Cortical and spinal evoked potential response to electrical stimulation in human rectum

AIM: To study a novel technique to record spinal and cortical evoked potentials (EPs) simultaneously in response to electrical stimulation in the human rectum. METHODS: Eight male and nine female healthy volunteers participated. Stimulating electrodes were attached to the rectal mucosa at 15 cm and 12 cm above the dentate line. Recording skin electrodes were positioned over vertebrae L4 through S2. The electrical stimulus was a square wave of 0.2 ms duration and the intensity of the stimulus varied between 0 and 100 mA. EP responses were recorded using a Nicolet Viking IV programmable signal conditioner.RESULTS: Simultaneous recording of cortical and spinal EPs was obtained in > 80% of the trials. The EP responses increased with the intensity of the electrical stimulation, were reproducible overtime, and were blocked by application of Lidocaine jelly at the site of stimulation. The morphology (N1/P1), mean ± SD for latency (spinal N1, 4.6 ± 0.4 ms; P1, 6.8 ± 0.5 ms; cortical N1, 136.1 ± 4.2 ms; P1, 233.6 ± 12.8 ms) and amplitude (N1/P1, spinal, 38 ± 7 μV; cortical 19 ± 3 μV) data for the EP responses were consistent with those in the published literature. Reliable and reproducible EP recordings were obtained with the attachment of the electrodes to the rectal mucosa at predetermined locations between 16 and 8 cm above the anal verge, and the distance between the attachment sites of the electrodes (the optimal distance being approximately 3.0 cm between the two electrodes). CONCLUSION: This technique can be used to assess potential abnormalities in primary afferent neural pathways innervating the rectum in several neurodegenerative and functional pain disorders.

Effect of electrical stimulation on neural regeneration via the p38-RhoA and ERK1/2-Bcl-2 pathways in spinal cord-injured rats

Although electrical stimulation is therapeutically applied for neural regeneration in patients, it remains unclear how electrical stimulation exerts its effects at the molecular level on spinal cord injury （SCI）. To identify the signaling pathway involved in electrical stimulation improving the function of injured spinal cord, 21 female Sprague-Dawley rats were randomly assigned to three groups： control （no surgical intervention, n = 6）, SCI （SCI only, n = 5）, and electrical simulation （ES; SCI induction followed by ES treatment, n = 10）. A complete spinal cord transection was performed at the 10^th thoracic level. Electrical stimulation of the injured spinal cord region was applied for 4 hours per day for 7 days. On days 2 and 7 post SCI, the Touch-Test Sensory Evaluators and the Basso-Beattie-Bresnahan locomotor scale were used to evaluate rat sensory and motor function. Somatosensory-evoked potentials of the tibial nerve of a hind paw of the rat were measured to evaluate the electrophysiological function of injured spinal cord. Western blot analysis was performed to measure p38-RhoA and ERK1/2-Bcl-2 pathways related protein levels in the injured spinal cord. Rat sensory and motor functions were similar between SCI and ES groups. Com- pared with the SCI group, in the ES group, the latencies of the somatosensory-evoked potential of the tibial nerve of rats were significantly shortened, the amplitudes were significantly increased, RhoA protein level was significantly decreased, protein gene product 9.5 expression, ERK1/2, p38, and Bcl-2 protein levels in the spinal cord were significantly increased. These data suggest that ES can promote the recovery of electrophysiological function of the injured spinal cord through regulating p38-RhoA and ERK1/2-Bcl-2 pathway-related protein levels in the injured spinal cord.

EFFECTS OF TRANSCRANIAL MAGNETIC STIMULATION ON MOTOR CORTICAL EXCITABILITY AND NEUROFUNCTION AFTER CEREBRAL ISCHEMIA-REPERFUSION INJURY IN RATS

Objective To clarify the effects of repetitive transcranial magnetic stimulation (rTMS) on rat motor cortical excitabi- lity and neurofunction after cerebral ischemia-reperfusion injury. Methods After determined awake resting motor threshold (MT) and motor evoked potentials (MEPs) of right hindlimbs, 20 Sprague-Dawley rats were subjected to middle cerebral artery occlusion (MCAO) reperfusion injury, then rTMS were applied to rTMS group (n = 10) at different time, while control group (n = 10) received no stimulation. A week later, MT and MEPs were evaluated again, as well as neurological deficits and infarct volume. The effects of rTMS and MCAO reperfusion injury on these parameters were analyzed. Results After MCAO reperfusion, both MT level and neurological deficit scores increased, distinct focal infarction formed, and latency of MEP elongated. Compared with the control group, the increased extent of MT and neurological scores of rats receiving rTMS were significantly lower (P < 0.05), as well as the infarct volumes reduced significantly(P < 0.05). But MEP was not affected by rTMS obviously. There was a positive linear correlation between postinjury MT and infarct volume (r = 0.64, P < 0.05). Conclusion rTMS may facilitate neurofunction recovery after cerebral ischemia-reperfusion. Postinjury MT could provide prognostic information after MCAO reperfusion injury.

Effects of different frequencies of repetitive transcranial magnetic stimulation on the recovery of upper limb motor dysfunction in patients with subacute cerebral infarction

Studies have confirmed that low-frequency repetitive transcranial magnetic stimulation can decrease the activity of cortical neurons, and high-frequency repetitive transcranial magnetic stimulation can increase the excitability of cortical neurons. However, there are few studies concerning the use of different frequencies of repetitive transcranial magnetic stimulation on the recovery of upper-limb motor function after cerebral infarction. We hypothesized that different frequencies of repetitive transcranial magnetic stimulation in patients with cerebral infarction would produce different effects on the recovery of upper-limb motor function. This study enrolled 127 patients with upper-limb dysfunction during the subacute phase of cerebral infarction. These patients were randomly assigned to three groups. The low-frequency group comprised 42 patients who were treated with 1 Hz repetitive transcranial magnetic stimulation on the contralateral hemisphere primary motor cortex （M1）. The high-frequency group comprised 43 patients who were treated with 10 Hz repetitive transcranial magnetic stimulation on ipsilateral M1. Finally, the sham group comprised 42 patients who were treated with 10 Hz of false stimulation on ipsilateral M1. A total of 135 seconds of stimulation was applied in the sham group and high-frequency group. At 2 weeks after treatment, cortical latency of motor-evoked potentials and central motor conduction time were significantly lower compared with before treatment. Moreover, motor function scores were significantly improved. The above indices for the low- and high-frequency groups were significantly different compared with the sham group. However, there was no significant difference between the low- and high-frequency groups. The results show that low- and high-frequency repetitive transcranial magnetic stimulation can similarly improve upper-limb motor function in patients with cerebral infarction.

Ipsilateral motor evoked potentials in a patient with unihemispheric cortical atrophy due to Rasmussen encephalitis

The role of the ipsilaterally descending motor pathways in the recovery mechanisms after unilateral hemispheric damage is still poorly understood. Motor output reorganization was investigated in a 56-year-old male patient with acquired unilateral hemispheric atrophy due to Rasmussen encephalitis. In particular,the ipsilateral corticospinal pathways were explored using focal transcranial magnetic stimulation. In the first dorsal interosseous and wrist extensors muscles, the median amplitudes of the ipsilateral motor evoked potentials induced by transcranial magnetic stimulation in the patient were higher than those of 10 age-matched healthy control subjects. In the biceps brachii muscle, the median amplitudes of the ipsilateral motor evoked potentials were the second largest in the patient compared to the controls. This study demonstrated a reinforcement of ipsilateral motor projections from the unaffected motor cortex to the hemiparetic hand in a subject with acquired unihemispheric cortical damage.

经颅磁声电刺激对健康与帕金森病大鼠神经回路中beta振荡的影响

背景:经颅磁声电刺激是一种基于磁声耦合电效应的无创、高精度脑神经聚焦刺激方法,可调节神经节律振荡活动,从而影响大脑的运动、认知等功能。目的:探究经颅磁声电刺激对健康与帕金森病大鼠神经回路中beta振荡的影响。方法:①动物实验:采用随机数字表法将24只Wistar大鼠随机分为4组,每组6只:正常对照组不进行任何干预;正常刺激组大脑前额叶皮质接受经颅磁声电刺激(空间峰值脉冲平均强度为13.33 W/cm^(2),基波频率为0.4 MHz,基波周期数为1000,脉冲重复频率为200 Hz);模型对照组、模型刺激组通过腹腔注射1-甲基-4-苯基-1,2,3,6-四氢吡啶建立帕金森病模型,造模成功后,模型对照组大脑前额叶皮质接受经颅磁声电假刺激,模型刺激组大脑前额叶皮质接受经颅磁声电刺激,每天刺激时长2.0 min,刺激结束停留8-10 min后,采集大鼠执行T迷宫过程中局部场电位信号并同时记录行为学正确率,对比分析各组局部场电位信号能量的时频分布情况和行为差异,当大鼠正确率连续3 d高于80%后停止刺激实验和T迷宫实验。②建模仿真实验:构建经颅磁声电刺激下皮质-基底神经节回路模型,分别改变超声发射周期(5,10,20 ms)、超声发射占空比(30%,50%,90%)和感应电流密度(20,50,100μA/cm^(2)),比较不同刺激参数下健康与帕金森病大鼠beta振荡的功率谱密度值。结果与结论:①动物实验:正常对照组大鼠的空间学习能力强于模型对照组(P<0.001),正常刺激组大鼠的空间学习能力强于正常对照组(P<0.05),模型刺激组大鼠的空间学习能力强于模型对照组(P<0.01);正常对照组beta振荡能量分布较为集中,正常刺激组较正常对照组beta振荡信号能量有所降低,模型对照组与模型刺激组beta振荡能量广泛分布且能量值显著高于正常对照组、正常刺激组,并且模型刺激组beta振荡信号能量明显低于模型对照组;②建模仿真实验:不加刺激时,健康大鼠beta频段功率谱密度峰值(30 dB)显著低于帕金森病大鼠(55 dB);施加经颅磁声电刺激后,两组大鼠beta频段功率谱密度值普遍降低;beta频段功率谱密度峰值与超声发射周期呈正相关、与感应电流密度呈负相关,当超声发射占空比为50%时功率谱密度峰值最低;③结果表明:经颅磁声电刺激可抑制健康与帕金森病大鼠的beta振荡,进而改善大鼠的运动功能与决策认知功能。

多参数监测在颈动脉内膜剥脱术治疗合并对侧颈动脉中重度狭窄中的应用

目的探索残端压(stump pressure,SP)、术中体感诱发电位(somatosensory evoked potential,SEP)、脑电图(electroencephalogram,EEG)和经颅多普勒超声(transcranial Doppler,TCD)监测在颈动脉内膜剥脱术(carotid endarterectomy,CEA)治疗合并对侧颈动脉中重度狭窄患者的应用和意义。方法回顾性分析2021年5月至2023年6月郑州大学第五附属医院26例行CEA治疗合并对侧颈动脉中重度狭窄患者的临床资料,患者术中均行SEP、EEG、SP和TCD监测并设定预警标准,记录围手术期并发症发生情况及改良Rankin量表(modified Rankin scale,mRS)评分。结果26例患者发生多参数监测预警34次,其中SEP预警7次、EEG预警8次、SP预警10次、TCD预警9次。3例患者在升压后未解除预警而使用转流管。术后发生症状性脑梗死1例,过度灌注综合征2例,颅神经损伤1例。术后3个月复查影像学显示术侧颈动脉均通畅,均无新发脑血管事件和死亡。患者术后mRS评分0分21例,1分4例,2分1例。结论对于合并对侧颈动脉中重度狭窄的患者,CEA术中多参数监测可更准确地评估术中脑血流状态,指导转流管的合理使用,减少围手术期并发症的发生。

Effect of Paired Associative Stimulation on Motor Cortex Excitability in Rats

Paired associative stimulation (PAS),combining transcranial magnetic stimulation (TMS) with electrical peripheral nerve stimulation (PNS) in pairs with an optimal interstimulus interval (ISI)in between,has been shown to influence the excitability of the motor cortex (MC)in humans.However,the underlying mechanisms remain unclear.This study was designed to explore an optimal protocol of PAS,which can modulate the excitability of MC in rats,and to investigate the underlying mechanisms. The resting motor thresholds (RMTs) of TMS-elicited motor evoked potentials (MEPs) recorded from the gastrocnemius muscle and the latency of P1 component of somatosensory evoked potentials (SEPs) induced by electrical tibial nerve stimulation were determined in male Sprague-Dawley rats (n=10).Sixty rats were then randomly divided into 3 groups:a PAS group (further divided into 10 subgroups at various ISIs calculated by using the latency of P1,n=5,respectively),a TMS (only)group (n=5)and a PNS (only)group (n=5).Ninety repetitions of PAS,TMS and PNS were administered to the rats in the 3 groups,respectively,at the frequency of 0.05 Hz and the intensity of TMS at 120% RMT and that of PNS at 6 mA.RMTs and motor evoked potentials'amplitude (MEPamp)were recorded before and immediately after the interventions.It was found that the MEPamp significantly decreased after PAS at ISI of 5 ms (P<0.05),while the MEPamp significantly increased after PAS at ISI of 15ms,as compared with those before the intervention (P<0.05).However,the RMT did not change significantly after PAS at ISI of 5 ms or 15 ms (P>0.05).PAS at other ISis as well as the sole use of TMS and PNS induced no remarkable changes in MEPamp and RMT.In conclusion,PAS can influence motor cortex excitability in rats.Neither TMS alone nor PNS alone shows significant effect.

Effects of cortical intermittent theta burst stimulation combined with precise root stimulation on motor function after spinal cord injury: a case series study

Activation and reconstruction of the spinal cord circuitry is important for improving motor function following spinal cord injury.We conducted a case series study to investigate motor function improvement in 14 patients with chronic spinal cord injury treated with 4 weeks of unilateral(right only)cortical intermittent theta burst stimulation combined with bilateral magnetic stimulation of L3-L4 nerve roots,five times a week.Bilateral resting motor evoked potential amplitude was increased,central motor conduction time on the side receiving cortical stimulation was significantly decreased,and lower extremity motor score,Berg balance score,spinal cord independence measure-III score,and 10 m-walking speed were all increased after treatment.Right resting motor evoked potential amplitude was positively correlated with lower extremity motor score after 4 weeks of treatment.These findings suggest that cortical intermittent theta burst stimulation combined with precise root stimulation can improve nerve conduction of the corticospinal tract and lower limb motor function recovery in patients with chronic spinal cord injury.

Nerve root magnetic stimulation improves locomotor function following spinal cord injury with electrophysiological improvements and cortical synaptic reconstruction

Following a spinal cord injury,there are usually a number of neural pathways that remain intact in the spinal cord.These residual nerve fibers are important,as they could be used to reconstruct the neural circuits that enable motor function.Our group previously designed a novel magnetic stimulation protocol,targeting the motor cortex and the spinal nerve roots,that led to significant improvements in locomotor function in patients with a chronic incomplete spinal cord injury.Here,we investigated how nerve root magnetic stimulation contributes to improved locomotor function using a rat model of spinal cord injury.Rats underwent surgery to clamp the spinal cord at T10;three days later,the rats were treated with repetitive magnetic stimulation(5 Hz,25 pulses/train,20 pulse trains)targeting the nerve roots at the L5-L6 vertebrae.The treatment was repeated five times a week over a period of three weeks.We found that the nerve root magnetic stimulation improved the locomotor function and enhanced nerve conduction in the injured spinal cord.In addition,the nerve root magnetic stimulation promoted the recovery of synaptic ultrastructure in the sensorimotor cortex.Overall,the results suggest that nerve root magnetic stimulation may be an effective,noninvasive method for mobilizing the residual spinal cord pathways to promote the recovery of locomotor function.

Combining Motor Imagery and Action Observation with Vibratory Stimulation Increases Corticomotor Excitability in Healthy Young Adults

Vibratory stimulation but also motor imagery and action observation can induce corticomotor modulation, as a bottom-up stimulus and top-down stimuli, respectively. However, it remains unknown whether the combination of motor imagery, action observation, and vibratory stimulation can effectively increase corticomotor excitability. This study aimed to investigate the effect of motor imagery and/or action observation, in the presence or absence of vibratory stimulation, on the corticomotor excitability of healthy young adults. Vibratory stimulation was provided to the palm of the right hand. Action observation consisted in viewing a movie of someone else’s finger flexion and extension movements. The imagery condition required the participants to imagine they were moving their fingers while viewing the movie and attempting to move their fingers in accordance with the movie. Eleven right-handed healthy young adults were asked to perform six conditions randomly: 1) vibratory stimulation, imagery, and action observation, 2) vibratory stimulation and action observation, 3) vibratory stimulation and viewing of a blank screen, 4) imagery and action observation, 5) action observation, and 6) viewing of a blank screen. Single-pulse transcranial magnetic stimulation was conducted to assess corticomotor excitability and the peak-to-peak amplitude of the motor evoked potentials. The results showed that vibratory stimulation increases corticospinal excitability. The findings further revealed that performing motor imagery while viewing finger movement is more effective at inducing an augmentation of corticomotor excitability compared to action observation alone. Thus, the combination of motor imagery, action observation, and vibratory stimulation can effectively augment corticomotor excitability.

电针联合重复经颅磁刺激治疗老年中重度卒中后抑郁的临床随机对照试验研究

目的 观察电针联合重复经颅磁刺激(rTMS)治疗中重度卒中后抑郁的临床疗效。方法 将2021年12月—2023年1月上海中医药大学附属第七人民医院康复医学科病房收治的78例中重度卒中后抑郁的患者按照数字表法随机分为观察组和对照组,每组39例。对照组接受重复经颅磁刺激治疗,观察组接受电针联合重复经颅磁刺激治疗,选取穴位有百会(DU20)、四神聪(EX-HN1)、本神(GB13)、曲池(LI11)、内关(PC6)、足三里(ST36)、申脉(BL62)。2组每周治疗5次,共治疗4周。治疗前后,观察并比较2组汉密尔顿抑郁量表(HAMD)和简式Fugl-Meyer评分(FMA)的评分变化,同时测量并比较2组运动诱发电位(MEP)的变化;比较2组的临床疗效。结果 治疗4周后,2组的HAMD评分、 MEP潜伏期及中枢运动传导时间(CMCT)均下降,FMA评分均升高,组内比较差异均具有统计学意义(P<0.01);治疗后,观察组的HAMD评分、MEP潜伏期及中枢运动传导时间(CMCT)均明显低/少于对照组,而FMA评分高于对照组,差异均有统计学意义(P<0.05)。观察组治疗总有效率高于对照组(P<0.05)。结论 电针联合重复经颅磁刺激(rTMS)治疗中重度卒中后抑郁疗效优于单纯重复经颅磁刺激,能更好的改善患者的抑郁情绪,同时可能更好的促进运动功能恢复。

经颅磁声电刺激下大鼠工作记忆中前额叶皮层因果连接网络特性分析

经颅磁声电刺激(TMAES)是一种新型非侵入式的脑神经调控技术,利用静磁场和超声波耦合在脑组织中产生刺激电流以调节特定脑区的神经放电活动。本研究旨在从神经节律振荡与信息传递的角度,探究经颅磁声电刺激对大脑工作记忆功能的影响。将24只斯普拉格·道利(SD)大鼠随机分为对照组、超声组和磁声组,磁声组接受0.10 T、7.98 W/cm^(2)的刺激,超声组接受相同强度的超声刺激,对照组不接受刺激;采集T迷宫工作记忆实验中大鼠前额叶皮层的局部场电位(LFPs)信号,对比不同组别θ(4~8 Hz)和γ(30~80 Hz)频段LFPs信号的时频分布,并基于图论进一步分析前额叶皮层的因果连接网络特性。结果显示,磁声组大鼠在行为选择过程中θ和γ频段LFPs信号的能量值大于超声组与对照组(P<0.05);磁声组信号间平均因果连接强度高于超声组和对照组(P<0.05);磁声组大鼠工作记忆任务中θ频段因果连接网络的全局效率(E_(glob))和聚类系数(C)比超声组和对照组显著升高(磁声组:E_(glob)=0.134±0.033,C=0.837±0.071;超声组:E_(glob)=0.099±0.032,C=0.713±0.111;对照组:E_(glob)=0.068±0.022,C=0.554±0.118,P<0.05);磁声组γ频段因果连接网络的全局效率、聚类系数比超声组和对照组显著升高(磁声组:E_(glob)=0.116±0.031,C=0.789±0.106;超声组:E_(glob)=0.087±0.018,C=0.641±0.135;对照组:E_(glob)=0.066±0.012,C=0.480±0.091,P<0.05)。研究表明,TMAES增强了θ和γ节律神经放电活动,促进大鼠行为选择期间神经元集群之间的信息交互,提高工作记忆相关信息的传递效率,为进一步揭示经颅磁声电刺激调控大脑记忆功能的深层作用机制提供支持。

经颅直流电刺激对亚急性期缺血性脑卒中患者上肢运动功能和体感诱发电位的影响

目的:探讨经颅直流电刺激(tDCS)对亚急性期缺血性脑卒中患者上肢运动功能和体感诱发电位的影响。方法:选取脑卒中后上肢运动功能障碍患者96例,随机分为观察组47例和对照组49例,观察组给与tDCS和上肢常规康复训练,对照组给与tDCS假刺激和上肢常规康复训练。分别于治疗前、治疗4周后应用Fugl-Meyer运动功能评定量表上肢部分(FMA-UE)、Wolf运动功能测试量表(WMFT)、改良Barthel指数(MBI)及上肢正中神经诱发电位N20潜伏期和波幅对2组患者进行评估,并对2组患者的正中神经诱发电位N20测定结果变化和肢体功能变化的进行相关性分析,观察干预前后患者上肢运动功能与体感诱发电位的变化。结果:治疗4周后,2组患者的FMA-UE、WMFT、MBI评分较治疗前均显著升高,且观察组高于对照组,差异均有统计学意义(均P<0.05);观察组N20波幅较治疗前则增加(P<0.05);2组N20潜伏期组内、组间比较均无统计学差异;除治疗组WMFT差值与N20潜伏期差值呈正相关(r=0.305,P=0.037)外,其余均无相关性,2组患者偏瘫侧治疗前正中神经SEP N20测定结果与治疗4周后MBI、FMA-UE、WMFT各项量表评分均无相关性。结论:经颅直流电刺激可改善亚急性期脑卒中患者的上肢运动功能及体感诱发电位N20的波幅,SEP N20潜伏期变化和肢体功能WMFT评分变化具有一定的相关性。

感觉输入干扰对咬肌运动皮质可塑性的影响

目的:本研究评估了感觉输入干扰对健康受试者牙齿咬合力精确控制训练(tooth-clenching task,TCT)后初级运动皮质(MI)咬肌控制区兴奋性变化的影响。方法:本试验纳入12名健康受试者进行了为期两期的垂直向研究,第一期:直接进行1小时TCT。第二期:切牙局部浸润麻醉下进行1小时TCT。应用导航经颅磁刺激(nTMS)对两期试验在基线和训练后两个时间点测量并记录受试者MI咬肌控制区及MI第一指间骨肌(FDI)控制区的特征。利用配对T检验分别对两期试验训练前后牙齿咬合力精确控制度进行比较,并对MI咬肌控制区及MI第一指间骨肌(FDI)控制区的运动诱发电位(MEP)平均振幅、运动阈值、地图面积进行比较。结果:在第一期试验中训练后与训练前相比咬肌皮质控制区MEPs平均振幅显著增加、牙齿咬合力控制精度显著增加(P<0.05),而第二期试验中训练前后MEPs平均振幅差异无统计学意义、牙齿咬合力控制精度无显著差异(P>0.05)。结论:1小时TCT可引发咬肌控制区域皮质兴奋性发生改变,切牙区局部浸润麻醉所引发的感觉输入干扰,钝化了TCT对大脑运动皮质咬肌控制区兴奋性的影响。

基于蓝牙传输的TMS运动诱发电位检测系统设计

目的 :针对现有经颅磁刺激(transcranial magnetic stimulation,TMS)运动诱发电位(motor evoked potential,MEP)检测仪器体积大、难以便携的现状,设计一种结构简单的便携式TMS运动诱发电位检测系统。方法:该系统由MEP调理模块、MEP实时采集模块和PC数据接收端组成。其中,MEP调理模块包括仪表放大电路、滤波电路、二级放大电路、电平抬升电路以及电源电路;MEP实时采集模块包括基于STM32F407的模数转换器、串口通信模块和蓝牙模块;PC数据接收端基于Qt开发平台设计。结果:MEP调理模块的放大增益倍数在1 000~1 500范围内可调,共模抑制比约为110 dB,通频带为11~1 300 Hz;TMS运动诱发电位检测系统的采样率可达到10 kHz,能够实现MEP的检测。结论:TMS运动诱发电位检测系统体积小且便携,为基于TMS运动诱发电位的健康检测提供了技术支撑。

多模态监测在颈动脉内膜剥脱术中的应用

目的探讨颈动脉内膜剥脱术(CEA)中行多模态监测预测术后脑卒中的应用价值。方法回顾性分析聊城市人民医院在2020年1月至2021年12月行CEA手术患者58例,其中男41例,女17例;年龄(65.1±8.7)岁,均经DSA检查证实存在颈动脉狭窄,术中均行多模态神经电生理监测。观察术后疗效及术后并发症,比较术中不同监测模式对于预测术后脑卒中发生的效能。结果患者CEA术后1周内复查CTA或DSA显示颈动脉狭窄均消失。发生围术期卒中患者7例。单一TCD监测的灵敏度为71.43%,高于SEP+MEP监测的57.14%,低于多模态监测的85.71%;SEP+MEP监测的特异度为82.35%,高于单一TCD监测的78.43%,低于多模态监测的92.16%。结论多模态监测在颈动脉内膜剥脱术中有重要意义,可以更好地指导手术进程,评估患者预后。

重复经颅磁刺激结合舌压抗阻反馈训练对脑出血术后吞咽功能障碍患者脑干听觉诱发电位及误吸风险的影响

目的探讨重复经颅磁刺激结合舌压抗阻反馈训练在脑出血术后吞咽功能障碍患者中的应用效果。方法选择2019年7月至2021年8月我院收治的80例脑出血术后吞咽功能障碍患者,根据干预方案不同将其分为对照组、观察组,各40例。对照组接受舌压抗阻反馈训练,观察组在对照组干预方案基础上加施重复经颅磁刺激。比较两组的干预效果。结果干预后,观察组的脑干听觉诱发电位(BAEP)Ⅰ波、Ⅲ波、Ⅴ波潜伏期均短于对照组(P<0.05)。干预后,观察组的渗透-误吸量表(PAS)等级分布优于对照组(P<0.05)。干预后,观察组的功能性经口摄食量表(FOIS)评分高于对照组,标准吞咽功能评估量表(SSA)评分低于对照组(P<0.05)。结论重复经颅磁刺激结合舌压抗阻反馈训练可改善脑出血术后吞咽功能障碍患者BAEP及吞咽功能,减少误吸的发生风险。

经颅磁声电刺激下皮层钙信号及突触传递特性的仿真与实验分析

为了探究经颅磁声电刺激(transcranial magneto-acoustic-electrical stimulation,TMAES)不同磁场强度和超声功率强度对工作记忆信息编码相关的皮层神经元钙信号及突触传递特性的影响,首先通过搭建基于磁声电效应改进的皮层锥体神经元模型,引入钙依赖神经递质释放的计算方法以计算TMAES引起的兴奋性突触后电位(excitatory postsynaptic potential,EPSP),以EPSP作为评价指标来评估不同TMAES磁场强度和超声功率强度下突触传递的短时程可塑性.随后使用光纤光度检测技术实时记录TMAES下小鼠前额叶皮层神经集群的钙信号,以揭示TMAES下钙依赖神经信息传递机制.仿真结果表明:TMAES不同磁场强度和超声功率强度对突触后响应的大小具有双向调节作用,其中,突触传递产生的短时程增强和抑制是由于TMAES下胞内钙浓度的变化引起的囊泡释放和囊泡耗竭.实验结论表明:TMAES对前额叶皮层神经元集群钙信号幅度和频率均有明显的调节作用,TMAES可以通过调节神经钙浓度进而影响突触间的信息传递.

神经肌肉电刺激疗法对急性脑梗死患者上肢体感诱发电位的影响研究

目的分析神经肌肉电刺激疗法用于急性脑梗死(ACI)患者对其上肢体感诱发电位(SEP)的影响。方法选取2020年1月至2022年11月河南科技大学第二附属医院收治的ACI患者共52例进行研究,结合随机数字表法分成对照组(常规疗法)、观察组(在前组基础上加以神经肌肉电刺激疗法)各有26例;观察两组疗效、治疗前后上肢SEP有关指标、Fugl-Meyer运动功能量表(FMA)、神经功能缺损量表(NIHSS)以及改良Barthel指数(MBI)得分情况。结果观察组治疗有效率高于对照组,差异有统计学意义(P<0.05)。治疗前,两组N9潜伏期、N9波幅、N20潜伏期、N-20波幅等上肢SEP有关指标相比,差异无统计学意义(P>0.05);治疗后,两组N9潜伏期、N20潜伏期较前降低,差异有统计学意义(P<0.05),N9波幅、N-20波幅较前升高,差异有统计学意义(P<0.05),且观察组N9潜伏期、N20潜伏期低于对照组,差异有统计学意义(P<0.05)。N9波幅、N-20波幅高于对照组,差异有统计学意义(P<0.05)。治疗前,两组FMA、NIHSS及MBI评分相比,差异无统计学意义(P>0.05);治疗后,两组FMA、MBI评分较前升高,差异有统计学意义(P<0.05),NIHSS评分较前降低,差异有统计学意义(P<0.05),且观察组FMA、MBI评分高于对照组,差异有统计学意义(P<0.05),NIHSS评分低于对照组,差异有统计学意义(P<0.05)。结论神经肌肉电刺激疗法用于ACI患者疗效理想,能改善其上肢SEP有关指标,提升其肢体运动功能和日常生活能力,减轻其神经功能缺损。