磁共振成像
工件(错误)
多层
核磁共振
医学
实时核磁共振成像
k-空间
图像分辨率
磁共振成像物理学
磁场
医学影像学
自旋回波
共振(粒子物理)
计算机科学
磁共振光谱成像
迭代重建
时间分辨率
磁共振显微术
磁共振力显微镜
介入性磁共振成像
加速度
医学物理学
放射科
临床前影像学
作者
Jan Vosshenrich,Iman Khodarahmi,Jan Fritz
出处
期刊:Seminars in Musculoskeletal Radiology
[Thieme Medical Publishers (Germany)]
日期:2026-05-12
摘要
Abstract: Musculoskeletal magnetic resonance imaging has evolved substantially, driven by advances in hardware, image acquisition, and reconstruction techniques. Improvements in gradient performance and dedicated radiofrequency coils have enhanced spatial resolution and scan efficiency across field strengths. Image acceleration strategies, including parallel imaging, simultaneous multislice acquisition, and compressed sensing, now enable high-quality two-dimensional and three-dimensional magnetic resonance imaging with markedly reduced examination times and facilitate the time-neutral incorporation of advanced metal artifact reduction techniques into clinical magnetic resonance imaging protocols. Abstract: Deep learning-based reconstruction and super-resolution augmentation methods have further expanded achievable acceleration and image quality. Emerging techniques such as synthetic magnetic resonance imaging, magnetic resonance neurography, kinematic magnetic resonance imaging, and zero echo time magnetic resonance imaging expand the capabilities of musculoskeletal magnetic resonance imaging. At the same time, renewed interest in low-field magnetic resonance imaging provides intriguing opportunities to improve accessibility and sustainability. Ultra-high field magnetic resonance imaging provides unprecedented spatial resolution and quantitative insights in selected applications. These developments are redefining musculoskeletal magnetic resonance imaging practice and broadening its clinical value.
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