刺激兔下丘脑室旁核诱发的心律失常与增压反应

在60只局麻与肌松剂制动的家兔,观察到用0.1—0.4mA,50Hz,1ms 的方波电刺激下丘脑室旁核(PV)能诱发频发性心律失常(包括室性与室上性期前收缩)及显著的动脉血压升高。与同侧的下丘脑外侧区(LHA)及腹内侧核(VMH)相比,刺激PV诱发期前收缩的次数更为频繁,增压反应幅度较大,且所需阈值亦较低。较低强度刺激LHA 在部分兔能引起血压下降与心率减慢,而PV 则一致地诱发增压反应。电刺激腓深神经能抑制刺激PV诱发的期前收缩,但在中脑中央灰质微量注射吗啡或电解毁损只能完全阻断刺激VMH诱发的期前收缩,而不能完全阻断PV诱发的期前收缩。这些结果提示,PV是下丘脑中诱发心律失常与血压增高的高反应区之一,并且可能具有不同于LHA或VMH的神经机制或下行神经通路。     

电刺激兔下丘脑视前内侧区对Oddi氏括约肌肌电的影响

下丘脑是内脏神经的较高级中枢。它对胃肠和心血管话动都具有重要的调整作用。关于下丘脑对胆道系统话动的调整作用在国内、外报道较少。近年来我们研究组分别报道了电刺激兔下丘脑前区、内侧区对胆汁流量、胆囊压力有明显的影响。本组实验是观察电刺激兔下丘脑视前内侧区(MPO)对Oddi氏括约肌肌电活动的影响,并初步分析引起这种变化的机制。     

安定降低家兔血压和减少刺激下丘脑诱发室性期前收缩的机制分析

家兔62只,用乌拉坦(700mg/kg)和氯醛醣(35mg/kg)静脉麻醉,三碘季铵酚制动,在人工呼吸下进行实验。用电刺激下丘脑近中线区的方法诱发室性期前收缩(HVE)。静脉注射安定(0.5mg/kg)可降低基础血压(BP),减弱刺激下丘脑引起升压反应(指收缩压峰值SBP_(max))和减少HVE。在双侧延髓腹外侧头端区(rVLM)微量注射氟安定(200μg溶于0.5μl中),γ-氨基丁酸(GABA)(6μg溶于0.5μl中)均能降低BP、SBP_(max)和减少HVE,若微量注射印防己毒素(7.5μg溶于0.5μl中)则可使BP上升并增多HVE。而于双侧延髓腹外侧尾端区(cVLM)微量注射同样剂量氟安定、GABA则无上述反应。安定降低BP、SBP_(max)和减少HVE的作用可被双侧rVLM区微量注射GABA受体拮抗剂荷包牡丹碱(3μg溶于0.5μl中)或印防己毒素所消除,但在双侧rVLM区微量注射甘氨酸受体拮抗剂士的宁(1μg溶于0.5μl中)、阿片受体拮抗剂纳洛酮(0.5μg溶于0.5μl中)、胆碱能阻断药阿托品(0.25μg溶于0.5μl中)、东莨菪碱(1.5μg溶于0.5μl中)后仍然存在。 上述结果提示,在双侧rVLM应用GABA受体拮抗剂可消除安定降低BP、SBP_(max)和减少HVE的作用,安定降低BP、SBP_(max)和减少HVE的作用可能通过GABA这一中间环节,而胆碱能受体、阿片受体、甘氨酸受体可能不起重要作用。     

大鼠腹腔迷走神经切除能阻断胆囊收缩素引起的饱作用

胆囊收缩素(CCK)既在中枢神经系统又在胃肠道内存在。据报道,由中枢或外周给予CCK可以在动物和人类引起饱感;但产生这一作用的部位一直有争论。中枢给予CCK-8(CCK羧基端八肽),推测是作用于脑内CCK受体。以前认为外周给予CCK-8通过血循环也作用于大脑,特别是下丘脑腹内侧核区域(简称VMH)。但也有资料报道,损毁大鼠两侧下丘脑VMH区后,由外周给予CCK-8仍可引起饱作用。最近G.P Smith等用大鼠观察了外周给予CCK-8引起饱作用的部位。他们先把大鼠分为两组:一组大鼠毁损两侧下丘脑VMH区;另一组大鼠施行腹腔内迷走神经切除术。然后分别向两组大鼠腹腔内注     

Leptin对下丘脑LHA、VMH、PVN的RNA含量和体脂肪的影响

目的:探讨Leptin对下丘脑外测区(LHA)、腹内侧核(VMH)和室旁核(PVN)的RNA含量和脂肪沉积的影响.方法:通过小鼠注射Leptin,连续注射14d,70日龄时将动物宰杀,取LHA、VMH和PVN的组织,用荧光显微数字成像系统和Image Pro plus图像分析,测RNA.结果:Leptin引起生长期小鼠LHA和VMH的RNA含量显著增高(P＜0.01、P＜0.05),PVN的RNA含量降低,腹腔脂肪沉积显著减少(P＜0.05).结论:Leptin能引起LHA和VMH的功能加强,且两者都均与腹腔脂肪沉积呈负相关.     

在清醒家兔中电针对刺激下丘脑引起的防御反应的抑制作用

在清醒家兔中电刺激下丘脑背内侧区可引起血压升高、肾交感神经放电增加、心率减慢等一系列防御反应的表现。用低频电脉冲刺激一侧“足三里”穴20min,可明显抑制刺激下丘脑引起的防御反应。这种抑制效应在停止电针后仍能持续一段时间,但可被静脉内注射纳洛酮(0.4mg/kg)翻转。预先注射纳洛酮也能防止电针的抑制效应。损毁下丘脑基底部包括弓状核在内的局部区域后,电针对防御反应的抑制作用基本消失。在弓状核区微量注射 L-谷氨酸钠(50mM,1μl)也可抑制刺激下丘脑引起的防御反应。这种抑制效应同样可被静脉内注射纳洛酮翻转。以上实验结果表明,电针可抑制刺激下丘脑引起的防御反应,弓状核区的内啡肽神经元可能在电针对防御反应的抑制效应中起重要的作用。     

下丘脑外侧区注入胃泌素对大鼠胃酸分泌的影响

本工作观察了下丘脑外侧区(LHA)、腹内侧核(VMH)或侧脑室(LCV)注射17肽胃泌素(G17)或五肽胃泌素(G5)对清醒大鼠胃酸分泌的影响。结果表明,将 G17或 G5注入 LHA可引起胃酸分泌明显增加,而将 G5注入 VMH、LCV 或静脉则不影响胃酸分泌;切断迷走神经可以阻断在 LHA 注入 G5引起胃酸分泌增加的效应;在阿托品背景下,将 G5注入 LHA仍能引起胃酸分泌明显增加;静脉注射酚妥拉明,心得安或纳洛酮均不影响 G5对 LHA 刺激胃酸分泌的作用。这些结果提示:LHA 是胃泌素作用的一个特异性部位,由 LHA 发出的冲动可能通过迷走神经内的两种传出纤维引起胃酸分泌,一为胆碱能纤维,另一为非胆碱能非肾上腺素能纤维。     

对家兔浅下颌腺分泌的初步研究

目前国内外对家免浅下颌腺的研究甚少,对其功能和分泌物的研究则未见报道。我们曾发现静脉脉注射垂体后叶素和电刺激下丘脑某些核团如下丘脑背内侧核(N.dorsomedialis hypothalami,DMH)和下丘脑前区(An(?)erior hypothalamic area,AHA)能引起此腺体分泌。在此基础上我们进行了进一步研究。     

太鼠坐骨神经、胫神经、腓总神经在脊髓胶状质定位投射的定量分析—FRAP 法

本实验按照跨神经节溃变的原理,用抗氟化物酸性磷酸酶(FRAP)法和显微测量,对大鼠坐骨神经,胫神经和腓总神经感觉纤维在脊髓胶状质的定位投射进行了定量分析。大鼠坐骨神经和胫神经向胶状质的纵向投射为 L_(2～3);腓总神经为 L_(2.6)及 S_1的上中部。水平向投射,坐骨神经:L_(2～3)主要为胶状质的最内侧和中间区的部分区域,L_4～S_1,主要为内侧,中间和部分外侧区的全部胶状质,但未见向胶状质最外侧区投射;胫神经:L_2～S_1主要为内侧区,中间及部分外侧区仅部分实验动物有投射;腓总神经:仅向 L_2～S_1的中间和部分外侧区一处投射。     

刺激腓深神经对低血压或休克狗心血管活动的影响

实验在麻醉狗中进行。静脉内匀速注射硝普钠时,平均动脉压和左心室收缩压明显降低,左心室dp/dt_(max)、-dp/dt_(max)和心力环面积均明显减小。此时电刺激一侧腓深神经可使动脉血压和左心室收缩压明显升高,dp/dt_(max)和心力环面积也显著增加。停止刺激后,动脉血压和左心室收缩压逐渐回向刺激前的水平。停止注射硝普钠5～15分钟后,上述各项观察指标基本恢复到注药前的水平。在用大肠杆菌内毒素造成休克的狗中,电刺激一侧腓深神经,也能使平均动脉压和左心室收缩压升高,同时dp/dt_(max)、-dp/dt_(max)和肠系膜血管阻力明显增高,但肾血管阻力增加不明显。本实验结果与以往的实验资料一起表明,在用扩血管药造成低血压时,躯体神经刺激引起的升压效应似乎以心肌收缩力增加为主;而在内毒素休克时,躯体神经刺激可通过改善心肌收缩功能和增加内脏血管阻力而引起升压作用。     

迷走神经对家兔在体心脏心室肌细胞跨膜电位的影响

本研究观察了电刺激迷走神经对家兔在体心脏心室肌细胞跨膜电位的作用及钾通道阻滞剂氯化四乙基铵对这一作用的影响。结果表明,在自然心率条件下,迷走神经刺激可使静息电位(RP)、动作电位振幅(APA)和0相最大上升速率(dv/dt)_(max)增加,动作电位时程(APD)缩短。冠脉注射氯化四乙基铵使心室肌细胞复极过程明显延长,迷走神经刺激不再引起 RP、APA 增大,动作电位时程不再缩短,(dv/dt)_(max)反而减小。这些结果提示,迷走神经刺激对正常心室肌细胞跨膜电位的影响可能是通过外向 K~ 流增加引起的。     

家兔急性缺血早期心室肌细胞跨膜电位的变化及迷走神经的保护作用

以在体家兔的心脏为对象,应用浮置微电极技术研究了急性缺血早期心室肌细胞跨膜电位的变化及迷走神经的保护作用。 冠状动脉的一个分支阻断后 1—5min,静息电位(RP)、动作电位振幅(APA)和 0相最大上升速率(dv/dt)_(max)均减小(P<0.01)。动作电位时程APD_(30)、APD_(50)和APD_(90)均缩短(P<0.01)。反映 2相平台时程的 APD_(30)和 APD_(50)缩短较总时程 APD_(90)的缩短更明显。 在自然心率的条件下,左颈迷走神经电刺激,可使急性缺血的心肌电位的变化有所恢复:RP、APA、(dv/dt)_(max)均增加,APD_(30)、APD_(50)、APD_(90)延长(P_均<0.01)。刺激迷走神经时缺血的心室肌细胞跨膜电位有所恢复,对防止缺血早期的室性心律失常可能具有重要作用。     

Effects of sequential biventricular pacing during acute right ventricular pressure overload

Temporary sequential biventricular pacing (BiVP) is a promising treatment for postoperative cardiac dysfunction, but the mechanism for improvement in right ventricular (RV) dysfunction is not understood. In the present study, cardiac output (CO) was optimized by sequential BiVP in six anesthetized, open-chest pigs during control and acute RV pressure overload (RVPO). Ventricular contractility was assessed by the maximum rate of increase of ventricular pressure (dP/dt(max)). Mechanical interventricular synchrony was measured by the area of the normalized RV-left ventricular (LV) pressure diagram (A(PP)). Positive A(PP) indicates RV pressure preceding LV pressure, whereas zero indicates complete synchrony. In the control state, CO was maximized with nearly simultaneous stimulation of the RV and LV, which increased RV (P = 0.006) and LV dP/dt(max) (P = 0.002). During RVPO, CO was maximized with RV-first pacing, which increased RV dP/dt(max) (P = 0.007), but did not affect LV dP/dt(max), and decreased the left-to-right, end-diastolic pressure gradient (P = 0.023). Percent increase of RV dP/dt(max) was greater than LV dP/dt(max) (P = 0.014). There were no increases in end-diastolic pressure to account for increases in dP/dt(max). In control and RVPO, RV dP/dt(max) was linearly related to A(PP) (r = 0.779, P < 0.001). The relation of CO to A(PP) was curvilinear, with a peak in CO with positive A(PP) in the control state (P = 0.004) and with A(PP) approaching zero during RVPO (P = 0.001). These observations imply that, in our model, BiVP optimization improves CO by augmenting RV contractility. This is mediated by changes in mechanical interventricular synchrony. Afterload increases during RVPO exaggerate this effect, making CO critically dependent on simultaneous pressure generation in the RV and LV, with support of RV contractility by transmission of LV pressure across the interventricular septum.     

Effects of ventromedial and lateral hypothalamic stimulation on chemically-induced liver injury in rats

The effects of hypothalamic stimulation on experimental liver injury induced by carbon tetrachloride (CCl4) or dimethylnitrosamine (DMN) were studied in rats, by measuring plasma alanine aminotransferase (ALT) activity as an index of acute liver injury. Electrical stimulation of the ventromedial hypothalamus (VMH) in CCl4-treated rats caused a marked increase in plasma ALT activity, accompanied by a significant decrease in ALT activity in the liver, although CCl4 treatment alone had no significant effect on plasma ALT activity. A similar effect of VMH stimulation on plasma ALT activity was observed in rats treated with DMN, another hepatotoxic chemical. No such exaggerated effect of VMH stimulation on plasma ALT activity was observed after stimulation of the lateral hypothalamic area (LH). Surgical sympathetic denervation of the liver greatly suppressed the increase in plasma ALT activity after CCl4 injection and VMH stimulation. Measurement of regional blood flow indicated that VMH stimulation did not produce a significant change in blood flow to the liver. These results suggest that the VMH is involved in the progress of chemically-induced liver injury through activation of the sympathetic nerve (hepatic nerves), possibly by affecting liver metabolism more than the blood flow change to the liver.     

Decrease in maximal voluntary contraction by tonic vibration applied to a single synergist muscle in humans.

The purpose of the study was to examine the effect of prolonged tonic vibration applied to a single synergist muscle on maximal voluntary contraction (MVC) and maximal rate of force development (dF/dt(max)). The knee extension MVC force and surface electromyogram (EMG) from the rectus femoris (RF), vastus lateralis (VL), and vastus medialis (VM) during MVC were recorded before and after vibration of RF muscle at 30 Hz for 30 min. MVC, dF/dt(max), and the integrated EMG (iEMG) of RF decreased significantly after prolonged tonic vibration in spite of no changes in iEMG of VL and VM. The present results indicate that MVC and dF/dt(max) may be influenced by the attenuated Ia afferent functions of a single synergist muscle.     

Validation of a novel noninvasive cardiac index of left ventricular contractility in patients

Although there are several excellent indexes of myocardial contractility, they require accurate measurement of pressure via left ventricular (LV) catheterization. Here we validate a novel noninvasive contractility index that is dependent only on lumen and wall volume of the LV chamber in patients with normal and compromised LV ejection fraction (LVEF). By analysis of the myocardial chamber as a thick-walled sphere, LV contractility index can be expressed as maximum rate of change of pressure-normalized stress (d sigma*/dt(max), where sigma* = sigma/P and sigma and P are circumferential stress and pressure, respectively). To validate this parameter, d sigma*/dt(max) was determined from contrast cine-ventriculography-assessed LV cavity and myocardial volumes and compared with LVEF, dP/dt(max), maximum active elastance (E(a,max)), and single-beat end-systolic elastance [E(es(SB))] in 30 patients undergoing clinically indicated LV catheterization. Patients with different tertiles of LVEF exhibit statistically significant differences in d sigma*/dt(max). There was a significant correlation between d sigma*/dt(max) and dP/dt(max) (d sigma*/dt(max) = 0.0075 dP/dt(max) - 4.70, r=0.88, P<0.01), E(a,max) (d sigma*/dt(max) = 1.20E(a,max) + 1.40, r=0.89, P<0.01), and E(es(SB)) [d sigma*/dt(max)=1.60 E(es(SB)) + 1.20, r=0.88, P<0.01]. In 30 additional individuals, we determined sensitivity of the parameter to changes in preload (intravenous saline infusion, n = 10 subjects), afterload (sublingual glyceryl trinitrate, n = 10 subjects), and increased contractility (intravenous dobutamine, n=10 patients). We confirmed that the index is not dependent on load but is sensitive to changes in contractility. In conclusion, d sigma*/dt(max) is equivalent to dP/dt(max), E(a,max), and E(es(SB)) as an index of myocardial contractility and appears to be load independent. In contrast to other measures of contractility, d sigma*/dt(max) can be assessed with noninvasive cardiac imaging and, thereby, should have more routine clinical applicability.     

Determination of cardiac contractility in awake unsedated mice with a fluid-filled catheter

Today, cardiac contractility in mice is exclusively measured under anesthesia or in sedated animals because the catheters available are too rigid to be used in awake mice. We therefore developed a new catheter (Pebax 03) to measure cardiac contractility in conscious mice. In this study, we evaluated the accuracy and utility of this new catheter for assessment of cardiac contractility in anesthetized and conscious mice. With the use of a balloon-pop test, the Pebax catheter with an inner diameter of 0.3 mm was found to exhibit a high natural frequency, a low damping coefficient, and a flat frequency of up to 50.5 +/- 0.6 Hz. Under anesthesia (0.5% or 1.0% halothane), no difference was found in heart rate (HR), left ventricular (LV) systolic pressure (LVSP), the maximum rates of LV pressure rise and fall (LV dP/dt(max) and LV dP/dt(min), respectively), ejection time (ET), and isovolumic relaxation time constant (tau) when measured with either the 1.4-Fr Millar or Pebax 03 catheter. However, when HR, LVSP, LV dP/dt(max), and LV dP/dt(min) were recorded with the Pebax catheter in awake mice, values were significantly higher, and ET and tau were lower, than under anesthesia, suggesting a major impact of anesthesia on these parameters. The Pebax catheter was also used in a normotensive one-renin gene mouse model of cardiac hypertrophy induced by DOCA and salt. In this model, DOCA-salt induced a severe decrease in cardiac contractility in the absence of changes in blood pressure. These data demonstrate that cardiac contractility can be measured very accurately in conscious mice. This new device can be of great help in the investigation of cardiac function in normal and genetically engineered mice.     

长期大强度运动对大鼠脑组织神经肽Y、亮氨酸脑啡肽、强啡肽A_(1-13)动态变化的影响

目的和方法：采用ＡＢＣ免疫组织化学法结合图象分析,观察大鼠脑组织神经肽Ｙ、亮氨酸脑啡肽、强啡肽Ａ１１３ 在长期（ 共７ 周）大强度（速度由１５ ｍ／ｍｉｎ 递增至３５ ｍ／ｍｉｎ、运动时间为２０ ～２５ ｍｉｎ／ｄ） 的运动下的变化。结果：安静状态下在丘脑室旁核（ＰＶ） 、下丘脑背内侧核（ＤＭ） 、下丘脑腹内侧核（ＶＭＨ）等核团ＮＰＹ 无显著性变化;在此基础上的末次急性运动结束后３ ｈ ＮＰＹ 变化尤为明显。安静状态下大鼠尾壳核ＬＥＮＫ 下降;而末次急性运动后大鼠下丘脑ＬＥＮＫ 被迅速激活而升高。该强度运动能激活下丘脑ＤＹＮＡ１１３ ,尤以运动结束后３０ ｍｉｎ 最为明显。结论： ＮＰＹ、ＬＥＮＫ、ＤＹＮＡ１１３ 在该强度运动下大鼠不同脑区呈现不同变化趋势