扩散抑制传播:电化学模式如何扭曲或创造感知

V. M. F. Lima, Alfredo Pereira Junior, Guilherme Lima de Oliveira
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引用次数: 2

摘要

在离体视网膜中记录到的从静止到传播波的转变中,一个圆形电流在细胞外基质中闭合;这种圆形电流产生磁环流,当进入波前的静止组织时,吸收元素,当离开时,有助于建立绝对难熔状态。波动磁环是涡旋效应的结果,并解释了驱动传播的能量提升。方法:我们对实验结果进行了解释,这些实验结果来自于内源性和外源性荧光染料,电压,钙和pH敏感,来自分离视网膜的光信号,以及使用离子交换树脂的时间序列记录:Ca, K, pH, Na, Cl在视网膜,小脑和皮层的细胞外记录,与传播的抑郁波耦合。最后,我们检查了大鼠海马从放电后到扩散性抑郁过渡时期的ECoG活动,也是一个时间序列。结果:综合评价各种测量结果,认识到波前磁流是波传播机制的主要贡献者。这种流动耦合了质量和电荷的流动,形成一个从激发态组织到静止组织的旋转环。结论:除了经典的HH和分子生物学模型外,可能还有另一种大脑模型。带电凝胶及其流动的物理化学解释了这一结果。其概念框架采用了远离平衡态的热力学。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The Spreading Depression Propagation: How Electrochemical Patterns Distort or Create Perception
At the transition from quiescence to propagating waves recorded in isolated retinas, a circular electric current closes in the extracellular matrix; this circular current creates a magnetic torus flow that, when entering quiescent tissue in front of the wave, recruits elements and when leaving behind, helps to build the absolute refractory state. The waving magnetic torus is the consequence of the vortex effect and explains the energy boost that drives propagation. Methods: We interpret experimental results from intrinsic and extrinsic fluorescence dyes, voltage, calcium and pH sensitive, optical signals from isolated retinas, and time series recordings using ion exchange resins: Ca, K, pH, Na, Cl recorded extracellularly at retinas, cerebellums and cortices coupled to spreading depression waves. Finally, we checked the ECoG activity, also a time series, at the transition from after discharges to spreading depression in rat hippocampus. Results: The integrated assessment of the diversified measurements led to the realization that the magnetic flow at the wavefront is a major contributor to the wave propagation mechanisms. This flow couples mass and charge flows as a swirling torus from excited to quiescent tissue. Conclusions: An alternative model of the brain is possible, apart from the classical HH and molecular biology model. Physical chemistry of charged gels and its flows explains the results. The conceptual framework uses far from equilibrium thermodynamics.
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