Investigation of Electrical Conductivity Changes during Brain Functional Activity in 3T MRI

Kyu-Jin Jung, Chuanjiang Cui, Soo-Hyung Lee, Chan-Hee Park, Ji-Won Chun, Dong-Hyun Kim
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Abstract

Blood oxygenation level-dependent (BOLD) functional magnetic resonance imaging (fMRI) is widely used to visualize brain activation regions by detecting hemodynamic responses associated with increased metabolic demand. While alternative MRI methods have been employed to monitor functional activities, the investigation of in-vivo electrical property changes during brain function remains limited. In this study, we explored the relationship between fMRI signals and electrical conductivity (measured at the Larmor frequency) changes using phase-based electrical properties tomography (EPT). Our results revealed consistent patterns: conductivity changes showed negative correlations, with conductivity decreasing in the functionally active regions whereas B1 phase mapping exhibited positive correlations around activation regions. These observations were consistent across both motor and visual cortex activations. To further substantiate these findings, we conducted electromagnetic radio-frequency simulations that modeled activation states with varying conductivity, which demonstrated trends similar to our in-vivo results for both B1 phase and conductivity. These findings suggest that in-vivo electrical conductivity changes can indeed be measured during brain activity. However, further investigation is needed to fully understand the underlying mechanisms driving these measurements.
通过 3T 磁共振成像研究大脑功能活动时的电导率变化
血液氧合水平依赖性(BOLD)功能磁共振成像(fMRI)被广泛用于通过检测与代谢需求增加相关的血流动力学反应来观察大脑激活区域。虽然已经采用了其他磁共振成像方法来监测功能活动,但对脑功能过程中体内电特性变化的研究仍然有限。在这项研究中,我们利用基于相位的电特性断层扫描(EPT)探索了 fMRI 信号与电导率(以拉莫夫频率测量)变化之间的关系。我们的结果揭示了一致的模式:电导率变化呈现负相关,在功能活跃区域电导率下降,而 B1 相位图在激活区域周围呈现正相关。这些观察结果在运动和视觉皮层活动中都是一致的。为了进一步证实这些发现,我们进行了电磁射频模拟,模拟了电导率变化时的激活状态,结果显示 B1 相位和电导率的变化趋势与体内结果相似。这些研究结果表明,体内电导率的变化确实可以在大脑活动过程中测量到。
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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