小尺寸、高性能、头部专用0.5T扫描仪上几何畸变的表征及不同扫描仪间的可重复性

Characterization and inter-scanner reproducibility of geometric distortion on a small footprint, high-performance, head-specific 0.5 T scanner.

作者信息

Wiens Curtis N, Harris Chad T, Connell Ian R O

机构信息

Research and Development, Synaptive Medical, Toronto, Canada.

Department of Medical Biophysics, University of Toronto, Toronto, Canada.

出版信息

Med Phys. 2025 Jun;52(6):4598-4604. doi: 10.1002/mp.17789. Epub 2025 Mar 29.

DOI:10.1002/mp.17789

PMID:40156302

Abstract

BACKGROUND

Magnetic resonance imaging (MRI) offers superior soft tissue contrast and essential imaging capabilities for modern medicine. MRI is increasingly being used in applications that require a high degree of spatial fidelity; however, distortions are a well-known limitation of the modality. The mid-field (0.3 T ≤ B < 1 T) has advantages in this respect due to being less susceptible to patient-induced distortions.

PURPOSE

The purpose of this work was to characterize the geometric fidelity of a short-bore, head-specific, 0.5T MRI system.

METHODS

Assessment of spatial fidelity was performed using a 3D gradient recalled echo (GRE) acquisition on a commercial distortion phantom using the validated distortion analysis software provided. B-induced distortions were measured using a 3D field map. Inter-scanner reproducibility was assessed across four distinct systems of identical make and model, while intra-scanner repeatability was assessed at one site over six repeat measurements.

RESULTS

Inter-scanner reproducibility measured an average 95th percentile distortion over 100 and 180 mm DSV of 0.15 ± 0.03 and 0.33 ± 0.05 mm. Average 95th percentile distortions due to B field inhomogeneities over 100 and 180 mm DSV were 0.02 ± 0.01 and 0.07 ± 0.02 mm. Intra-scanner repeatability measured the uncertainty in distortion values to be 0.020 ± 0.005 mm.

CONCLUSION

The total residual distortions measured in this phantom study were less than half the recommended value required for radiosurgery and significantly better than data published from other MR systems. This demonstrates that in addition to the compact footprint of the Synaptive 0.5T scanner, it exceeds current standards for geometric accuracy.

摘要

背景

磁共振成像（MRI）为现代医学提供了卓越的软组织对比度和重要的成像能力。MRI越来越多地用于需要高度空间保真度的应用中；然而，失真是该模态众所周知的局限性。中场（0.3 T≤B＜1 T）在这方面具有优势，因为它不太容易受到患者引起的失真影响。

目的

本研究的目的是表征一款短孔径、头部专用的0.5T MRI系统的几何保真度。

方法

使用经过验证的失真分析软件，在商用失真模型上通过3D梯度回波（GRE）采集来评估空间保真度。使用3D场图测量B场引起的失真。在四个相同品牌和型号的不同系统之间评估扫描仪间的可重复性，同时在一个部位进行六次重复测量来评估扫描仪内的重复性。

结果

在100和180 mm的视野直径（DSV）上，扫描仪间可重复性测量的第95百分位数平均失真分别为0.15±0.03和0.33±0.05 mm。在100和180 mm DSV上，由于B场不均匀性导致的第95百分位数平均失真分别为0.02±0.01和0.07±0.02 mm。扫描仪内重复性测量的失真值不确定性为0.020±0.005 mm。

结论

在该模型研究中测得的总残余失真小于放射外科手术推荐值的一半，且明显优于其他MR系统公布的数据。这表明，除了Synaptive 0.5T扫描仪紧凑的占地面积外，其几何精度也超过了当前标准。

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小尺寸、高性能、头部专用0.5T扫描仪上几何畸变的表征及不同扫描仪间的可重复性

Characterization and inter-scanner reproducibility of geometric distortion on a small footprint, high-performance, head-specific 0.5 T scanner.

作者信息

机构信息

出版信息

BACKGROUND

PURPOSE

METHODS

RESULTS

CONCLUSION

背景

目的

方法

结果

结论

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