topics in the field, including: Tissue optics and spectroscopy Novel microscopies Optical coherence tomography Diffuse and fluorescence tomography Photoacoustic and multimodal imaging Molecular imaging and therapies Nanophotonic biosensing Optical biophysics/photobiology Microfluidic optical devices Vision research.