Bullock T H, McClune M C, Achimowicz J Z, Iragui-Madoz V J, Duckrow R B, Spencer S S
Department of Neurosciences, University of California, San Diego, La Jolla 92093-0201, USA.
Electroencephalogr Clin Neurophysiol. 1995 Sep;95(3):161-77. doi: 10.1016/0013-4694(95)93347-a.
Subdural recordings from 8 patients and depth recordings from 3 patients via rows of electrodes with 5-10 mm spacing were searched for signs of significant local differentiation of coherence calculated between all possible pairs of loci. EEG samples of 2-4 min were taken during 4 states: alertness, stage 2-3 sleep, light surgical anesthesia permitting the patient to respond to questions and electrical seizures. Coherence was computed for all frequencies from 1 to 50 Hz or 0.3-100 Hz; for comparisons the mean coherence over each of 6 or 7 narrower bands between 2 and 70 Hz was used. Whereas the literature supports the view that EEG coherence is usually substantial over many centimeters, the hypothesis here tested--and found to be well above stochastic expectations--is that significant structure occurs in the millimeter domain for EEG recorded subdurally or within the brain. In both the subdural surface samples and those from temporal lobe depth electrode arrays coherence declines with distance between electrodes of the pair, on the average quite severely in millimeters. This is nearly the same for all frequency bands. For middle bands like 8-13 and 13-20 Hz, mean coherence typically declines most steeply in the first 10 mm, from values indistinguishable from 1.0 at < 0.5 mm distance to 0.5 at 5-10 mm and to 0.25 in another 10-20 mm in the subdural surface data. Temporal lobe depth estimates decline about half as fast; coherence > or = 0.5 extends for 9-20 mm and > or = 0.25 for another 20-35mm. Low frequency bands (1-5, 5-8 Hz) usually fall slightly more slowly than high frequency bands (20-35, 35-50 Hz but the difference is small and variance large. The steepness of decline with distance in humans is significantly but only slightly smaller than that we reported earlier for the rabbit and rat, averaging less than one half. Local coherence, for individual pairs of loci, shows differentiation in the millimeter range, i.e., nearest neighbor pairs may be locally well above or below average and this is sustained over minutes. Local highs and lows tend to be similar for widely different frequency bands. Coherence varies quite independently of power, although they are sometimes correlated. Regional differentiation is statistically significant in average coherence among pairs of loci on temporal vs frontal cortex or lateral frontal vs. subfrontal strips in the same patient, but such differences are usually small.(ABSTRACT TRUNCATED AT 400 WORDS)
对8例患者的硬膜下记录以及3例患者通过间距为5 - 10毫米的成排电极进行的深度记录进行分析,寻找所有可能位点对之间计算出的相干性显著局部分化的迹象。在4种状态下采集2 - 4分钟的脑电图样本:清醒、2 - 3期睡眠、允许患者对问题做出反应的浅手术麻醉以及癫痫发作。计算1至50赫兹或0.3至100赫兹的所有频率的相干性;为进行比较,使用2至70赫兹之间6个或7个较窄频段各自的平均相干性。尽管文献支持脑电图相干性通常在许多厘米范围内都很显著的观点,但这里所检验的假设(并且发现远高于随机预期)是,对于硬膜下或脑内记录的脑电图,在毫米范围内会出现显著结构。在硬膜下表面样本以及颞叶深度电极阵列的样本中,一对电极之间的相干性随距离下降,平均在毫米尺度上下降相当严重。所有频段情况几乎相同。对于8 - 13和13 - 20赫兹这样的中频带,在硬膜下表面数据中,平均相干性通常在前10毫米下降最陡,从距离小于0.5毫米时与1.0难以区分的值,下降到5 - 10毫米时的0.5,再到另外10 - 20毫米时的0.25。颞叶深度估计下降速度约为其一半;相干性≥0.5延伸9 - 20毫米,≥0.25再延伸20 - 35毫米。低频带(1 - 5、5 - 8赫兹)通常比高频带(20 - 35、35 - 50赫兹)下降稍慢,但差异小且方差大。人类中相干性随距离下降的陡度显著但仅略小于我们之前报道的兔子和大鼠的情况,平均不到一半。对于单个位点对的局部相干性,在毫米范围内显示出分化,即最近邻位点对的局部相干性可能远高于或低于平均水平,并且这种情况会持续数分钟。不同频率带的局部高点和低点往往相似。相干性与功率相当独立地变化,尽管它们有时会相关。在同一患者中,颞叶与额叶皮层或外侧额叶与额下皮层条带上位点对之间的平均相干性的区域分化在统计学上具有显著性,但这种差异通常较小。(摘要截断于400字)
