Deep Learning-Based Reconstruction of 3D T1 SPACE Vessel Wall Imaging Provides Improved Image Quality with Reduced Scan Times: A Preliminary Study.

Girish Bathla, Steven A Messina, David F Black, John C Benson, Peter Kollasch, Marcel D Nickel, Neetu Soni, Brian C Rucker, Ian T Mark, Felix E Diehn, Amit K Agarwal
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Abstract

Background and purpose: Intracranial vessel wall imaging is technically challenging to implement, given the simultaneous requirements of high spatial resolution, excellent blood and CSF signal suppression, and clinically acceptable gradient times. Herein, we present our preliminary findings on the evaluation of a deep learning-optimized sequence using T1-weighted imaging.

Materials and methods: Clinical and optimized deep learning-based image reconstruction T1 3D Sampling Perfection with Application optimized Contrast using different flip angle Evolution (SPACE) were evaluated, comparing noncontrast sequences in 10 healthy controls and postcontrast sequences in 5 consecutive patients. Images were reviewed on a Likert-like scale by 4 fellowship-trained neuroradiologists. Scores (range, 1-4) were separately assigned for 11 vessel segments in terms of vessel wall and lumen delineation. Additionally, images were evaluated in terms of overall background noise, image sharpness, and homogeneous CSF signal. Segment-wise scores were compared using paired samples t tests.

Results: The scan time for the clinical and deep learning-based image reconstruction sequences were 7:26 minutes and 5:23 minutes respectively. Deep learning-based image reconstruction images showed consistently higher wall signal and lumen visualization scores, with the differences being statistically significant in most vessel segments on both pre- and postcontrast images. Deep learning-based image reconstruction had lower background noise, higher image sharpness, and uniform CSF signal. Depiction of intracranial pathologies was better or similar on the deep learning-based image reconstruction.

Conclusions: Our preliminary findings suggest that deep learning-based image reconstruction-optimized intracranial vessel wall imaging sequences may be helpful in achieving shorter gradient times with improved vessel wall visualization and overall image quality. These improvements may help with wider adoption of intracranial vessel wall imaging in clinical practice and should be further validated on a larger cohort.

基于深度学习的 3D-T1-SPACE 血管壁成像重构可在缩短扫描时间的同时提高图像质量:初步研究
背景和目的:颅内血管壁成像(IC-VWI)同时要求高空间分辨率、出色的血液和 CSF 信号抑制以及临床上可接受的梯度时间,因此在技术上具有挑战性。在此,我们将介绍利用 T1 加权成像对深度学习优化序列进行评估的初步结果:对临床和优化的基于深度学习的图像重建(DLBIR)T1 SPACE 序列进行了评估,比较了 10 名健康对照者的非对比序列和 5 名连续患者的对比后序列。图像由四名受过研究培训的神经放射科医生以李克特评分法进行审查。分别对 11 个血管节段的血管壁和管腔划分进行评分(范围 1-4)。此外,还对图像的整体背景噪声、图像清晰度和均匀的 CSF 信号进行了评估。采用配对样本 t 检验比较各分段的得分:临床和 DLBIR 序列的扫描时间分别为 7:26 分钟和 5:23 分钟。DLBIR 图像显示出更高的管壁信号和管腔可视化评分,在对比前和对比后图像的大多数血管节段中,差异均有统计学意义。DLBIR 图像的背景噪声较低,图像清晰度较高,CSF 信号均匀。DLBIR 图像对颅内病变的描绘更好或相似:我们的初步研究结果表明,DLBIR 优化 IC-VWI 序列有助于缩短梯度时间,改善血管壁的可视化和整体图像质量。这些改进可能有助于在临床实践中更广泛地采用 ICVWI,并应在更大的群体中进一步验证:缩写:DL 深度学习;VWI = 血管壁成像。
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