Kaufman L, Kaufman J H, Wang J Z
Dept. of Psychology and Neural Science, New York University, NY 10003.
Electroencephalogr Clin Neurophysiol. 1991 Sep;79(3):211-26. doi: 10.1016/0013-4694(91)90139-u.
A folded cortical source of neuromagnetic fields, similar in configuration to the visual cortex, was simulated. Cortical activity was modelled by different distributions of independent current dipoles. The map of the summed fields of the dipoles of this cruciform model changed, depending upon the statistical distribution of the electrical activity of the dipoles and its geometry. Arrays of dipoles of random orientations and strengths produced field patterns that could be interpreted as due to moving neural currents, although the geometry of the neural tissue remained unchanged and the average activity remained approximately constant. The field topography at any instant was apparently unrelated to the depth or orientation of the underlying structure, thus raising questions about how to interpret topographic MEG and EEG displays. Furthermore, asynchronous activity (defined as independent directions and magnitudes of activity of the dipoles) did not result in less field power than when the dipoles were synchronized, i.e., when the direction of current flow was correlated across all of the dipoles within the cruciform structure. Therefore, in this model 'alpha blockage' cannot be mimicked by desynchronization. More generally, for the cruciform or any other symmetrically folded and active cortical sheet, 'blockage' cannot be attributed to desynchronization. The same is true for the EEG except that smooth unfolded sheets of radially oriented dipoles would result in enhancement of voltage due to synchronization. Such radial dipoles do not contribute to the MEG. Blockage was simulated by reducing the amount of activity within different portions of the synchronized cruciform model. This resulted in a dramatic increase in the net field because attenuation broke the symmetry of the synchronized cruciform structure. With asynchronous dipoles populating the structure, the attenuation of the same portion of the structure had no easily discerned effect on the net field. However, maps of average field power were consistently related to the position of the region of attenuated activity. The locations of regions of attenuated activity were determined by taking the difference between the mean square field pattern obtained when all portions of the cruciform structure were active and the pattern obtained when a portion of the structure was relatively inactive. When activity of the same portions were incremented rather than attenuated, the resulting plot of average power was essentially the same as that of the attenuated portion derived by taking these differences between power distributions. The major conclusions are that the concepts of synchronization and desynchronization have no explanatory power unless the physical conditions under which they occur are specified precisely.(ABSTRACT TRUNCATED AT 400 WORDS)
模拟了一个折叠的皮质神经磁场源,其结构与视觉皮质相似。皮质活动通过独立电流偶极子的不同分布进行建模。这个十字形模型的偶极子总和场图会发生变化,这取决于偶极子电活动的统计分布及其几何形状。随机取向和强度的偶极子阵列产生的场模式可以解释为是由移动的神经电流引起的,尽管神经组织的几何形状保持不变且平均活动大致恒定。任何时刻的场地形图显然与底层结构的深度或取向无关,这就引发了关于如何解释MEG和EEG地形图显示的问题。此外,异步活动(定义为偶极子活动的独立方向和大小)所产生的场功率并不比偶极子同步时(即十字形结构内所有偶极子的电流流动方向相关时)小。因此,在这个模型中,“α阻断”不能通过去同步来模拟。更一般地说,对于十字形或任何其他对称折叠且活跃的皮质薄片,“阻断”不能归因于去同步。脑电图也是如此,只是径向取向偶极子的平滑展开薄片会因同步而导致电压增强。这种径向偶极子对MEG没有贡献。通过减少同步十字形模型不同部分内的活动量来模拟阻断。这导致净场显著增加,因为衰减打破了同步十字形结构的对称性。当结构中填充异步偶极子时,结构相同部分的衰减对净场没有容易辨别的影响。然而,平均场功率图始终与活动衰减区域的位置相关。活动衰减区域的位置是通过计算十字形结构所有部分都活跃时获得的均方场模式与结构一部分相对不活跃时获得的模式之间的差异来确定的。当相同部分的活动增加而不是衰减时,得到的平均功率图与通过这些功率分布差异得出的衰减部分的图基本相同。主要结论是,除非精确指定同步和去同步发生的物理条件,否则它们的概念没有解释力。(摘要截断于400字)
