Deep Learning Reconstruction of Accelerated MRI: False-Positive Cartilage Delamination Inserted in MRI Arthrography Under Traction.

Q2 Medicine

Topics in Magnetic Resonance Imaging Pub Date : 2024-07-12 eCollection Date: 2024-08-01 DOI:10.1097/RMR.0000000000000313

Wolfram A Bosbach, Kim Carolin Merdes, Bernd Jung, Elham Montazeri, Suzanne Anderson, Milena Mitrakovic, Keivan Daneshvar

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引用次数: 0

Abstract

Objectives: The radiological imaging industry is developing and starting to offer a range of novel artificial intelligence software solutions for clinical radiology. Deep learning reconstruction of magnetic resonance imaging data seems to allow for the acceleration and undersampling of imaging data. Resulting reduced acquisition times would lead to greater machine utility and to greater cost-efficiency of machine operations.

Materials and methods: Our case shows images from magnetic resonance arthrography under traction of the right hip joint from a 30-year-old, otherwise healthy, male patient.

Results: The undersampled image data when reconstructed by a deep learning tool can contain false-positive cartilage delamination and false-positive diffuse cartilage defects.

Conclusions: In the future, precision of this novel technology will have to be put to thorough testing. Bias of systems, in particular created by the choice of training data, will have to be part of those assessments.

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加速磁共振成像的深度学习重建：牵引下核磁共振关节造影中插入的假阳性软骨分层。

目的：放射成像行业正在开发并开始为临床放射学提供一系列新型人工智能软件解决方案。磁共振成像数据的深度学习重建似乎可以加速成像数据的采样和采样不足。由此缩短的采集时间将提高机器的实用性和机器运行的成本效益：我们的病例显示的是一名 30 岁、身体健康的男性患者右髋关节牵引下的磁共振关节造影图像：结果：深度学习工具对采样不足的图像数据进行重建时，可能会出现假阳性软骨分层和假阳性弥漫性软骨缺损：今后，必须对这项新技术的精确性进行全面测试。系统的偏差，尤其是由训练数据的选择造成的偏差，必须成为这些评估的一部分。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Topics in Magnetic Resonance Imaging Medicine-Medicine (all)

CiteScore

5.50

自引率

0.00%

发文量

期刊介绍： Topics in Magnetic Resonance Imaging is a leading information resource for professionals in the MRI community. This publication supplies authoritative, up-to-the-minute coverage of technical advances in this evolving field as well as practical, hands-on guidance from leading experts. Six times a year, TMRI focuses on a single timely topic of interest to radiologists. These topical issues present a variety of perspectives from top radiological authorities to provide an in-depth understanding of how MRI is being used in each area.