Boakye M, Huckins S C, Szeverenyi N M, Taskey B I, Hodge C J
Department of Neurosurgery, State University of New York Upstate Medical University, Syracuse 13210, USA.
J Neurosurg. 2000 Nov;93(5):774-83. doi: 10.3171/jns.2000.93.5.0774.
Functional magnetic resonance (fMR) imaging was used to determine patterns of cerebral blood flow changes in the somatosensory cortex that result from median nerve stimulation (MNS).
Ten healthy volunteers underwent stimulation of the right median nerve at frequencies of 5.1 Hz (five volunteers) and 50 Hz (five volunteers). The left median nerve was stimulated at frequencies of 5.1 Hz (two volunteers) and 50 Hz (five volunteers). Tactile stimulation (with a soft brush) of the right index finger was also applied (three volunteers). Functional MR imaging data were transformed into Talairach space coordinates and averaged by group. Results showed significant activation (p < 0.001) in the following regions: primary sensorimotor cortex (SMI), secondary somatosensory cortex (SII), parietal operculum, insula, frontal cortex, supplementary motor area, and posterior parietal cortices (Brodmann's Areas 7 and 40). Further analysis revealed no statistically significant difference (p > 0.05) between volumes of cortical activation in the SMI or SII resulting from electrical stimuli at 5.1 Hz and 50 Hz. There existed no significant differences (p > 0.05) in cortical activity in either the SMI or SII resulting from either left- or right-sided MNS. With the exception of the frontal cortex, areas of cortical activity in response to tactile stimulation were anatomically identical to those regions activated by electrical stimulation. In the SMI and SII, activation resulting from tactile stimulation was not significantly different (p > 0.05) from that resulting from electrical stimulation.
Electrical stimulation of the median nerve is a reproducible and effective means of activating multiple somatosensory cortical areas, and fMR imaging can be used to investigate the complex network that exists between these areas.
运用功能磁共振成像(fMR)来确定正中神经刺激(MNS)引起的体感皮层脑血流变化模式。
10名健康志愿者接受右侧正中神经以5.1赫兹(5名志愿者)和50赫兹(5名志愿者)频率的刺激。左侧正中神经以5.1赫兹(2名志愿者)和50赫兹(5名志愿者)频率进行刺激。还对右侧食指进行了触觉刺激(用软刷)(3名志愿者)。功能磁共振成像数据被转换为Talairach空间坐标并按组进行平均。结果显示在以下区域有显著激活(p < 0.001):初级感觉运动皮层(SMI)、次级体感皮层(SII)、顶叶岛盖、脑岛、额叶皮层、辅助运动区以及顶叶后皮层(布罗德曼区7和40)。进一步分析表明,5.1赫兹和50赫兹电刺激在SMI或SII中引起的皮层激活体积之间无统计学显著差异(p > 0.05)。左侧或右侧MNS在SMI或SII中引起的皮层活动也无显著差异(p > 0.05)。除额叶皮层外,对触觉刺激产生反应的皮层活动区域在解剖学上与电刺激激活的区域相同。在SMI和SII中,触觉刺激引起的激活与电刺激引起的激活无显著差异(p > 0.05)。
正中神经的电刺激是激活多个体感皮层区域的一种可重复且有效的方法,并且fMR成像可用于研究这些区域之间存在的复杂网络。
