大鼠 C 类传入纤维诱发的脊髓背表面电位

实验共用大鼠66只,以激活 C 类纤维的强度刺激腓肠神经,在脊髓背表面除记录到 A 类纤维诱发的 N_1、N_2和 P_1波外,还见一长潜伏期正波。该波与 P_1波方向一致,波形类似,故称之为 P_2波。P_2波潜伏期为133.3±13.7ms, 时程为83.3±21.9ms,幅度为154.8±92.8μV.P_2波的刺激阈值(33.7±11.8T)与复合动作电位 C 波的阈值(33.1±11.8T)相同或略高,当刺激强度达87.1±15.4T 时,两者幅度同时达最大值。P_2波的潜伏期与 C 类传入抵达脊髓的时间(125.6±13.4ms)非常接近,缩短外周传导距离所致 P_2波潜伏期的缩短(39.8±5.7ms)与 C 类传入经过缩短段所需时间(38.8±5.7ms)基本一致。用直流电阻断 A 类传入仅保留 C波时,N_1、N_2、P_1波消失而 P_2波仍存在,加大阻断电流使 C 波消失时,P_2波随之消失。以上结果表明 P_2波是 C 类传入诱发的脊髓电位。脊髓横断后 P_2波并不消失,P_2波在脊髓背表面的纵向分布与 P_1波基本平行,注射印防己碱后 P_2波与 P_1波都有减小,说明 P_2波的性质与 P_1波类似,可能是 C 类传入主要经脊髓环路诱发的初级传入末梢去极化,或许可作为突触前抑制指标。     

电刺激大鼠坐骨神经诱发海马齿状回突触可塑性研究

观察电刺激大鼠坐骨神经引起海马齿状回诱发场电位的变化,探讨外周传入信息在海马的可塑性以及海马在痛觉调制中的作用。共记录了28只大鼠海马齿状回诱发场电位,平均幅度(23.73±1.12)μV,潜伏期(198.46±5.91)ms。不同条件刺激引起的反应包括:高频条件刺激使海马齿状回诱发场电位幅度降低;低频条件刺激使海马齿状回诱发场电位幅度增大。结果提示,电刺激坐骨神经可在海马齿状回记录到诱发场电位,不同的条件刺激可引起诱发场电位的不同变化,表现为突触传递效能增强或降低,海马对外周传入信息及痛觉起一定的调制作用。     

大鼠前庭内侧核在前庭—交感反应中的作用

实验在氯醛糖和尿酯混合麻醉的大鼠上进行。在内脏大神经上记录刺激同侧前庭神经进入脑干处的交感反应。电刺激前庭神经可在同侧内脏大神经引出—明确的叠加反应,其平均潜伏期为45.8±6.98ms,时程为55.21±5.35ms。增加刺激强度,反应幅度也增加,但潜伏期不变。用前庭内侧核(NVM)的片层场电位作为指标并选择其相位倒转处作刺激点,可在同侧内脏大神经记录到潜伏期为32ms 的叠加反应,而同一动物刺激前庭神经入脑处时内脏大神经反应的潜伏期为43ms。在 NVM 头端损毁后,此前庭-交感反应明显减小,再损毁尾端 NVM 后,此反应消失。损毁 Deiters 核对前庭-交感反应无影响。这些结果表明 NVM在内脏大神经记录到的前庭-交感反应中是一重要的中继站。     

通过脊髓-延脑-脊髓回路引起的脊髓背根电位

过去的工作提示在针刺抑制内脏-躯体反射的效应中,针刺信号沿着脊髓腹外侧索上行至延脑,激活包括中缝大核在内的延脑内侧网状结构,由此发出下行冲动至脊髓,阻遇内脏Aδ传入纤维冲动的向上传递。本工作在经麻痹的清醒猫刺激以上神经回路的各个部分,均能在腰段及胸段引起背根电位。为了刺激上行纤维,我们将右半部胸段脊髓分离出一段,其尾端切断,前端仍与脊髓相连。在 T2-4水平将这样半孤立的脊髓(S_p)挂在钧形电极上刺激,所引起的 L6背根电位的潜伏期是48±6;在 P9水平刺激中缝大核(R_m)引起的 L6背根电位的潜伏期是36±3,刺激背外侧索表面引起的 L6背根电位潜伏期仅3—5毫秒。背根电位的时程和反射的抑制时程大体相符,但后一时程一般总是要长些。刺激 S_p 和 R_m 引起的背根电位的长度常数均在3毫米左右,表示是较细纤维的去极化。如在脊髓 T2-3水平切割背外侧索,则由刺激 S_p(T5-7)及 R_m 引起的 L6及 T11背根电位均消失。毁损延脑内侧网状结构后,刺激 S_p 引起的 L6及 T11背根电位大为减弱或消失。以上结果指示通过我们所提出的神经回路能引起脊髓较细传入末梢发生去极化,这种突触前机制可能在针刺镇痛效应中起一定的作用。     

微电极矩阵研究小鼠胚胎心脏电生理活动

本实验采用一种新方法——微电极矩阵技术从整体水平研究小鼠胚胎离体整体心脏电生理活动。我们用微电极矩阵记录与60个电极相接触的心肌细胞的电活动(细胞外记录),称为场电位(field potentials,FPs),并与全细胞膜片钳记录的动作电位(action potentials,APs)(细胞内记录)进行比较,发现心房、心室处场电位形态类似于负向的细胞动作电位,场电位时程亦与动作电位时程类似。为研究兴奋的传导,我们比较了不同电极处场电位发生时间,发现在房室结构还未形成的胚胎发育第9．5天(E9．5)已经观察到明显的房室传导延迟(A-V delay)[(50．21±9．7)ms],而心室不同部位兴奋几乎是同步的。在发育晚期(E16．5),房室传导延迟为(82．21±10．50)ms。进一步研究基本的神经体液因素对心脏兴奋的调控,表明: 在E9．5,异丙肾上腺素(isoproterenol,Iso)使胚胎兴奋频率加快(34．04±7．31)％,房室传导延迟缩短(20．00±6．44)％,同时场电位时程增宽;相反,卡巴唑(carbachol,CCh)则使兴奋频率降低(42．32±5．36)％,房室传导缩短(26．00±4．81)％, 场电位时程减小。而在E16．5,Iso的作用显著增强,兴奋频率加快(101．54±10．23)％,房室传导延迟缩短(56．62±6．43)％, 而CCh则几乎使所有晚期心脏兴奋完全消失。所以,心脏的传导系统在胚胎发育早期4个腔室还未形成时已经建立,神经体液因子对心脏基本电生理活动的调控是在发育过程中逐渐成熟的。     

正常中国人中枢运动系统传导时间的测定

本文应用高电压、低输出阻抗刺激器,经皮给予大脑皮层和脊髓电刺激(BSPES),同时在上肢鱼际(Thenar)和下肢胫骨前肌(Muscle tibialis anterior)上记录诱发肌肉动作电位,测定了64名正常健康中国人(男:46;女:18)的中枢运动系统传导时间。受试者年龄为20—67岁,身高为156—185cm。刺激大脑皮层出现反应的潜伏期与刺激脊髓出现反应的潜伏期之差为中枢运动传导时间(CMCT)。实验测得鱼际的 CMCT 为6.69±1.48ms;胫骨前肌的 CMCT 为12.90±1.59ms。经统计学处理证明,CMCT 与左右侧肢体、性别、年龄及身高无关。说明 CMCT 是无损伤测定与评价中枢运动系统功能的较精确的一种客观指标。本文根据所测数据,计算出脊髓内运动传导速度为71.34±10.89 m/s,与文献报道的锥体束传导速度50—70 m/s 相近。因此,CMCT 反映了锥体束的传导时间。     

刺激中缝背核区对猫小脑皮层浦肯野细胞电活动的影响

本文研究了刺激外周神经及中缝背核区对猫小脑皮层浦肯野细胞(Purkinje Cell,PC)电活动的影响。在清醒的去大脑猫上记录刺激桡深神经(NRP)及腓深神经(NPP)时PC的电变化,并观察刺激中缝背核区对PC自发放电以及肢体神经传入冲动诱发活动的影响。结果表明,刺激NPP和NRP均可引起小脑皮层第Ⅴ和第ⅦA小叶的PC产生兴奋或抑制反应。刺激中缝背核区对PC自发放电以及诱发活动主要起抑制性影响。     

刺激兔中脑导水管周围灰质对束旁核单位放电的影响

实验在65只家兔进行。局麻下进行手术准备,筒箭毒素麻痹下进行实验观察。用玻璃微电极记录束旁核单位放电,以腓总神经的强电流刺激(30—50伏)作为损伤性刺激。根据对外周损伤性刺激反应的不同,在束旁核单位中可区分出两类功能不同的神经元,一类的自发放电可因外周痛信号的传入而增强,称为痛敏神经元;一类的自发放电可因外周痛信号的传入而减少,称为痛抑制神经元。中脑导水管周围灰质的弱电流刺激(4—6伏)或吗啡静注(3毫克/公斤体重),可使痛敏神经元对外周损伤性刺激的痛反应减弱或消失,却可使痛抑制神经元因痛传入而出现的自发放电的抑制现象减弱或不再出现。刺激中脑中央灰质或吗啡注射对束旁核痛敏神经元的上述影响,在脊髓胸_(12)或腰_1段的背侧1/2被切断后仍然能出现。由于多数实验证明脑干对脊髓痛传递的下行抑制系统是在脊髓背外侧束中下行的,因此我们的实验提示,中脑结构有可能通过上行性联系抑制束旁核神经元对痛传入的反应;吗啡似乎也能通过这一联系实现其镇痛作用。     

刺激隐神经C类纤维诱发体感皮层电反应(平均诱发电位)

当猫的隐神经A类纤维单独兴奋时,可引起同侧脊髓背表面电位 A-SSP(潜伏期 2.6±0.4ms)和对侧体感皮层诱发电位 A-CEP。A-CEP由早成分(潜伏期 9.6±1 1ms)和晚成分(203.0±10.gms)组成。当 C类纤维选择性传入时,出现特异的 C-CEP(潜伏期 134.4±25.9ms)和C-SSP(115.8±15.6ms)。C-CEP的幅值较A-CEP 小,并随C类纤维传入的数量而改变。C-CEP的最大幅值位于后乙状回一定部位,多为负或正-负电位,在皮层深层其相位倒转。与A-CEP相比,C-CEP的中枢延搁时间较长,跟随频率较低,对镇痛药较敏感。表明C-CEP不同于A-CEP,它是由C类传入所引起的,是在体感皮层内产生的。当A类和C类纤维同时传入时,只有A-CEP和A-SSP出现,而不出现C-CEP和C-SSP。在阻断电流逐渐增强过程中,C-CEP较C-SSP后出现;而在撤销阻断过程中,则C-CEP较C-SSP先消失。提示C类传入在中枢可能被A类传入所抑制,这种抑制可以发生在脊髓和脊上水平,后者可能更强。     

电刺激大鼠皮神经外周端对相邻脊髓节段皮神经内Aβ纤维的机械感受特性的影响

为观察Aβ类初级传入纤维是否参与相邻脊髓节段外周末梢之间的信息传递及其相关机制 ,实验自近中端切断一侧T8～T12 脊髓节段背侧皮神经 ,将一支被切断的皮神经的外周端分离成数支细束 ,以单个Aβ纤维放电为指征 ,检测单位的传导速度、适应特性、机械感受阈值、感受野的形状和面积 ;在相邻脊髓节段、也与中枢断离的皮神经干上施加逆向电刺激 ( 0 45mA ,0 1ms,2 0Hz,10s) ,以观察该刺激对Aβ纤维的上述机械感受特性的影响。在 42只大鼠上共记录了 5 0个Aβ类单位。逆向电刺激相邻节段皮神经后 ,60 6% (n =3 3 )的单位感受野增大 ,全部单位的感受野平均面积从 8 94± 6 5 1mm2 显著增加到 2 0 3 4± 16 17mm2 (P <0 0 1)。 81 8% (n =2 0 )的单位感受野形状从点状、圆或与身体长轴垂直的椭圆变成与身体长轴斜行或平行的椭圆。 68 0 % (n =5 0 )的单位机械感受阈值下降 ,全部单位的平均阈值从 2 3 7± 1 2 4mN降至 2 2 9± 1 2 4mN (P <0 0 5 )。上述机械感受特性的改变可持续 5 2 2 3± 9 2 7至 5 6 93± 15 76min。跨节段电刺激后 ,有 5 0 0 % (n =5 0 )的单位同时出现放电的增加 ,但该增加仅持续 1 5 2± 0 46min ,显著短于机械感受特性改变的时程 (P <0 0 1)。有机械感受特性改变的单位也     

Rapid-Rate Paired Associative Stimulation over the Primary Somatosensory Cortex

Rapid-rate paired associative stimulation (rPAS) involves repeat pairing of peripheral nerve stimulation and Transcranial magnetic stimulation (TMS) pulses at a 5 Hz frequency. RPAS over primary motor cortex (M1) operates with spike-timing dependent plasticity such that increases in corticospinal excitability occur when the nerve and TMS pulse temporally coincide in cortex. The present study investigates the effects of rPAS over primary somatosensory cortex (SI) which has not been performed to date. In a series of experiments, rPAS was delivered over SI and M1 at varying timing intervals between the nerve and TMS pulse based on the latency of the N20 somatosensory evoked potential (SEP) component within each participant (intervals for SI-rPAS: N20, N20-2.5 ms, N20 + 2.5 ms, intervals for M1-rPAS: N20, N20+5 ms). Changes in SI physiology were measured via SEPs (N20, P25, N20-P25) and SEP paired-pulse inhibition, and changes in M1 physiology were measured with motor evoked potentials and short-latency afferent inhibition. Measures were obtained before rPAS and at 5, 25 and 45 minutes following stimulation. Results indicate that paired-pulse inhibition and short-latency afferent inhibition were reduced only when the SI-rPAS nerve-TMS timing interval was set to N20-2.5 ms. SI-rPAS over SI also led to remote effects on motor physiology over a wider range of nerve-TMS intervals (N20-2.5 ms – N20+2.5 ms) during which motor evoked potentials were increased. M1-rPAS increased motor evoked potentials and reduced short-latency afferent inhibition as previously reported. These data provide evidence that, similar to M1, rPAS over SI is spike-timing dependent and is capable of exerting changes in SI and M1 physiology.     

急性神经损伤引起脊髓背角C-纤维诱发电位长时程增强

神经损伤引起神经病性疼痛,表现为持续性痛超敏和痛觉过敏。目前对神经病性疼痛的机制尚缺乏了解。我们以往的工作表明强直电刺激坐骨神经可引起脊髓背角C-纤维诱发电位的长时程增强(long-term potentiation,LTP),该LTP被认为是病理性疼痛的突触模型。本研究的目的在于探讨急性神经损伤是否能在完整动物的脊髓背角诱发出C-纤维诱发电位LTP。在以测试刺激(10～20V,0．5ms)电刺激坐骨神经的同时在脊髓背角用微电极记录C一纤维诱发电位。分别用强直刺激、剪断或夹捏坐骨神经诱导LTP。结果发现：(1)剪断或夹捏坐骨神经都可以诱导脊髓背角C-纤维诱发电位的LTP,该LTP可持续到实验结束(3～9h),在剪断神经前10min用利多卡因局部阻滞坐骨神经则可完全阻断LTP的产生;(2)神经损伤诱导的LTP可被NMDA受体阻断剂AP5所阻断;(3)用单次强直刺激引起LTP后,切断坐骨神经可使LTP的幅度进一步增大,而用多次强直电刺激使LTP饱和后,损伤神经则不能使LTP进一步增大。切断神经引起LTP后,强直电刺激也不能使LTP进一步增大。这些结果表明,急性神经损伤可以诱导脊髓背角C纤维诱发电位LTP,且切断神经能更有效地诱导LTP。该试验进一步支持我们的设想,即脊髓背角C-纤维诱发电位LTP可能在病理性疼痛的形成中起重要作用。     

Participation of nonsegmentary neurons of the spinal cord in execution of presynaptic control

Experiments were carried out on cats six days after complete transection of the spinal cord. Cord dorsum potentials (CDP) were recorded in the vicinity of the third lumbar segment during stimulation of the isolated dorsolateral funiculus (DLF). The CDP consist of a rapid monophasic potential (which apparently reflects antidromic excitation of the cells of Clarke's column) and two subsequent slow negative waves, which are replaced by a long positive oscillation. In form, time characteristics, and behavior during thythmic stimulation, this potential differs considerably from the CDP recorded during stimulation of the afferent nerves. The presence of a positive phase of the CDP indicates that stimulation of the DLF evokes primary afferent depolarization (PAD). Stimulation of the DLF causes inhibition of the CDP evoked by stimulation of the afferent nerve. The time course of this inhibition corresponds to the time course of presynaptic inhibition. It is demonstrated that stimulation of the afferent nerve (n. femoralis) inhibits slow components of the CDP evoked by stimulation of the DLF. This inhibition reaches a maximum at the 16th millisecond; its duration exceeds 300 msec. Stronger and more prolonged inhibition of the same components is observed when both the conditioning and the testing stimuli are administered to the DLF. Since primary afferents do not take part in CDP emergence during stimulation of the DLF, it may be hypothesized that the observed inhibition develops as a result of depolarization of interneuron axon terminals.Dnepropetrovsk State University. Translated from Neirofiziologiya, Vol. 2, No. 5, pp. 520–527, September–October, 1970.     

左旋四氢巴马汀加强电针对兔大脑皮层牙髓诱发电位的...

Cortical potentials evoked by stimulation of the contralateral tooth-pulp were recorded epidurally from the SI cortex of rabbits anesthetized with urethane and chloralose. It was found that nociceptive components of the evoked potential consisted of P1 and P2 wavelets with a relative stable peak latency of 22.5 +/- 1.2 ms and 66.1 +/- 1.9 ms respectively. Higher intensity of tooth pulp stimulation was required for appearance of P2 than P1. Diazepam, a non-analgesic sedative, reduced P1 but not P2 amplitude. On the contrary, dolantin, an analgesic, suppressed P2 but showed no significant influence on P1. The results suggest that P2, but not P1 might be related to pain. The effects of l-tetrahydropalmatine (1-THP) and electroacupuncture on P2 were observed on 12 animals. The results showed that both iv l-THP 8mg/kg and electroacupuncture brought forth a decrease in P2 amplitude by 40.3 +/- 14% and 59.3 +/- 10% respectively, while electroacupuncture combined with l-THP produce a further decrease in P2 amplitude by 92.8 +/- 7%. Furthermore, the inhibitory periods of P2 amplitude were significantly prolonged after electroacupuncture combined with l-THP. The results indicated that l-THP enhanced the suppression of P2 by electroacupuncture.     

新生大鼠离体脊髓薄片侧角中间外侧核细胞的电生理特性

在新生大鼠离体脊髓薄片的中间外侧核作细胞内记录,研究细胞膜的静态与动态电生理特性。细胞的静息电位(RP)变动于-46—-70mV,膜的输入阻抗为108.3±67.9MΩ(X±SD,下同),时间常数9.9±5.6ms,膜电容138.6±124.2pF。用去极化电流进行细胞内刺激时,大部份细胞(85.4％)能产生高频率连续发放,其余细胞(15.6％)仅产生初始单个发放。胞内直接刺激引起的动作电位(AP)幅度为63.4±9.0mV,时程2.4±0.6ms,阈电位水平在RP基础上去极18.7±6.2mV。大部份细胞的锋电位后存在明显的超极化后电位,其幅度为5.1±2.7mV、持续90±31.8ms。刺激背根可在记录细胞引起EPSP或顺向AP,少数细胞尚出现IPSP。而刺激腹根则可引起逆向AP。     

Spinal cord dorsum potentials recorded in vivo after cold injury to the sural nerve in the rabbit

Evoked potentials were recorded in the spinal cord dorsum of rabbits during and after local cooling or freezing of the sural nerve. The potentials were elicited by stimulation through implanted bipolar electrodes distal and proximal to the site of cooling. Recordings were made with a unipolar electrode implanted dorsally into the epidural space.The first two negative deflections of the evoked field potentials (s- and n-potentials) decreased or disappeared during cooling to temperatures between 12 and 2 °C. Immediately following cooling the potentials were depressed by as much as 40% below that of controls. Gradual recovery of the nerve conduction velocity and of both potentials occurred between postoperative Days 20 and 60. Cooling of the nerve to between +2 and ?2 °C caused a 70–80% decrease in amplitude and the precooling values were not obtained within 90 days' follow-up. Local freezing of the sural nerve to ?45 °C resulted in disappearance of the cord dorsum potentials previously obtained by stimulation of the sural nerve with electrode distal to the site frozen. About 40% decrease occurred when stimulated proximal to the site frozen. A fast amplitude increase took place between days 50 and 100 and a slower increase between days 150 and 450 to values more than twice the preoperative amplitudes. A similar amplitude increase was obtained by stimulation of the nerve proximal to the site frozen.     

In vivo recording of electrical activity of canine tracheal smooth muscle.

Electrical activity of the tracheal smooth muscle was studied using extracellular bipolar electrodes in 37 decerebrate, paralyzed, and mechanically ventilated dogs. A spontaneous oscillatory potential that consisted of a slow sinusoidal wave of 0.57 +/- 0.13 (SD) Hz mean frequency but lacked a fast spike component was recorded from 15 dogs. Lung collapse accomplished by bilateral pneumothoraxes evoked or augmented the slow potentials that were associated with an increase in tracheal muscle contraction in 26 dogs. This suggests that the inputs from the airway mechanoreceptors reflexly activate the tracheal smooth muscle cells. Bilateral vagal transection abolished both the spontaneous and the reflexly evoked slow waves and provided relaxation of the tracheal smooth muscle. Electrical stimulation of the distal nerve with a train pulse (0.5 ms, 1-30 Hz) evoked slow-wave oscillatory potentials accompanied by a contraction of the tracheal smooth muscle in all the experimental animals. Our observations in this in vivo study confirm that the electrical activity of tracheal smooth muscle consists of slow oscillatory potentials and that tracheal contraction is at least partly coupled to the slow-wave activity of the smooth muscle.     

Stimulation of H fields of Forel decreases total lung resistance in dogs

Although there is considerable evidence that the H fields of Forel of the posterior diencephalon play an important role in the regulation of cardiovascular function, little is known about the role these areas play in the control of airway caliber. In chloralose-anesthetized paralyzed dogs, we used both electrical and chemical means to stimulate the H fields of Forel, while we monitored breath-by-breath changes in total lung resistance (TLR), a functional index of airway caliber. Electrical stimulation (200-250 microA, 80 Hz, 0.75 ms) of 82 histologically confirmed sites significantly decreased TLR from 9.2 +/- 0.4 to 7.9 +/- 0.4 cmH2O.l-1.s (P less than 0.01). The bronchodilation evoked by electrical stimulation was unaffected by beta-adrenergic blockade with propranolol but was abolished by cholinergic blockade with atropine. The increases in airway caliber evoked by stimulation were often accompanied by increases in phrenic nerve activity. Chemical stimulation of 21 of 82 sites with microinjections of DL-homocysteic acid (83 nl, 0.2 and 0.5 M), which stimulates cell bodies but not fibers of passage, also decreased TLR from 8.3 +/- 0.5 to 7.3 +/- 0.5 cmH2O.l-1.s (P less than 0.03). We conclude that stimulation of cell bodies in the H fields of Forel produces bronchodilation by withdrawal of cholinergic tone to airway smooth muscle.     

隐神经C类纤维传入诱发小脑皮层电反应

当弱刺激只引起隐神经A类纤维传入时,小脑皮层出现A-CEP,由潜伏期为11.8±3.5ms的早成分和312.1±17.5ms的晚成分组成;当强刺激同时引起A类和C类纤维传入时,出现AC-CEP类似A-CEP;用极化电流选择性阻断A类纤维传导后,只让C类纤维传入时,出现潜伏期为134.2±18.4ms的C-CEP。在Ⅵ小叶蚓部原裂附近C-CEP以正波为主,幅值最大,并在深层位相倒转。C-CEP的潜伏期较长,频率响应较低,幅值较小,随C类纤维传入量而变化,且对镇痛剂较敏感。结果表明C-CEP是由单纯C类纤维传入引起的,在小脑皮层内产生,是小脑皮层对慢痛信息传入的反应。提示C类纤维传入可以到达小脑皮层,引起诱发电位。当A和C类纤维同时传入时,C-CEP不出现,可能是被A类纤维传入所抑制。