基于深度学习重建的薄切片二维 T2 加权成像：改善多发性硬化症患者脑内病变的检测。

Thin-slice Two-dimensional T2-weighted Imaging with Deep Learning-based Reconstruction: Improved Lesion Detection in the Brain of Patients with Multiple Sclerosis.

机构信息

Department of Radiology, Hirosaki University Graduate School of Medicine.

Department of Radiology, Aomori Prefectural Central Hospital.

出版信息

Magn Reson Med Sci. 2024 Apr 1;23(2):184-192. doi: 10.2463/mrms.mp.2022-0112. Epub 2023 Mar 16.

DOI:10.2463/mrms.mp.2022-0112

PMID:36927877

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11024714/

Abstract

PURPOSE

Brain MRI with high spatial resolution allows for a more detailed delineation of multiple sclerosis (MS) lesions. The recently developed deep learning-based reconstruction (DLR) technique enables image denoising with sharp edges and reduced artifacts, which improves the image quality of thin-slice 2D MRI. We, therefore, assessed the diagnostic value of 1 mm-slice-thickness 2D T2-weighted imaging (T2WI) with DLR (1 mm T2WI with DLR) compared with conventional MRI for identifying MS lesions.

METHODS

Conventional MRI (5 mm T2WI, 2D and 3D fluid-attenuated inversion recovery) and 1 mm T2WI with DLR (imaging time: 7 minutes) were performed in 42 MS patients. For lesion detection, two neuroradiologists counted the MS lesions in two reading sessions (conventional MRI interpretation with 5 mm T2WI and MRI interpretations with 1 mm T2WI with DLR). The numbers of lesions per region category (cerebral hemisphere, basal ganglia, brain stem, cerebellar hemisphere) were then compared between the two reading sessions.

RESULTS

For the detection of MS lesions by 2 neuroradiologists, the total number of detected MS lesions was significantly higher for MRI interpretation with 1 mm T2WI with DLR than for conventional MRI interpretation with 5 mm T2WI (765 lesions vs. 870 lesions at radiologist A, < 0.05). In particular, of the 33 lesions in the brain stem, radiologist A detected 21 (63.6%) additional lesions by 1 mm T2WI with DLR.

CONCLUSION

Using the DLR technique, whole-brain 1 mm T2WI can be performed in about 7 minutes, which is feasible for routine clinical practice. MRI with 1 mm T2WI with DLR enabled increased MS lesion detection, particularly in the brain stem.

摘要

目的

高空间分辨率的脑部 MRI 可更详细地区分多发性硬化症（MS）病变。最近开发的基于深度学习的重建（DLR）技术可实现具有锐利边缘和减少伪影的图像去噪，从而提高薄层 2D MRI 的图像质量。因此，我们评估了基于 DLR 的 1 毫米切片厚度 2D T2 加权成像（T2WI）（1 毫米 T2WI 与 DLR）与常规 MRI 相比在识别 MS 病变方面的诊断价值。

方法

对 42 例 MS 患者进行常规 MRI（5 毫米 T2WI、2D 和 3D 液体衰减反转恢复）和 1 毫米 T2WI 与 DLR（成像时间：7 分钟）检查。为了检测病变，两位神经放射科医生在两次阅读会议中对 MS 病变进行计数（常规 MRI 解释为 5 毫米 T2WI 和 MRI 解释为 1 毫米 T2WI 与 DLR）。然后比较两次阅读会议中每个区域类别的病变数量（大脑半球、基底节、脑干、小脑半球）。

结果

对于两位神经放射科医生对 MS 病变的检测，使用 1 毫米 T2WI 与 DLR 的 MRI 解释检测到的 MS 病变总数明显高于使用 5 毫米 T2WI 的常规 MRI 解释（放射科医生 A 为 765 个病变与 870 个病变，<0.05）。特别是在脑干中的 33 个病变中，放射科医生 A 通过 1 毫米 T2WI 与 DLR 检测到 21 个（63.6%）额外的病变。

结论

使用 DLR 技术，大约 7 分钟即可完成全脑 1 毫米 T2WI，这对于常规临床实践是可行的。使用 1 毫米 T2WI 与 DLR 的 MRI 可提高 MS 病变的检出率，特别是在脑干中。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/a574/11024714/e910886f7b3e/mrms-23-184-g1.jpg

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基于深度学习重建的薄切片二维 T2 加权成像：改善多发性硬化症患者脑内病变的检测。

Thin-slice Two-dimensional T2-weighted Imaging with Deep Learning-based Reconstruction: Improved Lesion Detection in the Brain of Patients with Multiple Sclerosis.

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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