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刺激正中神经诱发的人类皮质电位。II. 产生长潜伏期活动的细胞构筑区。

Human cortical potentials evoked by stimulation of the median nerve. II. Cytoarchitectonic areas generating long-latency activity.

作者信息

Allison T, McCarthy G, Wood C C, Williamson P D, Spencer D D

机构信息

Neuropsychology Laboratory, Veterans Administration Medical Center, West Haven 06516.

出版信息

J Neurophysiol. 1989 Sep;62(3):711-22. doi: 10.1152/jn.1989.62.3.711.

DOI:10.1152/jn.1989.62.3.711
PMID:2769355
Abstract
  1. The anatomic generators of human median nerve somatosensory evoked potentials (SEPs) in the 40 to 250-ms latency range were investigated in 54 patients by means of cortical-surface and transcortical recordings obtained during neurosurgery. 2. Contralateral stimulation evoked three groups of SEPs recorded from the hand representation area of sensorimotor cortex: P45-N80-P180, recorded anterior to the central sulcus (CS) and maximal on the precentral gyrus; N45-P80-N180, recorded posterior to the CS and maximal on the postcentral gyrus; and P50-N90-P190, recorded near and on either side of the CS. 3. P45-N80-P180 inverted in polarity to N45-P80-N180 across the CS but was similar in polarity from the cortical surface and white matter in transcortical recordings. These spatial distributions were similar to those of the short-latency P20-N30 and N20-P30 potentials described in the preceding paper, suggesting that these long-latency potentials are generated in area 3b of somatosensory cortex. 4. P50-N90-P190 was largest over the anterior one-half of somatosensory cortex and did not show polarity inversion across the CS. This spatial distribution was similar to that of the short-latency P25-N35 potentials described in the preceding paper and, together with our and Goldring et al. 1970; Stohr and Goldring 1969 transcortical recordings, suggest that these long-latency potentials are generated in area 1 of somatosensory cortex. 5. SEPs of apparently local origin were recorded from several regions of sensorimotor cortex to stimulation of the ipsilateral median nerve. Surface and transcortical recordings suggest that the ipsilateral potentials are generated not in area 3b, but rather in other regions of sensorimotor cortex perhaps including areas 4, 1, 2, and 7. This spatial distribution suggests that the ipsilateral potentials are generated by transcallosal input from the contralateral hemisphere. 6. Recordings from the periSylvian region were characterized by P100 and N100, recorded above and below the Sylvian sulcus (SS) respectively. This distribution suggests a tangential generator located in the upper wall of the SS in the second somatosensory area (SII). In addition, N125 and P200, recorded near and on either side of the SS, suggest a radial generator in a portion of SII located in surface cortex above the SS. 7. In comparison with the short-latency SEPs described in the preceding paper, the long-latency potentials were more variable and were more affected by intraoperative conditions.
摘要
  1. 通过神经外科手术期间获得的皮质表面和经皮质记录,对54例患者在40至250毫秒潜伏期范围内的人类正中神经体感诱发电位(SEP)的解剖起源进行了研究。2. 对侧刺激在感觉运动皮质的手部代表区记录到三组SEP:P45 - N80 - P180,在中央沟(CS)前方记录,在中央前回最大;N45 - P80 - N180,在CS后方记录,在中央后回最大;以及P50 - N90 - P190,在CS附近及两侧记录。3. P45 - N80 - P180在CS两侧极性反转成N45 - P80 - N180,但在经皮质记录中从皮质表面和白质记录时极性相似。这些空间分布与前文所述的短潜伏期P20 - N30和N20 - P30电位相似,表明这些长潜伏期电位在体感皮质的3b区产生。4. P50 - N90 - P190在体感皮质前半部分最大,且在CS两侧未显示极性反转。这种空间分布与前文所述的短潜伏期P25 - N35电位相似,并且与我们以及Goldring等人1970年;Stohr和Goldring 1969年的经皮质记录一起,表明这些长潜伏期电位在体感皮质的1区产生。5. 对同侧正中神经刺激,在感觉运动皮质的几个区域记录到明显起源于局部的SEP。表面和经皮质记录表明,同侧电位不是在3b区产生,而是在感觉运动皮质的其他区域产生,可能包括4区、1区、2区和7区。这种空间分布表明同侧电位是由对侧半球的胼胝体传入产生的。6. 颞叶周围区域的记录特征为分别在外侧裂(SS)上方和下方记录到的P1

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