通过运动前脑电位评估清醒状态下人类呼吸肌的皮质驱动。
The cortical drive to human respiratory muscles in the awake state assessed by premotor cerebral potentials.
作者信息
Macefield G, Gandevia S C
机构信息
Department of Clinical Neurophysiology, Prince Henry Hospital, Matraville, NSW, Australia.
出版信息
J Physiol. 1991 Aug;439:545-58. doi: 10.1113/jphysiol.1991.sp018681.
Abstract
- We investigated the possibility of a cortical contribution to human respiration by recording from the scalp of awake subjects the premotor cerebral potentials that are known to precede voluntary limb movements. 2. Electroencephalographic activity (EEG) was recorded from scalp electrodes and averaged for 1.8-2.0 s before the time at which airway pressure exceeded an inspiratory or expiratory threshold. Clear premotor cerebral potentials were recorded during brisk, self-paced nasal inhalations or exhalations. In ten subjects, a slow cortical negativity (Bereitschaftspotential) was apparent in the averaged EEG, commencing 1.2 +/- 0.3 s before the onset of inspiratory (scalene) or expiratory (abdominal) muscle activity (EMG). It was maximal at the vertex, with a mean slope of 12.3 +/- 5.8 microV/s, and was followed by a post-movement positivity. 3. In four subjects the inspiratory premotor potential culminated in a large negativity, the motor potential, which began 24 +/- 15 ms before the onset of scalene EMG. It is argued that such a short latency is consistent with a volitionally generated respiratory command which travels relatively directly to the respiratory muscles, having a total central delay which is no longer than that for voluntary finger movements. 4. That the respiratory premotor and motor potentials did not originate in subcortical structures was supported by their absence in a patient suffering from chronic reflexogenic hiccups, in whom cerebral activity was back-averaged from each brisk hiccup. 5. During quiet breathing, in which subjects were relaxed and distracted from thinking about their respiration, no premotor cerebral potentials preceding inspiration could be detected. This failure was not due to the slow rate of rise of inspiratory activity during quiet breathing as compared with a brisk sniff, because premotor potentials were detected when subjects intermittently generated slow active expiratory efforts. 6. These observations suggest that during quiet breathing the cerebral cortex does not contribute to respiratory drive on a breath-by-breath basis. Conversely, the presence of clear premotor cerebral potentials when subjects performed self-paced inspiratory or expiratory manoeuvres illustrates the powerful cortical projection to human respiratory muscles.
摘要
- 我们通过在清醒受试者头皮上记录已知先于自主肢体运动的运动前脑电位,来研究皮质对人类呼吸的影响。2. 从头皮电极记录脑电图活动(EEG),并在气道压力超过吸气或呼气阈值之前的1.8 - 2.0秒进行平均。在轻快的、自定节奏地经鼻吸气或呼气过程中记录到了清晰的运动前脑电位。在10名受试者中,平均脑电图显示出一个缓慢的皮质负电位(准备电位)很明显,在吸气(斜角肌)或呼气(腹肌)肌肉活动(EMG)开始前1.2±0.3秒开始。它在头顶处最大,平均斜率为12.3±5.8微伏/秒,随后是运动后正电位。3. 在4名受试者中,吸气运动前电位最终形成一个大的负电位,即运动电位,它在斜角肌EMG开始前24±15毫秒开始。有人认为,如此短的潜伏期与一个由意志产生的呼吸指令一致,该指令相对直接地传至呼吸肌,其总的中枢延迟不超过自主手指运动的延迟。4. 一名患有慢性反射性呃逆的患者,其每次轻快呃逆的脑活动进行逆向平均时未出现呼吸运动前和运动电位,这支持了呼吸运动前和运动电位并非起源于皮质下结构的观点。5. 在安静呼吸时,受试者放松且未思考呼吸,未检测到吸气前的运动前脑电位。这种未检测到的情况并非由于安静呼吸时吸气活动的上升速率比轻快吸气时慢,因为当受试者间歇性地进行缓慢主动呼气动作时能检测到运动前电位。6. 这些观察结果表明,在安静呼吸过程中,大脑皮质并非逐次对呼吸驱动产生影响。相反,当受试者进行自定节奏的吸气或呼气动作时出现清晰的运动前脑电位,这说明了大脑皮质对人类呼吸肌有强大的投射作用。
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