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3 分钟内的三个对比:用于颅面成像的快速、高分辨率和骨选择性 UTE MRI 与自动深度学习颅骨分割。

Three contrasts in 3 min: Rapid, high-resolution, and bone-selective UTE MRI for craniofacial imaging with automated deep-learning skull segmentation.

机构信息

Department of Radiology, Perelman School of Medicine, University of Pennsylvania, Philadelphia, Pennsylvania, USA.

Department of Bioengineering, School of Engineering and Applied Sciences, University of Pennsylvania, Philadelphia, Pennsylvania, USA.

出版信息

Magn Reson Med. 2025 Jan;93(1):245-260. doi: 10.1002/mrm.30275. Epub 2024 Sep 1.

DOI:10.1002/mrm.30275
PMID:39219299
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11735049/
Abstract

PURPOSE

Ultrashort echo time (UTE) MRI can be a radiation-free alternative to CT for craniofacial imaging of pediatric patients. However, unlike CT, bone-specific MR imaging is limited by long scan times, relatively low spatial resolution, and a time-consuming bone segmentation workflow.

METHODS

A rapid, high-resolution UTE technique for brain and skull imaging in conjunction with an automatic segmentation pipeline was developed. A dual-RF, dual-echo UTE sequence was optimized for rapid scan time (3 min) and smaller voxel size (0.65 mm). A weighted least-squares conjugate gradient method for computing the bone-selective image improves bone specificity while retaining bone sensitivity. Additionally, a deep-learning U-Net model was trained to automatically segment the skull from the bone-selective images. Ten healthy adult volunteers (six male, age 31.5 ± 10 years) and three pediatric patients (two male, ages 12 to 15 years) were scanned at 3 T. Clinical CT for the three patients were obtained for validation. Similarities in 3D skull reconstructions relative to clinical standard CT were evaluated based on the Dice similarity coefficient and Hausdorff distance. Craniometric measurements were used to assess geometric accuracy of the 3D skull renderings.

RESULTS

The weighted least-squares method produces images with enhanced bone specificity, suppression of soft tissue, and separation from air at the sinuses when validated against CT in pediatric patients. Dice similarity coefficient overlap was 0.86 ± 0.05, and the 95th percentile Hausdorff distance was 1.77 ± 0.49 mm between the full-skull binary masks of the optimized UTE and CT in the testing dataset.

CONCLUSION

An optimized MRI acquisition, reconstruction, and segmentation workflow for craniofacial imaging was developed.

摘要

目的

超短回波时间(UTE)MRI 可以作为小儿患者颅面成像的一种无辐射替代 CT 方法。然而,与 CT 不同,骨特异性 MRI 成像受到扫描时间长、空间分辨率相对较低以及耗时的骨分割工作流程的限制。

方法

开发了一种用于脑和颅骨成像的快速、高分辨率 UTE 技术,并结合了自动分割流水线。双射频、双回波 UTE 序列经过优化,以实现快速扫描时间(3 分钟)和较小的体素尺寸(0.65mm)。用于计算骨选择性图像的加权最小二乘共轭梯度法提高了骨特异性,同时保留了骨灵敏度。此外,还训练了一个深度学习 U-Net 模型,用于自动从骨选择性图像中分割颅骨。在 3T 下对 10 名健康成年志愿者(6 名男性,年龄 31.5±10 岁)和 3 名儿科患者(2 名男性,年龄 12 至 15 岁)进行扫描。为了验证,为这 3 名患者获取了临床 CT。根据 Dice 相似系数和 Hausdorff 距离评估 3D 颅骨重建与临床标准 CT 的相似性。使用头测量法评估 3D 颅骨渲染的几何精度。

结果

与 CT 相比,加权最小二乘法生成的图像在验证时具有增强的骨特异性、软组织抑制和窦腔空气分离。在测试数据集的优化 UTE 和 CT 的全颅骨二值掩模之间,Dice 相似系数重叠为 0.86±0.05,95%的 Hausdorff 距离为 1.77±0.49mm。

结论

开发了一种用于颅面成像的优化 MRI 采集、重建和分割工作流程。