VoxelMorph-Based Deep Learning Motion Correction for Ultrasound Localization Microscopy of Spinal Cord.

IF 3 2区 工程技术 Q1 ACOUSTICS
Junjin Yu, Yang Cai, Zhili Zeng, Kailiang Xu
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引用次数: 0

Abstract

Accurate assessment of spinal cord vasculature is important for the urgent diagnosis of injury and subsequent treatment. Ultrasound localization microscopy (ULM) offers super-resolution imaging of microvasculature by localizing and tracking individual microbubbles across multiple frames. However, a long data acquisition often involves significant motion artifacts caused by breathing and heartbeat, which further impairs the resolution of ULM. This effect is particularly pronounced in spinal cord imaging due to respiratory movement. We propose a VoxelMorph-based deep learning motion correction method to enhance ULM performance in spinal cord imaging. Simulations were conducted to demonstrate the motion estimation accuracy of the proposed method, achieving a mean absolute error of 8 μm. Results from in vivo experiments show that the proposed method efficiently compensates for rigid and nonrigid motion, providing improved resolution with smaller vascular diameters and enhanced microvessel reconstruction after motion correction. Nonrigid deformation fields with varying displacement magnitudes were applied to in vivo data for assessing the robustness of the algorithm.

基于深度学习运动校正的脊髓超声定位显微镜 VoxelMorph。
准确评估脊髓血管对于紧急诊断损伤和后续治疗非常重要。超声定位显微镜(ULM)通过定位和跟踪多个帧中的单个微气泡,对微血管进行超分辨率成像。然而,长时间的数据采集往往会因呼吸和心跳造成明显的运动伪影,从而进一步影响 ULM 的分辨率。在脊髓成像中,由于呼吸运动,这种影响尤为明显。我们提出了一种基于 VoxelMorph 的深度学习运动校正方法,以提高脊髓成像中的超低分辨率。我们通过模拟实验证明了所提方法的运动估计精度,其平均绝对误差为 8 μm。体内实验结果表明,所提出的方法能有效补偿刚性和非刚性运动,在运动校正后,能以更小的血管直径提高分辨率,并增强微血管重建。为了评估该算法的鲁棒性,我们将具有不同位移幅度的非刚性形变场应用于体内数据。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.70
自引率
16.70%
发文量
583
审稿时长
4.5 months
期刊介绍: IEEE Transactions on Ultrasonics, Ferroelectrics and Frequency Control includes the theory, technology, materials, and applications relating to: (1) the generation, transmission, and detection of ultrasonic waves and related phenomena; (2) medical ultrasound, including hyperthermia, bioeffects, tissue characterization and imaging; (3) ferroelectric, piezoelectric, and piezomagnetic materials, including crystals, polycrystalline solids, films, polymers, and composites; (4) frequency control, timing and time distribution, including crystal oscillators and other means of classical frequency control, and atomic, molecular and laser frequency control standards. Areas of interest range from fundamental studies to the design and/or applications of devices and systems.
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