通过约束数值优化实现张量值扩散编码的运动补偿梯度波形

Motion-compensated gradient waveforms for tensor-valued diffusion encoding by constrained numerical optimization.

作者信息

Szczepankiewicz Filip, Sjölund Jens, Dall'Armellina Erica, Plein Sven, Schneider Jürgen E, Teh Irvin, Westin Carl-Fredrik

机构信息

Harvard Medical School, Boston, Massachusetts, USA.

Radiology, Brigham and Women's Hospital, Boston, Massachusetts, USA.

出版信息

Magn Reson Med. 2021 Apr;85(4):2117-2126. doi: 10.1002/mrm.28551. Epub 2020 Oct 13.

DOI:10.1002/mrm.28551

PMID:33048401

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7821235/

Abstract

PURPOSE

Diffusion-weighted MRI is sensitive to incoherent tissue motion, which may confound the measured signal and subsequent analysis. We propose a "motion-compensated" gradient waveform design for tensor-valued diffusion encoding that negates the effects bulk motion and incoherent motion in the ballistic regime.

METHODS

Motion compensation was achieved by constraining the magnitude of gradient waveform moment vectors. The constraint was incorporated into a numerical optimization framework, along with existing constraints that account for b-tensor shape, hardware restrictions, and concomitant field gradients. We evaluated the efficacy of encoding and motion compensation in simulations, and we demonstrated the approach by linear and planar b-tensor encoding in a healthy heart in vivo.

RESULTS

The optimization framework produced asymmetric motion-compensated waveforms that yielded b-tensors of arbitrary shape with improved efficiency compared with previous designs for tensor-valued encoding, and equivalent efficiency to previous designs for linear (conventional) encoding. Technical feasibility was demonstrated in the heart in vivo, showing vastly improved data quality when using motion compensation. The optimization framework is available online in open source.

CONCLUSION

Our gradient waveform design is both more flexible and efficient than previous methods, facilitating tensor-valued diffusion encoding in tissues in which motion would otherwise confound the signal. The proposed design exploits asymmetric encoding times, a single refocusing pulse or multiple refocusing pulses, and integrates compensation for concomitant gradient effects throughout the imaging volume.

摘要

目的

扩散加权磁共振成像（MRI）对非相干组织运动敏感，这可能会混淆测量信号及后续分析。我们提出一种用于张量值扩散编码的“运动补偿”梯度波形设计，该设计可消除弹道状态下的体运动和非相干运动的影响。

方法

通过约束梯度波形矩向量的大小来实现运动补偿。该约束与考虑b张量形状、硬件限制和伴随场梯度的现有约束一起纳入数值优化框架。我们在模拟中评估了编码和运动补偿的效果，并通过对健康心脏进行体内线性和平面b张量编码展示了该方法。

结果

优化框架产生了不对称的运动补偿波形，与先前的张量值编码设计相比，其能以更高的效率生成任意形状的b张量，且与先前的线性（传统）编码设计效率相当。在心脏体内证明了技术可行性，表明使用运动补偿时数据质量有大幅提高。优化框架可在开源网站上获取。

结论

我们的梯度波形设计比以前的方法更灵活、更高效，便于在运动否则会混淆信号的组织中进行张量值扩散编码。所提出的设计利用了不对称编码时间、单个重聚焦脉冲或多个重聚焦脉冲，并在整个成像体积中整合了对伴随梯度效应的补偿。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/952b/7821235/a63f88514ded/MRM-85-2117-g001.jpg

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通过约束数值优化实现张量值扩散编码的运动补偿梯度波形

Motion-compensated gradient waveforms for tensor-valued diffusion encoding by constrained numerical optimization.

作者信息

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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