Chloramine-T alters the nerve membrane birefringence response

Summary The change in birefringence during depolarizing voltage-clamp pulses of internally perfused squid giant axons are biphasic. There is a rapid decrease in birefringence with a 220-sec half time at 8°C followed by a slow decrease over the next several milliseconds. After the pulse there is a rapid recovery which is smaller than the initial rapid decrease followed by a slow recovery phase. The rate of change of the slow phase during the pulse is more rapid for larger depolarizations. After the pulse the rate of change is more rapid for more negative potentials.3.6mm chloramine-T, applied externally until the sodium currents were prolonged and inactivation was removed, removed the slow phase of the birefringence response both during and after the pulse and made the fast off response as large as the fast on response. Two anesthetics reduced the birefringence response by about 20%.A rocking helix model is presented which relates the birefringence findings and earlier gating current experiments.     

Precursors for Cholesterol Synthesis (7-Dehydrocholesterol, 7-Dehydrodesmosterol, and Desmosterol): Cholesterol/7-Dehydrocholesterol Ratio as an Index of Development and Aging in PNS but Not in CNS

In rat sciatic nerve, the 7-dehydrocholesterol content decreased dramatically during the postnatal period and slowly during adulthood and aging. In contrast, the 7-dehydrodesmosterol content peaked at 14 days and was nearly undetectable after 60 days. The desmosterol content peaked at 21 days and was nearly undetectable after 1 year. The cholesterol content increased up to 21 days and remained nearly constant thereafter. In brain (in contrast to sciatic nerve), 7-dehydrodesmosterol and desmosterol contents decreased dramatically during development and slightly during adulthood and aging; the 7-dehydrocholesterol content peaked at 21 days and remained constant during aging. Only 7-dehydrocholesterol was dramatically more concentrated in PNS than in CNS. In brain, the cholesterol/7-dehydrocholesterol ratio increased during development and remained stable after 6 months. In contrast, in sciatic nerve, this ratio continuously increased during development and aging (950-fold between 5 days and 18 months). Thus, the cholesterol/7-dehydrocholesterol ratio is a useful biochemical index of development and aging in the PNS.     

Changes in α-Tubulin and Actin Gene Expression During Optic Nerve Regeneration in Frog Retina

The optic nerve of the bullfrog was transected and the regeneration process was investigated. We previously reported that alpha-tubulin mRNA in the retina increased to a maximum 1-2 h after optic nerve transection with no specific change in actin mRNA. In the present investigation, we examined the long-term effect of optic nerve transection. Northern blot analysis revealed that alpha-tubulin mRNA increased again gradually after the rapid and transient increase and actin mRNA increased to a maximum at 7 days (more than twofold compared to the control retinas). The period during which actin mRNA reaches a maximal increase almost corresponds to the time lag between the axotomy and the initiation of axonal outgrowth. The main cytoskeletons of neuronal growth cones have been shown to consist of actin-containing microfilaments. Therefore, the transient increase of actin mRNA may have a relationship to the initial outgrowth of axons. On the other hand, the rapid and transient increase of alpha-tubulin mRNA observed in our previous studies is probably one of the initial responses of retinal ganglion cells to the axotomy, and the gradual increase in alpha-tubulin mRNA observed in this study can probably be interpreted as provision of the structural materials necessary for axonal elongation.     

头端延髓腹外侧区在侧脑室注射新斯的明所致升压中的作用

实验在47只乌拉坦(700m/kg)、氯醛糖(35mg/kg)麻醉,肌肉麻痹,人工呼吸的家兔上进行。结果观察到,侧脑室注射(icv)新斯的明引起血压升高,心率(HR)先减慢后有加快趋势,股动脉血流量(FBF)与股动脉血管通道性(COND)减小,左心室内压(LVP)增大,肾交感神经放电(RND)增加,延髓腹外侧头端(rVLM)微量注射阿托品则引起血压下降,HR减慢,FBF与COND增加,LVP与RND减小,若在icv新斯的明之前,预先向rVLM注入阿托品,可阻断新斯的明的升压效应,上述结果提示,rVLM是icv新斯的明升压效应的重要部位,rVLM区M受体功能完整是这种升压作用的关键因素。     

家兔孤束核区微量注射羟基马桑毒素对膈神经放电的影响

实验在44只乌拉坦麻醉、肌肉麻痹、切断双侧颈迷走神经的日本大耳白兔上进行。于一侧孤束核区微量注射不同浓度(0.1μg/μl,1μg/μl,5μg/μl,10μg/μl)的羟基马桑毒素1μl,可以引起膈神经放电活动产生可逆的吸气时程和呼气时程缩短,呼吸频率加快及膈神经放电积分的峰幅度降低。羟基马桑毒素0.1μg/μl组作用最弱,1μl/μl组作用最强。5μg/μl组,10μg/μl组还可使膈神经放电活动在呼气期出现短时的吸气性放电及呼气期间歇性不规则延长等呼吸节律紊乱现象。出现上述现象时血压、心率无明显变化,脑电图也未出现异常改变。结果提示:家兔孤束核区参与呼吸时相的转换,而羟基马桑毒素可能作用于孤束核区的呼吸时相转换机制,促进呼吸时相的转换。     

心房钠尿多肽对麻醉大鼠血压和肾神经传出放电的影响

本实验观察了心房肽Ⅱ(Atriopeptin Ⅱ,APⅡ)对麻醉大鼠血压(AP)、心率(HR)和肾交感神经传出放电(RSNA)的影响,并与硝普钠对 AP 和 RSNA 的影响作比较。结果如下:(1)缓冲神经完整和迷走神经完整条件下(n=12)静脉注射 APⅡ(50μg/kg)后,动脉收缩压(SAP)降低23.0±1.66 mmHg(Μ±SE,p<0.001),HR 减慢9±3.5b/min(p<0.05),RSNA 降低4.89±2.95%(P>0.05)。迷走神经切断后,静脉注射 APⅡ引起的~⊿SAP 虽有所减小,但与切断迷走神经前的反应比较,无统计学意义,HR 减慢不再出现,而 RSNA 则有所增加;(2)缓冲神经切断和迷走神经完整条件下(n=7),静脉注射 APⅡ时 SAP 降低27.4±3.25mmHg(P<0.001),HR 减慢13±3.1b/min(P<0.01),RSNA 降低11.67±1.95%(P<0.001)。切断迷走神经后,静脉注射 APⅡ引起的 SAP 降低程度有明显減小(P<0.01),HR减慢不再出现,RSNA 则反而增加(3)无论在迷走神经完整还是切断条件下,静脉注射硝普钠(n=6) SAP 均明显降低,同时伴有 RSNA 的反射性增加。以上结果表明:APⅡ的降压效应,部分是通过迷走神经传入纤维;在切断缓冲神经条件下,APⅡ可经由迷走神经传入纤维的激活而反射地抑制 RSNA。     

Storage proteins are present in the hemolymph from larvae and adults of the Colorado potato beetle.

The protein composition of larval and adult hemolymph from the Colorado potato beetle, Leptinotarsa decemlineata, was investigated and some abundant, high molecular weight proteins were identified and characterized. Diapause protein 1, which occurs in the hemolymph of last instar larvae and short-day adults, appeared to be a storage protein. This protein dissociated into two bands due to the high pH used in nondenaturing gels. Its quaternary structure was established by chemical crosslinking. It appeared to be a hexamer. Diapause protein 1 is composed of approximately 82,000 subunits. The amino acid composition and N-terminal sequence of this protein has been determined. Specific antibodies against diapause protein 1 have been developed. Topical application of 1 microgram pyriproxyfen, a juvenile hormone analog, to last instar larvae and short-day adults suppressed the appearance of this protein in the hemolymph. Pyriproxyfen prematurely induced vitellogenin, when applied to last instar larvae. A larval specific protein was also identified in the hemolymph. Its temporary appearance in the hemolymph of last instar larvae, its subunit composition (M(r) approximately 82,000) and its suppression by pyriproxyfen suggests that this protein is a storage protein as well.     

Trophic factor effects on cholinergic innervation in the cerebral cortex of the adult rat brain

The cholinergic pathway ascending from the nucleus basalis magnocellularis (NBM) to the cortex has been implicated in several important higher brain functions such as learning and memory. Following infarction of the frontoparietal cortical area in the rat, a retrograde atrophy of cholinergic cell bodies and fiber networks occurs in the basalocortical cholinergic system. We have observed that neuronal atrophy in the NBM induced by this lesion can be prevented by intracerebroventricular administration of exogenous nerve growth factor (NGF) or the monosialoganglioside GM₁. In addition, these agents can upregulate levels of cortical choline acetyltransferase (ChAT) activity in the remaining cortex adjacent to the lesion site. Furthermore, an enhancement in cortical high-affinity³H-choline uptake and a sustained in vivo release of cortical acetylcholine (ACh) after K⁺ stimulation are also observed after the application of neurotrophic agents. Moreover, these biochemical changes in the cortex are accompanied by an anatomical remodeling of cortical ChAT-immunoreactive fibers and their synaptic boutons.     

正常小儿胫神经诱发脊髓电位特征和脑瘫小儿该电位的变化

采取刺激后胫神经(PTN)诱发叠加技术,利用体表无创伤性双极记录方法观察了16例正常小儿和43例脑瘫小儿的脊髓诱发电位(SCEP)。正常小儿的SCEP自下而上潜伏时逐渐延长、电压减小。从椎体C6到T10表现为Pa-Na-Pb三相波,T10～T12为Pa-Na1-Na2-Pb波,T12～L4为多相复合波。左右侧SCEP波形相似,潜伏时、电压相同,它们之间无统计学显著差别;但不同节段之间SCEP差异显著;脊髓传导速度为57.14m/s。脑瘫小儿SCEP正常者占14％;全髓反应低下者占20％;左右侧反应不对称者占46％;节段性反应低下者占15％;其它异常约占5％。不但节段间存在显著差异,而且全脊髓左右侧电压间以及颈、腰骶髓的潜伏时间出现显著差异。脊髓传导速度减低(患侧46.22m/s,对侧53.48m/s)。结果提示:(1)正常小儿脊髓活动左右对称,不同脊髓节段对PTN刺激反应不同。(2)脑瘫小儿脊髓活动左右不对称,一侧功能下降时对侧有一定代偿力,脊髓传导速度减慢。     

Alterations in the morphology of ganglion cell dendrites in the adult rat retina after optic nerve transection and grafting of peripheral nerve segments

Summary Transected ganglion cell axons from the adult retina are capable of reinnervating their central targets by growing into transplanted peripheral nerve (PN) segments. Injury of the optic nerve causes various metabolic and morphological changes in the retinal ganglion cell (RGC) perikarya and in the dendrites. The present work examined the dendritic trees of those ganglion cells surviving axotomy and of those whose severed axons re-elongated in PN grafts to reach either the superior colliculus (SC), transplanted SC, or transplanted autologous thigh muscle. The elaboration of the dendritic trees was visualized by means of the strongly fluorescent carbocyanine dye DiI, which is taken up by axons and transported to the cell bodies and from there to the dendritic branches. Alternatively, retinofugal axons regrowing through PN grafts were anterogradely filled from the eye cup with rhodamine B-isothiocyanate. The transection of the optic nerve resulted in characteristic changes in the ganglion cell dendrites, particularly in the degeneration of most of the terminal and preterminal dendritic branches. This occurred within the first 1 to 2 weeks following axotomy. The different types of ganglion cells appear to vary in their sensitivity to axotomy, as reflected by a rapid degeneration of certain cell dendrites after severance of the optic nerve. The most vulnerable cells were those with small perikarya and small dendritic fields (type II), whereas larger cells with larger dendritic fields (type I and III) were slower to respond and less dramatically affected. Regrowth of the lesioned axons in peripheral nerve grafts and reconnection of the retina with various tissues did not result in a significant immediate recovery of ganglion cell dendrites, although it did prevent some axotomized cells from further progression toward posttraumatic cell death.