Compressed Sensing Reconstruction with Zero-Shot Self-Supervised Learning for High-Resolution MRI of Human Embryos.

IF 2.2 4区医学 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING

Tomography Pub Date : 2025-08-02 DOI:10.3390/tomography11080088

Kazuma Iwazaki, Naoto Fujita, Shigehito Yamada, Yasuhiko Terada

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引用次数: 0

Abstract

Objectives: This study investigates whether scan time in the high-resolution magnetic resonance imaging (MRI) of human embryos can be reduced without compromising spatial resolution by applying zero-shot self-supervised learning (ZS-SSL), a deep-learning-based reconstruction method. Methods: Simulations using a numerical phantom were conducted to evaluate spatial resolution across various acceleration factors (AF = 2, 4, 6, and 8) and signal-to-noise ratio (SNR) levels. Resolution was quantified using a blur-based estimation method based on the Sparrow criterion. ZS-SSL was compared to conventional compressed sensing (CS). Experimental imaging of a human embryo at Carnegie stage 21 was performed at a spatial resolution of (30 μm)³ using both retrospective and prospective undersampling at AF = 4 and 8. Results: ZS-SSL preserved spatial resolution more effectively than CS at low SNRs. At AF = 4, image quality was comparable to that of fully sampled data, while noticeable degradation occurred at AF = 8. Experimental validation confirmed these findings, with clear visualization of anatomical structures-such as the accessory nerve-at AF = 4; there was reduced structural clarity at AF = 8. Conclusions: ZS-SSL enables significant scan time reduction in high-resolution MRI of human embryos while maintaining spatial resolution at AF = 4, assuming an SNR above approximately 15. This trade-off between acceleration and image quality is particularly beneficial in studies with limited imaging time or specimen availability. The method facilitates the efficient acquisition of ultra-high-resolution data and supports future efforts to construct detailed developmental atlases.

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基于零点自监督学习的高分辨率人类胚胎MRI压缩感知重构。

目的：本研究探讨了采用基于深度学习的零间隔自监督学习（ZS-SSL）重建方法，能否在不影响空间分辨率的情况下减少人类胚胎高分辨率磁共振成像（MRI）的扫描时间。方法：采用数值模拟方法评估不同加速因子（AF = 2、4、6和8）和信噪比（SNR）水平下的空间分辨率。采用基于Sparrow准则的模糊估计方法对分辨率进行量化。将ZS-SSL与传统压缩感知（CS）进行了比较。在（30 μm）3的空间分辨率下，使用AF = 4和8时的回顾性和前瞻性欠采样对卡内基21期人类胚胎进行实验成像。结果：在低信噪比下，ZS-SSL比CS更有效地保留了空间分辨率。在AF = 4时，图像质量与完全采样的数据相当，而在AF = 8时出现明显的退化。实验验证证实了这些发现，在AF = 4时，解剖结构（如副神经）清晰可见；AF = 8时结构清晰度降低。结论：假设信噪比高于约15，ZS-SSL可以显著减少人类胚胎高分辨率MRI的扫描时间，同时保持AF = 4的空间分辨率。这种加速和图像质量之间的权衡在成像时间或标本可用性有限的研究中特别有益。该方法有助于高效获取超高分辨率数据，并为未来构建详细的开发地图集提供支持。

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

Tomography Medicine-Radiology, Nuclear Medicine and Imaging

CiteScore

2.70

自引率

10.50%

发文量

222

期刊介绍： TomographyTM publishes basic (technical and pre-clinical) and clinical scientific articles which involve the advancement of imaging technologies. Tomography encompasses studies that use single or multiple imaging modalities including for example CT, US, PET, SPECT, MR and hyperpolarization technologies, as well as optical modalities (i.e. bioluminescence, photoacoustic, endomicroscopy, fiber optic imaging and optical computed tomography) in basic sciences, engineering, preclinical and clinical medicine. Tomography also welcomes studies involving exploration and refinement of contrast mechanisms and image-derived metrics within and across modalities toward the development of novel imaging probes for image-based feedback and intervention. The use of imaging in biology and medicine provides unparalleled opportunities to noninvasively interrogate tissues to obtain real-time dynamic and quantitative information required for diagnosis and response to interventions and to follow evolving pathological conditions. As multi-modal studies and the complexities of imaging technologies themselves are ever increasing to provide advanced information to scientists and clinicians. Tomography provides a unique publication venue allowing investigators the opportunity to more precisely communicate integrated findings related to the diverse and heterogeneous features associated with underlying anatomical, physiological, functional, metabolic and molecular genetic activities of normal and diseased tissue. Thus Tomography publishes peer-reviewed articles which involve the broad use of imaging of any tissue and disease type including both preclinical and clinical investigations. In addition, hardware/software along with chemical and molecular probe advances are welcome as they are deemed to significantly contribute towards the long-term goal of improving the overall impact of imaging on scientific and clinical discovery.