Reliability of brain volume measures of accelerated 3D T1-weighted images with deep learning-based reconstruction.

IF 2.4 3区医学 Q2 CLINICAL NEUROLOGY Neuroradiology Pub Date : 2025-01-01 Epub Date: 2024-09-24 DOI:10.1007/s00234-024-03461-5

Woojin Jung, Geunu Jeong, Sohyun Kim, Inpyeong Hwang, Seung Hong Choi, Young Hun Jeon, Kyu Sung Choi, Ji Ye Lee, Roh-Eul Yoo, Tae Jin Yun, Koung Mi Kang

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Abstract

Purpose: The time-intensive nature of acquiring 3D T1-weighted MRI and analyzing brain volumetry limits quantitative evaluation of brain atrophy. We explore the feasibility and reliability of deep learning-based accelerated MRI scans for brain volumetry.

Methods: This retrospective study collected 3D T1-weighted data using 3T from 42 participants for the simulated acceleration dataset and 48 for the validation dataset. The simulated acceleration dataset consists of three sets at different simulated acceleration levels (Simul-Accel) corresponding to level 1 (65% undersampling), 2 (70%), and 3 (75%). These images were then subjected to deep learning-based reconstruction (Simul-Accel-DL). Conventional images (Conv) without acceleration and DL were set as the reference. In the validation dataset, DICOM images were collected from Conv and accelerated scan with DL-based reconstruction (Accel-DL). The image quality of Simul-Accel-DL was evaluated using quantitative error metrics. Volumetric measurements were evaluated using intraclass correlation coefficients (ICCs) and linear regression analysis in both datasets. The volumes were estimated by two software, NeuroQuant and DeepBrain.

Results: Simul-Accel-DL across all acceleration levels revealed comparable or better error metrics than Simul-Accel. In the simulated acceleration dataset, ICCs between Conv and Simul-Accel-DL in all ROIs exceeded 0.90 for volumes and 0.77 for normative percentiles at all acceleration levels. In the validation dataset, ICCs for volumes > 0.96, ICCs for normative percentiles > 0.89, and R² > 0.93 at all ROIs except pallidum demonstrated good agreement in both software.

Conclusion: DL-based reconstruction achieves clinical feasibility of 3D T1 brain volumetric MRI by up to 75% acceleration relative to full-sampled acquisition.

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基于深度学习重建的加速三维 T1 加权图像脑容量测量的可靠性。

目的：获取三维 T1 加权磁共振成像并分析脑容量的时间密集性限制了对脑萎缩的定量评估。我们探索了基于深度学习的加速 MRI 扫描用于脑容量测量的可行性和可靠性：这项回顾性研究使用 3T 采集了 42 名参与者的三维 T1 加权数据用于模拟加速数据集，48 名参与者的数据用于验证数据集。模拟加速度数据集由不同模拟加速度级别（Simul-Accel）的三组数据组成，分别对应级别 1（65% 欠采样）、级别 2（70%）和级别 3（75%）。然后对这些图像进行基于深度学习的重建（Simul-Accel-DL）。没有加速和 DL 的常规图像（Conv）被设为参考。在验证数据集中，DICOM 图像来自 Conv 和基于 DL 重建的加速扫描（Accel-DL）。使用定量误差指标对 Simul-Accel-DL 的图像质量进行了评估。使用类内相关系数（ICC）和线性回归分析对两个数据集的容积测量进行评估。体积由 NeuroQuant 和 DeepBrain 两款软件估算：在所有加速度水平上，Simul-Accel-DL 都显示出与 Simul-Accel 相当或更好的误差指标。在模拟加速度数据集中，Conv 和 Simul-Accel-DL 在所有加速度级别的所有 ROI 中，体积的 ICC 超过 0.90，标准百分位数的 ICC 超过 0.77。在验证数据集中，体积的 ICC > 0.96，标准百分位数的 ICC > 0.89，除苍白球外所有 ROI 的 R2 > 0.93，这表明两种软件的一致性都很好：结论：基于 DL 的重建实现了三维 T1 脑容积磁共振成像的临床可行性，与全采样采集相比，加速高达 75%。

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来源期刊

Neuroradiology 医学-核医学

CiteScore

5.30

自引率

3.60%

发文量

214

审稿时长

4-8 weeks

期刊介绍： Neuroradiology aims to provide state-of-the-art medical and scientific information in the fields of Neuroradiology, Neurosciences, Neurology, Psychiatry, Neurosurgery, and related medical specialities. Neuroradiology as the official Journal of the European Society of Neuroradiology receives submissions from all parts of the world and publishes peer-reviewed original research, comprehensive reviews, educational papers, opinion papers, and short reports on exceptional clinical observations and new technical developments in the field of Neuroimaging and Neurointervention. The journal has subsections for Diagnostic and Interventional Neuroradiology, Advanced Neuroimaging, Paediatric Neuroradiology, Head-Neck-ENT Radiology, Spine Neuroradiology, and for submissions from Japan. Neuroradiology aims to provide new knowledge about and insights into the function and pathology of the human nervous system that may help to better diagnose and treat nervous system diseases. Neuroradiology is a member of the Committee on Publication Ethics (COPE) and follows the COPE core practices. Neuroradiology prefers articles that are free of bias, self-critical regarding limitations, transparent and clear in describing study participants, methods, and statistics, and short in presenting results. Before peer-review all submissions are automatically checked by iThenticate to assess for potential overlap in prior publication.