Benefits of combination of electroencephalography, short latency somatosensory evoked potentials, and transcranial Doppler techniques for confirming brain death

Objective: Optimization of combining electroencephalography (EEG), short latency somatosensory evoked potentials (SLSEP) and transcranial Doppler (TCD) techniques to diagnose brain death. Methods: One hundred and eleven patients (69 males, 42 females) from the major hospitals of Zhejiang Province were examined with portable EEG, SLSEP and TCD devices. Re-examinations occurred ≤12 h later. Results: The first examination revealed that the combination of SLSEP and EEG led to more sensitive diagnoses than the combination of SLSEP and TCD. Re-examination confirmed this and also revealed that the combination of TCD and EEG was the most sensitive. Conclusion: The results show that using multiple techniques to diagnose brain death is superior to using single method, and that the combination of SLSEP and EEG is better than other combinations.

Monitoring somatosensory evoked potentials in spinal cord ischemia-reperfusion injury

It remains unclear whether spinal cord ischemia-reperfusion injury caused by ischemia and other non-mechanical factors can be monitored by somatosensory evoked potentials. Therefore, we monitored spinal cord ischemia-reperfusion injury in rabbits using somatosensory evoked potential detection technology. The results showed that the somatosensory evoked potential latency was significantly prolonged and the amplitude significantly reduced until it disappeared during the period of spinal cord ischemia. After reperfusion for 30-180 minutes, the amplitude and latency began to gradually recover; at 360 minutes of reperfusion, the latency showed no significant difference compared with the pre-ischemic value, while the somatosensory evoked potential amplitude in- creased, and severe hindlimb motor dysfunctions were detected. Experimental findings suggest that changes in somatosensory evoked potentia~ ~atency can reflect the degree of spinat cord ischemic injury, while the amplitude variations are indicators of the late spinal cord reperfusion injury, which provide evidence for the assessment of limb motor function and avoid iatrogenic spinal cord injury.

Cortical evoked potential changes in a rat model of acute ischemic stroke Detection of somatosensory evoked potential and motor evoked potential

BACKGROUND： Studies have shown that latency changes of some elements in a somatosensory evoked potential （SEP） and motor evoked potential （MEP） can reflect electrical activity of cerebral cortical neurons and conduction of white matter nerve fibers. However, there is a paucity of information regarding the dynamic observation of SEP and MEP following cerebral ischemic injury. OBJECTIVE： To explore SEP and MEP changes following acute ischemic stroke, and investigate the role of evoked potentials in monitoring brain function in stroke. DESIGN, TIME AND SETTING： A randomized, controlled, animal experiment was performed at the Chongqing Key Laboratory of Neurology, Affiliated Hospital of Chongqing Medical University from September 2007 to August 2008. MATERIALS＂ Hydrogen blood flow detector was purchased from Soochow University Medical Instrument Co., China, and Power lab system was purchased from AD Instruments, Inc., USA. METHODS A total of 36 healthy, adult, male, Sprague Dawley rats were randomly assigned to four groups （n = 9）, including three ischemia groups （12, 24 and 72 hours of ischemia） and a sham-surgery group. The rat model of acute ischemic stroke was established by middle cerebral artery occlusion （MCAO） in the left hemisphere. MAIN OUTCOME MEASURES＂ SEP and MEP of the left limbs were detected, and cerebral blood flow was measured by the hydrogen cleaning method. RESULTS： The latency of positive wave 1 （P1）, negative wave 1 （N1） and positive wave 2 （P2） waves in SEP, and latency of negative wave 1,2 （N1, N2） waves in MEP were significantly prolonged with increasing ischemic duration following MCAO （P 〈 0.01）, but cerebral blood flow was significantly decreased （P 〈 0.05, or P 〈 0.01）. CONLUSION： Ischemic stroke prolongs the latency of SEP waves （P1, N1, P2） and MEP waves （N1, N2）, and cerebral cortical evoked potential may correlate with cerebral blood flow changes. This indicates that SEP and MEP can be used to evaluate brain function following acute ischemic stroke.

A translational study of somatosensory evoked potential time–frequency components in rats,goats,and humans

Somatosensory evoked potentials(SEPs)have been widely used to assess neurological function in clinical practice.A good understanding of the association between SEP signals and neurological function is helpful for precise diagnosis of impairment location.Previous studies on SEPs have been reported in animal models.However,few studies have reported the relationships between SEP waveforms in animals and those in humans.In this study,we collected normal SEP waveforms and decomposed them into specific time–frequency components(TFCs).Our results showed three stable TFC distribution regions in intact goats and rats and in humans.After we induced spinal cord injury in the animal models,a greater number of small TFC distribution regions were observed in the injured goat and rat groups than in the normal group.Moreover,there were significant correlations(P<0.05)and linear relationships between the main SEP TFCs of the human group and those of the goat and rat groups.A stable TFC distribution of SEP components was observed in the human,goat and rat groups,and the TFC distribution modes were similar between the three groups.Results in various animal models in this study could be translated to future clinical studies based on SEP TFC analysis.Human studies were approved by the Institutional Review Board of the University of Hong Kong/Hospital Authority Hong Kong West Cluster(approval No.UM 05-312 T/975)on December 5,2005.Rat experiments were approved by the Committee on the Use of Live Animals in Teaching and Research of Li Ka Shing Faculty of Medicine of the University of Hong Kong(approval No.CULART 2912-12)on January 28,2013.Goat experiments were approved by the Animal Ethics Committee of Affiliated Hospital of Guangdong Medical University(approval No.GDY2002132)on March 5,2018.

BAEP和SSEP监测重型脑血管病患者脑干功能的研究

目的 研究急性重型脑血管病的脑干听觉诱发电位 (BAEP)和短潜伏期体感诱发电位 (SSEP)。方法 选择 3 0例急性重型脑血管病患者及 60名正常对照组 ,应用丹麦仪器完成BAEP和SSEP检查 ,分别在发病后 10h ,2、5、7、10及 3 0d观察脑干功能 ,并与临床表现和影像学检查相比较。结果 发病后 10h ,2、5、7、10及 3 0d时 ,BAEP和SSEP发现的脑干损害均明显早于临床表现和影像学检查。结论 BAEP和SSEP在检测重型脑血管病病人脑干功能方面具有定量评价作用。与临床表现和影像学检查相比 ,BAEP和SSEP能更好地反映重型脑血管病病人的脑干功能情况。

脑梗死患者非梗死侧正中神经体感诱发电位的研究

目的观察脑梗死患者非梗死侧正中神经体感诱发电位(SEP)的改变。方法对25例经头部MRI确诊的单侧颈内动脉脑梗死患者进行正中神经体感诱发电位检测并与正常对照组进行比较。结果脑梗死组与对照组比较,非梗死侧SEP的P15潜伏期延长(P<0.05)、N60潜伏期显著延长(P<0.001);25例脑梗死患者中8例患者非梗死侧SEP异常,异常率32%。结论SEP检测对发现脑梗死患者的微小病灶或亚临床病灶具有重要价值,其敏感性高于MRI。它是一种客观的、敏感的脑功能评定方法。

声诱发的短潜伏期负反应与前庭诱发的肌源性电位关系初步研究

目的 研究声诱发的短潜伏期负反应（acoustically evoked short latency negative response，ASNR）的特点，并初步证实该电位的前庭源性，即与前庭诱发的肌源性电位（vestibular evoked myogenic potentials，VEMP）同源。方法分别检测28例健康成人、16例前庭疾病和1例全聋患者的VEMP和ASNR，比较ASNR与VEMP之间的关系。结果 ASNR正常引出率为87．5％，潜伏期正常值为3．50±0．25ms；2倍标准差作为正常值的上、下限，ASNR潜伏期的范围为3～4ms，阈值为80～90dB nHL。16例前庭疾病患者均行双侧检查，在VEMP消失的9耳（9例）中，ASNR均未引出；VEMP低振幅的8例（8耳）中，5例（5耳）未引出ASNR，3例（3耳）ASNR正常引出。5例梅尼埃病患者接受甘油试验，1例（2耳）甘油试验前后VEMP与ASNR均正常，2例（4耳）双侧VEMP与ASNR甘油试验前异常，甘油试验后正常，1例（1耳）患侧VEMP正常，甘油试验前后无变化，ASNR由异常变为正常；1例（2耳）VEMP甘油试验前双侧异常，甘油试验后正常，但ASNR均未引出。1例听力正常的前庭神经炎患者，患侧VEMP未引出，ASNR电位也未引出。1例先天性全聋患者人工耳蜗植入前，VEMP、ASNR正常引出；植入后，术侧VEMP振幅降低，ASNR未引出。结论 ASNR与VEMP可能均源于球囊。鉴于目前的结果，在不便进行VEMP检测时可用ASNR替代。

先天性马蹄内翻足的神经电生理研究

目的探讨应用神经电生理方法检测马蹄内翻足患儿神经功能以明确病因和评估预后。方法应用SSEP、NCV及H反射等电生理检测方法,对48例(63足)马蹄内翻足患儿的神经功能进行检测。结果共有43足出现神经电生理异常(68.3%)。其中显示SSEP异常27足(42.9%),NCV异常15足(23.8%),H反射异常10足(15.9%)。重度畸形中(88.2%),中度畸形(74.2)存在神经电生理异常;合并SSEP和H反射均异常者6足。病变位点位腰骶脊髓者21足(48.8%)。结论先天性马蹄足患者多存在神经电生理异常且病变位点多位于腰骶脊髓节段。神经电生理异常与马蹄内翻足畸形程度相关。

早泄临床分度诊断及治疗方式的选择

目的:探讨早泄临床分度的合理性,及几种治疗方法对早泄分度治疗的临床应用效果。方法:按病情程度将其分为Ⅰ度组(轻度)、Ⅱ度组(中度)、Ⅲ度组(重度),每组分别随机抽取7人、7人、6人行骶神经感觉诱发电位(SSEP)检查。对每组病人均行四种治疗,以询问或信访获取临床效果。结果:SSEP检查三组间龟头、尿道外口处感觉阈值有显著性差异(P<0.05)。四种疗法对三组的治疗效果随分度的不同而各有差异,以单纯性行为疗法最低,以口服精神类药物为主的综合疗法最高,临床有效率达91.73％。结论:早泄病人的临床分度合理,按临床分度来选择治疗方式,可提高早泄治疗的针对性。尿道内注入并龟头涂抹局麻药是一种简单而有效的方式,而对重度早泄可选择以抗抑郁药为主的综合疗法。

短潜伏期体感诱发电位和闪光视觉诱发电位对脑出血患者预后的判断

目的近年来有多种诱发电位(EP)和脑外伤预后显著相关的报道,而EP和脑出血预后的关系还未见报道。本实验旨在了解发病早期短潜伏期体感诱发电位(SLSEP)、闪光视觉诱发电位(F-VEP)和脑出血近期预后的关系。方法81例脑出血患者均在发病48h内行SLSEP、F-VEP检查、Glascow昏迷评分(GCS),出院或死亡时进行Glascow预后分级(GOS)。结果SLSEP的中枢传导时间(CCT)、N20、F-VEP的N2和脑出血患者的GCS、GOS均显著相关。结论SLSEP和F-VEP是评价脑出血近期预后的有效手段。

正中神经脑干躯体感觉诱发电位和经颅短串电刺激运动诱发电位联合术中监护在颈髓手术中的应用

目的研究在异丙酚全静脉麻醉方案下,联合应用正中神经脑干躯体感觉诱发电位(MN-BSEP)和经颅短串电刺激运动诱发电位(STTES-MEP)对颈髓手术实施术中监护的可行性。方法通过变换不同的刺激条件、记录条件、技术参数,分别摸索MN-BSEP和STTES-MEP的可靠检测方法,并按照总结得到的技术规范,选择我科15例接受颈髓手术的病人,进行术中联合监护,对照分析术前和术后脊髓功能的改变和诱发电位变化之间的关系。结果MN-BSEP基本不受麻醉影响,术后的改变与术后病人感觉功能的转归情况相吻合;STTES-MEP与麻醉方案有关,在异丙酚麻醉下,可记录到清晰、稳定的运动诱发电位,其术后的变化与术后病人肌力的转归情况相吻合。结论选用异丙酚全静脉麻醉,联合应用MN-BSEP和STTES-MEP实现对颈髓功能的术中监护是可行的,其效果优于单纯应用体感诱发电位或运动诱发电位进行监护。

青少年胫后神经皮层体感诱发电位正常参考值研究

目的探讨及建立青少年胫后神经皮层体感诱发电位正常参考值范围。方法对45名13～24岁健康青少年记录和测量胫后神经皮层体感诱发电位P40、N50及P60的正常值。建立多元回归模型，探讨性别、年龄及身高等生理因素对峰潜伏期的影响。结果所有45例受试者均检测出可清晰辨认的波形。左右侧峰潜伏期差值无明显差异，与性别、年龄及身高无关。P40、N50、P60的峰潜伏期与身高呈XEN关（r=0.766～0．896，P〈0．001），与年龄及性别无关。结论青少年胫后神经皮层体感诱发电位各波峰潜伏期正常参考值及上限标准可根据峰潜伏期与身高的回归方程确定。

短潜伏期体感诱发电位量化得气:随机交叉对照试验方案

目的探索运用短潜伏期体感诱发电位(SLSEP)客观量化得气的可行性。方法采用随机对照交叉试验,纳入健康受试者,分为得气组(粗针、深刺、行手法促使得气)和不得气组(细针、浅刺、不行手法避免得气),记录针刺前、中、后体感诱发电位,量表测评受试者得气情况,观察三阴交穴得气与否对电位的影响。结果通过预试验进行可行性初探,发现得气对于SLSEP的影响具有一定规律性,值得观察。结论该方案具有可行性,可以展开正式试验。

兔急性颅内高压模型中体感诱发电位与听觉诱发电位的变化

目的 :探索颅内压 (ICP)升高过程中体感诱发电位 (SEPs)与脑干听觉诱发电位 (BAEPs)的变化规律。方法 :采用幕上不同部位放置球囊引起急性ICP增高的动物模型。将新西兰兔 30只分为 3组 :A组动物球囊置入右顶部硬膜下 ;B组动物球囊置入右颞底 ,C组以上部位动物各半 ,球囊内不注水。结果 :(1)A组SEPsP1波幅在ICP升至(1.48± 0 .35 )kPa即发生显著变化 ,而B组中ICP达 (8.10± 1.2 5 )kPa才出现波幅显著压缩。A组BAEPs在ICP升至(9.40± 1.6 0 )kPa时才出现IV ,V ,VII波的PL延长 ,而B组在ICP为 (3.11± 0 .80 )kPa时即见III波PL显著延长。 (2 )随ICP增高 ,P1波幅先随之升高 ,继而转为下降。结论 :SEPs与BAEPs的变化不仅受ICP高低的影响 ,还与病变的部位有关 ;

人类声诱发短潜伏期负电位的研究

目的在极重度感音性聋耳的ABR检测中发现一个位于3～4ms潜伏期的"V"字形负向波形,称声诱发短潜伏期负电位(Acoustically Evoked Short Latency Negative Response,ASNR)。本研究通过大宗病例调查和临床实验来探讨ASNR的特点和起源。方法回顾性调查并分析3104例ABR检测结果,以详尽了解ASNR的出现率和特性。对20名双耳极重度感音性耳聋患者(6～62岁)和12名健康人(23～30岁)进行了ABR和前庭诱发肌源性电位(VEMP)测试。患者组包括了16名人工耳蜗植入术后的患者,植入耳在裸耳状态时可提供无功能耳蜗模型。结果判读侧重于:人工耳蜗植入耳能否诱发ASNR,以及对比在极重度感音性聋耳中ASNR组和非ASNR组的VEMP出现率及反应阈值。结果ASNR仅出现于极重度感音性聋耳,并且对强声刺激(80～120dBnHL)有依赖性。在653例极重度感音性聋患者(981耳)的ABR波形中,有80例(12.3%)117耳(11.9%)出现了ASNR。ASNR有良好的重复性,可排除伪迹干扰的可能性。ASNR具有神经电位的特征,表现在随着声刺激的增强,其潜伏期缩短而振幅增大。ASNR与ABR的波形完全不一样,无法将其解释为传统听觉神经通路产生的电位。临床实验中,3个人工耳蜗植入耳能诱发出ASNR,说明ASNR的发生与耳蜗无关。所有9个ASNR耳都诱发出VEMP,且阈值与正常对照组无统计学差异(P>0.05),提示ASNR耳具有正常的球囊功能。在非ASNR组中,三分之二没有引出VEMP,而另外三分之一虽然可以诱发出VEMP,但阈值明显较正常对照组高(P<0.01),分别提示球囊功能丧失或低下。此外,有一外半规管麻痹耳诱发出了ASNR和VEMP。结论ASNR并非伪迹,而是一种依赖强声刺激,且只出现于极重度感音性聋耳的神经电位。ASNR的出现完全依赖于正常的球囊功能,而不依赖于残余听力或者半规管功能。据此认为ASNR起源感觉器官为球囊,根据其潜伏期推测电位源自前庭神经核。

脑血管病患者的经颅磁刺激运动诱发电位和短潜伏期体感诱发电位的对比研究

采用经颅磁刺激运动诱发电位（MEP）对72名脑血管病患者进行检测，其中57例还同时测定短潜伏期体感诱发电位（SSEP），并和50例正常人进行对比研究．结果发现脑血管病患者瘫痪侧上肢MEP异常表现为刺激无反应或皮层潜伏期延长和中枢传导时间延长，与正常对照组和健侧比较差异有极高度显著性（P＜0．001），瘫痪侧下肢MEP异常表现为刺激无反应或中枢传导时间延长，与正常对照组和健侧比较，差异有显著性（P＜0．05）．MEP和SSEP异常率在脑出血与脑梗塞之间无显著性差异（P＞0．05），而与临床表现和病变部位密切相关。本文提示MEP和SSEP分别能客观地反映脑血管病愈者中枢运动传导通路和中枢感觉通路功能受损的情况．

身高、体质量、年龄对术中体感诱发电位监护的影响

目的研究脊柱侧凸病人体质量、身高、年龄与术中体感诱发电位(SEP)监护的关系。方法以70例脊柱侧凸病人为对象,其中男性19例,女性51例;年龄4～35岁,平均年龄17.5岁;身高100～188cm,平均159.44cm;体质量15.5～84kg,平均44.39kg。分析术中皮层和下皮层SEP的潜伏期和波幅在不同手术阶段的百分比变化率与体质量、身高、年龄的相关性。结果数据统计结果显示,各监护阶段SEP波峰潜伏期和波幅的百分比变化率与病人的体质量、身高和年龄没有显著的相关性(相关系数│r│<0.35,P>0.05)。结论在脊柱侧凸矫形手术术中脊髓监护过程中,病人的身高、体质量和年龄不会对SEP监护结果产生影响。

短潜时体感诱发电位评价冠心病患者中枢神经功能研究

目的应用短潜时体感诱发电位（SSEP）评价冠心病中枢神经功能的变化.方法刺激43例无明显中枢神经症状的冠心病患者（心绞痛18例、心肌梗死慢性期25例）以及14例正常对照的正中神经,同时记录皮质体感诱发电位和脊髓体感诱发电位,观察中枢神经功能的变化.结果心绞痛和心肌梗死患者的N13、N20、P25波潜伏期及中枢传导时间（CCT）均较对照组明显延长（ P〈0.05～0.001）;心绞痛患者的N20、P25波潜伏期及CCT均较心肌梗死患者明显延长（ P〈0.01～0.001）.结论冠心病特别是心肌梗死患者,其脊髓到大脑皮质第一感觉区的中枢躯体感觉通路存在亚临床损害.

硫喷妥钠对上肢短潜伏期体感诱发电位的影响

目的与方法：７例上肢感觉传导道无异常的病例，静脉注射硫喷妥钠５ｍｇ／ｋｇ后，分别观察注药前、注药后即刻、２、４和６ｍｉｎ上肢短潜伏期体感诱发电位，比较Ｐ１５、Ｎ２０、Ｐ２５各波的潜伏期以及Ｐ１５Ｎ２０、Ｎ２０Ｐ２５的峰间值。结果：各波潜伏期在注药后缩短，以注药后２、４ｍｉｎ最明显，６ｍｉｎ时已基本恢复，Ｐ１５Ｎ２０、Ｎ２０Ｐ２５峰间值在注药后减小，以２ｍｉｎ时减至最小，６ｍｉｎ时已基本恢复。结论：术中行体感诱发电位监测时，不宜使用硫喷妥钠。

正常小儿胫神经诱发短潜伏时头皮体感区电位及脑瘫对该电位的影响

本研究观察了20例正常小儿和49例脑瘫小儿的下肢胫后神经刺激性短潜伏时头皮体感诱发电位(PTN-SSEP)。正常小儿在刺激后出现6个反应波(P18、N23、P31、N42、P54和N68),大脑左右两体感头皮的SSEP波形相似;时相基本相等,t检验表明两侧间无差异;电压除波P31外其余波也无显著差异。脑瘫小儿PTN-SSEP异常率达91.84％,有4种类型:正常型占8.16％、混合异常型57.14％、反应低下型6.12％及电压不对称型28.57％。经统计患儿左右头皮的SSEP、潜伏时和电压均有显著差异(P<0.05),其中P31和N42电压差值>50％。与正常小儿比较,患儿双侧反应降低,多数波潜伏时延长。患侧电压损失率>50％(P<0.001),波P18、N23和P31的潜伏时差异显著。结果提示.(1)正常小儿体感通路反应稳定,左右侧活动基本对称;(2)脑瘫小儿体感通路左右侧活动不对称,患侧传导机能下降,体感皮层反应减退。