Laboratory for Human and Experimental Neurophysiology (LAHEN), School of Medicine, University of Split, Split, Croatia; Department for Intraoperative Neurophysiology, Roosevelt Hospital, New York, NY, USA.
Laboratory for Human and Experimental Neurophysiology (LAHEN), School of Medicine, University of Split, Split, Croatia.
Clin Neurophysiol. 2014 Sep;125(9):1912-22. doi: 10.1016/j.clinph.2014.01.023. Epub 2014 Feb 11.
The aim of this study was to identify neurophysiologic markers generated by primary motor and premotor cortex for laryngeal muscles, recorded from laryngeal muscle.
Ten right-handed healthy subjects underwent navigated transcranial magnetic stimulation (nTMS) and 18 patients underwent direct cortical stimulation (DCS) over the left hemisphere, while recording neurophysiologic markers, short latency response (SLR) and long latency response (LLR) from cricothyroid muscle. Both healthy subjects and patients were engaged in the visual object-naming task. In healthy subjects, the stimulation was time-locked at 10-300 ms after picture presentation while in the patients it was at zero time.
The latency of SLR in healthy subjects was 12.66 ± 1.09 ms and in patients 12.67 ± 1.23 ms. The latency of LLR in healthy subjects was 58.5 ± 5.9 ms, while in patients 54.25 ± 3.69 ms. SLR elicited by the stimulation of M1 for laryngeal muscles corresponded to induced dysarthria, while LLR elicited by stimulation of the premotor cortex in the caudal opercular part of inferior frontal gyrus, recorded from laryngeal muscle, corresponded to speech arrest in patients and speech arrest and/or language disturbances in healthy subjects.
In both groups, SLR indicated location of M1 for laryngeal muscles, and LLR location of premotor cortex in the caudal opercular part of inferior frontal gyrus, recorded from laryngeal muscle, while stimulation of these areas in the dominant hemisphere induced transient speech disruptions.
Described methodology can be used in preoperative mapping, and it is expected to facilitate surgical planning and intraoperative mapping, preserving these areas from injuries.
本研究旨在识别由喉肌记录的初级运动和运动前皮层产生的神经生理标记。
10 名右利手健康受试者接受经颅磁刺激(nTMS),18 名患者接受左侧大脑半球的直接皮质刺激(DCS),同时记录环甲肌的神经生理标记,短潜伏期反应(SLR)和长潜伏期反应(LLR)。健康受试者和患者均参与视觉物体命名任务。在健康受试者中,刺激时间锁定在图片呈现后 10-300 毫秒,而在患者中则为零时间。
健康受试者 SLR 的潜伏期为 12.66 ± 1.09ms,患者为 12.67 ± 1.23ms。健康受试者 LLR 的潜伏期为 58.5 ± 5.9ms,而患者为 54.25 ± 3.69ms。刺激喉肌的 M1 产生的 SLR 对应于诱导性构音障碍,而刺激位于下额前回后外侧部运动前皮层的 LLR 记录于喉肌,对应于患者的言语停止,以及健康受试者的言语停止和/或语言障碍。
在两组中,SLR 指示喉肌 M1 的位置,而 LLR 指示下额前回后外侧部运动前皮层的位置,刺激这些区域在优势半球引起短暂的言语障碍。
描述的方法可用于术前定位,并有望促进手术计划和术中定位,保护这些区域免受损伤。
