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引用次数: 0
摘要
近端旋转扫描主要用于内窥镜和血管内 OCT 的临床实践,这主要是因为与远端扫描相比,探头的制造成本要低得多。然而,近端扫描会导致严重的光束稳定性问题(也称为非均匀旋转变形,NURD),这阻碍了其在功能成像(如 OCT 弹性成像,OCE)方面的应用。在这项工作中,我们展示了基于学习的 NURD 校正方法实现基于强度的 OCE 所需的成像稳定性的能力。与之前使用伪失真向量进行模型训练的基于学习的 NURD 校正方法相比,我们提出了一种从特定内窥镜 OCT 系统中提取真实失真向量的方法,并验证了其在基于卷积神经网络和转换器的学习架构下的准确性优势。我们进一步验证了它在弹性成像计算(数字图像相关性和光流)中的有效性,以及我们的方法与其他 NURD 校正方法相比的优势。利用球囊导管的气压作为机械刺激,我们的近端扫描内窥镜 OCE 可以有效区分动脉粥样硬化血管模型的不同僵硬度区域。与仅在径向进行测量的现有内窥镜 OCE 方法相比,我们的方法可在径向和周向实现二维位移/应变分布。
Learning-based distortion correction enables proximal-scanning endoscopic OCT elastography.
Proximal rotary scanning is predominantly used in the clinical practice of endoscopic and intravascular OCT, mainly because of the much lower manufacturing cost of the probe compared to distal scanning. However, proximal scanning causes severe beam stability issues (also known as non-uniform rotational distortion, NURD), which hinders the extension of its applications to functional imaging, such as OCT elastography (OCE). In this work, we demonstrate the abilities of learning-based NURD correction methods to enable the imaging stability required for intensity-based OCE. Compared with the previous learning-based NURD correction methods that use pseudo distortion vectors for model training, we propose a method to extract real distortion vectors from a specific endoscopic OCT system, and validate its superiority in accuracy under both convolutional-neural-network- and transformer-based learning architectures. We further verify its effectiveness in elastography calculations (digital image correlation and optical flow) and the advantages of our method over other NURD correction methods. Using the air pressure of a balloon catheter as a mechanical stimulus, our proximal-scanning endoscopic OCE could effectively differentiate between areas of varying stiffness of atherosclerotic vascular phantoms. Compared with the existing endoscopic OCE methods that measure only in the radial direction, our method could achieve 2D displacement/strain distribution in both radial and circumferential directions.
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.