COMPLEX-VALUED PHASE SYNCHRONY REVEALS DIRECTIONAL COUPLING IN FMRI AND TRACKS MEDICATION EFFECTS.

ArXiv Pub Date : 2025-09-16

Sir-Lord Wiafe, Najme Soleimani, Masoud Seraji, Bradley Baker, Robyn Miller, Ashkan Faghiri, Vince D Calhoun

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Abstract

Understanding interactions in complex systems requires capturing the directionality of coupling, not only its strength. Phase synchronization captures this timing, yet most methods either reduce phase to its cosine or collapse it into scalar indices such as the phase-locking value, discarding directionality. We propose a complex-valued phase synchrony (CVPS) framework that estimates phase with an adaptive Gabor wavelet and preserves both cosine and sine components. Simulations confirm that CVPS recovers true phase offsets and tracks non-stationary dynamics more faithfully than Hilbert-based methods. Because antipsychotics are known to modulate the timing of cortical interactions, they provide a rigorous context to evaluate whether CVPS can capture such pharmacological effects. CVPS further reveals cortical neuro-hemodynamic drivers, with occipital-to-parietal and prefrontal-to-striatal lead-lag flows consistent with known receptor targets, confirming its ability to capture pharmacological timing. CVPS, therefore, offers a robust and generalizable framework for detecting directional coupling in complex systems such as the brain.

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复值相位同步揭示了FMRI中的定向耦合并跟踪了药物效应。

理解复杂系统中的相互作用需要捕捉耦合的方向性，而不仅仅是它的强度。相位同步捕获了这个时间，然而大多数方法要么将相位减少到余弦值，要么将其分解为标量指数，如锁相值，从而丢弃方向性。我们提出了一种复值相位同步（CVPS）框架，该框架使用自适应Gabor小波估计相位并保留余弦和正弦分量。仿真结果表明，与基于hilbert的方法相比，CVPS可以更准确地恢复真实的相位偏移并跟踪非平稳动态。因为已知抗精神病药物可以调节皮质相互作用的时间，它们提供了一个严格的背景来评估CVPS是否可以捕获这种药理作用。CVPS进一步揭示了皮质神经血流动力学驱动因素，枕叶到顶叶和前额叶到纹状体的超前-滞后流动与已知受体靶点一致，证实了其捕捉药理时间的能力。因此，CVPS为检测复杂系统（如大脑）中的定向耦合提供了一个鲁棒且可推广的框架。

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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