多回波采集和热去噪技术促进婴儿精密功能成像。

Julia Moser, Steven M Nelson, Sanju Koirala, Thomas J Madison, Alyssa K Labonte, Cristian Morales Carrasco, Eric Feczko, Lucille A Moore, Jacob T Lundquist, Kimberly B Weldon, Gracie Grimsrud, Kristina Hufnagle, Weli Ahmed, Michael J Myers, Babatunde Adeyemo, Abraham Z Snyder, Evan M Gordon, Nico U F Dosenbach, Brenden Tervo-Clemmens, Bart Larsen, Steen Moeller, Essa Yacoub, Luca Vizioli, Kamil Uğurbil, Timothy O Laumann, Chad M Sylvester, Damien A Fair
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引用次数: 0

摘要

近年来,精确功能映射对个体功能脑组织的表征为成人提供了重要的见解。然而,关于人类发育过程中大脑功能组织的个体间差异的个体发生知之甚少,但在高可塑性时期对系统组织的精确描述可能对促进终身健康的发现最有影响。收集和分析早期发育过程中精确的fMRI数据具有独特的挑战,并强调了新方法的重要性,以改善婴儿样本的数据采集,处理和分析策略。在这里,我们研究了来自成人MRI研究的两种方法,多回波(ME)数据采集和热噪声去除与分布校正主成分分析(NORDIC)的降噪,在三个新生儿的精确fMRI数据中的适用性。与成人受试者相比,从婴儿的ME数据计算出的T2*放松时间更长,整个大脑的变化也更大,这表明ME获取是优化发育性fMRI的一个有前途的工具。通过NORDIC进行的热去噪提高了婴儿ME数据的tSNR和功能连接的总体强度,以及功能连接矩阵的劈裂半可靠性。虽然我们的研究结果与成人文献一致,并且ME数据采集显示出很高的前景,但其在发育样本中的应用需要进一步研究。目前的工作揭示了我们对发育性脑成像最佳技术的理解差距,并强调了进一步发展特定的方法进步和优化的必要性,以实现婴儿的精确功能成像。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Multi-echo Acquisition and Thermal Denoising Advances Precision Functional Imaging.

The characterization of individual functional brain organization with Precision Functional Mapping has provided important insights in recent years in adults. However, little is known about the ontogeny of inter-individual differences in brain functional organization during human development. Precise characterization of systems organization during periods of high plasticity is likely to be essential for discoveries promoting lifelong health. Obtaining precision fMRI data during development has unique challenges that highlight the importance of establishing new methods to improve data acquisition, processing, and analysis. Here, we investigate two methods that can facilitate attaining this goal: multi-echo (ME) data acquisition and thermal noise removal with Noise Reduction with Distribution Corrected (NORDIC) principal component analysis. We applied these methods to precision fMRI data from adults, children, and newborn infants. In adults, both ME acquisitions and NORDIC increased temporal signal to noise ratio (tSNR) as well as the split-half reliability of functional connectivity matrices, with the combination helping more than either technique alone. The benefits of NORDIC denoising replicated in both our developmental samples. ME acquisitions revealed longer and more variable T2* relaxation times across the brain in infants relative to older children and adults, leading to major differences in the echo weighting for optimally combining ME data. This result suggests ME acquisitions may be a promising tool for optimizing developmental fMRI, albeit application in infants needs further investigation. The present work showcases methodological advances that improve Precision Functional Mapping in adults and developmental populations and, at the same time, highlights the need for further improvements in infant specific fMRI.

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