Multifunctional optical tomography system combining surface extraction and 3D fluorescence reconstruction

Conference on Biomedical Photonics and Cross-Fusion Pub Date : 2023-07-28 DOI:10.1117/12.2692026

Yanan Wu, Shengyu Gao, Linlin Li, Jianru Zhang, Qian Hu, Xin Lou, Xinjun Zhu, Jiahua Jiang, Wuwei Ren

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引用次数: 1

Abstract

Macroscopic-level diffuse optical imaging has been widely used in small animal imaging for preclinical research. Due to severe light scattering, 3D reconstruction in diffuse optics is highly ill-posed and sensitive to small noise in measurement. Bringing prior information such as the inner structural or surface information of the imaging object may largely reduce the ill-posed nature of the inverse problem and improve the reconstruction accuracy. Most existing solutions use additional equipment or multimodal techniques (e.g., CT, MRI, etc.). However, these methods pose new challenges such as increased cost and image alignment between different modalities. Herein, we present a novel compact optical tomography system that enables surface extraction using a single programmable scanning module and pinhole modeling. Experiments on phantom and mice show that the system is capable of achieving high-fidelity surface extraction with a minimal error of less than 0.1 mm, which in turn improves the accuracy of 3D fluorescence reconstruction

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结合表面提取和三维荧光重建的多功能光学层析成像系统

宏观级漫射光学成像已广泛应用于小动物影像学临床前研究。由于严重的光散射，漫射光学的三维重建具有高度的不适定性，并且对测量中的小噪声敏感。引入成像对象的内部结构或表面信息等先验信息，可以大大降低反演问题的病态性，提高反演精度。大多数现有的解决方案使用额外的设备或多模态技术(例如，CT, MRI等)。然而，这些方法带来了新的挑战，如成本增加和不同模态之间的图像对齐。在此，我们提出了一种新型的紧凑光学层析成像系统，该系统使用单个可编程扫描模块和针孔建模来实现表面提取。幻影和小鼠实验表明，该系统能够实现高保真的表面提取，最小误差小于0.1 mm，从而提高了三维荧光重建的精度

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Conference on Biomedical Photonics and Cross-Fusion

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