Nongenomic effect of levothyroxine on the synchronous electrical activity of the spinal dorsal horn in the rat

Levothyroxine (T₄) has a well-known effect on the central nervous system (CNS). This effect requires hours of latency by genetic pathway. We tested for short latency nongenomic effects of T₄ superfusion on the spinal dorsal horn (DH) evaluating lumbar somatosensory evoked potentials in rats. T₄ increased N and P wave amplitudes and N wave area under the curve, but reduced P wave duration and N–P interval, suggesting that T₄ exerts both excitatory and synchronizing effects on DH interneurons in less than 300?s, thus, providing evidence of nongenomic effects of T₄ on DH.     

Modulation of dorsal horn neuronal activity by spinal cord stimulation in a rat model of neuropathy: The role of the dorsal funicles

We recorded the spike activity from spinal neurons In rats with a model of neuropathy after ligation of then. ishiadicus. A significantly increased frequency of background discharges and responsiveness to nonnoxious stimuli were observed in dorsal horn wide-dynamic range (convergent) neurons in a group of allodynic rats, as compared with non-allodynic and intact rats. Spinal cord stimulation (SCS) Induced a significant depression of both the principal responses and afterdischarges in allodynic rats. The frequency of background discharges was markedly decreased in approximately one third of the neurons. These effects outlasted SCS by about 10 rain. The moderating effect of SCS is considered a result of activation of distinctly different and complementary mechanisms: segmental and transsupraspinal. The former appears to be the most important in allodynic animals.     

Quantitative autoradiographic analysis of [I]-human CGRP binding sites in the dorsal horn of rat following chronic constriction injury or dorsal rhizotomy

Quantitative receptor autoradiography was used to examine the binding of [¹²⁵I]-human CGRP in the dorsal horn of the L4 spinal segment of rats with a chronic constriction injury (CCI) of the sciatic nerve or unilateral dorsal rhizotomies of spinal segments L1–L6. At the times selected for study, we found no change in the amount of CGRP binding in any areas examined following CCI. In contrast, our results showed a temporally related increase in the amount of CGRP binding in areas within laminae I–II and in lateral lamina V of the dorsal horn ipsilateral to the rhizotomies. These results indicate that CGRP binding sites are regulated, most likely, by changes in the release of CGRP. Further, our results suggest that the release of CGRP from primary afferent neurons is unchanged in animals with a CCI.     

Fractalkine and minocycline alter neuronal activity in the spinal cord dorsal horn

Fractalkine (FKN) evokes nociceptive behavior in nai ve rats, whereas minocycline attenuates pain acutely after neuronal injury. We show that, in nai ve rats, FKN causes hyperresponsiveness of lumbar wide dynamic range neurons to brush, pressure and pinch applied to the hindpaw. One day after spinal nerve ligation (SNL), minocycline attenuates after-discharge and responses to brush and pressure. In contrast, minocycline does not alter evoked neuronal responses 10 days after SNL or sciatic constriction, but increases spontaneous discharge. We speculate that microglia rapidly alter sensory neuronal activity in nai ve and neuropathic rats acutely, but not chronically, after injury.     

Neurochemistry of the dorsal horn

The dorsal horn region of the spinal cord, particularly the dorsal root entry zone (DREZ), represents the first central integration center for nociceptive afferent impulses. Here, the excitatory neurotransmitters/modulators, products of the primary sensory neurons, are released, the segmental interneuronal influences pertain, and the descending bulbospinal tracts terminate. A vast variety of compounds are thus involved in the processing of nociceptive information in these areas, among which are the 'classical' neurotransmitters and the more recently described neuropeptides. A continued vast interest exists concerning the chemistry of the dorsal horn/DREZ region. The current developments and understanding regarding the pharmacology of this region are presented. Particular emphasis is given to the interactions among the various compounds, the coexistence of some of these within single neuronal populations, the importance of the opiate receptor subtypes, and the actions and localizations of some of the newly discovered neuropeptides.     

Slow excitatory transmission in rat spinal dorsal horn and the effects of capsaicin

High intensity repetitive stimulation of a dorsal root elicited slow depolarization in more than half of the dorsal horn neurons examined in the rat spinal cord slice preparation. There was a significantly smaller group of neurons showing slow hyperpolarization as well. Slow depolarization was not observed when synaptic activity was blocked by perfusing the slice with a TTX- or a low-Ca2+ high-Mg2+ solution. This result is consistent with a presynaptic origin of the slow response. Capsaicin treatment of neonatal rats significantly reduced the incidence of slow depolarization, suggesting that the slow depolarization was generated by small diameter afferent fibres, probably unmyelinated afferents. DR-evoked slow depolarization and SP-induced depolarization were similar in several important aspects: a) Both responses caused depolarization and increased the excitability of dorsal horn neurons; b) They were frequently associated with similar membrane conductance changes; c) The size of both responses varied in parallel when the membrane potential was shifted over a wide range; d) Both responses were markedly reduced or abolished by an analogue of SP having antagonist properties, and by polyclonal and monoclonal antibodies to SP; e) The depression of the DR-elicited slow depolarization during and after the SP-induced depolarization suggested that SP and the natural transmitter for the DR-elicited slow depolarization were bound to the same receptors. The results suggest that SP or, SP-like peptide, is an agonist that mimics in some aspects the action on the natural transmitter for the slow depolarizing potential.     

Chronic pregabalin inhibits synaptic transmission between rat dorsal root ganglion and dorsal horn neurons in culture

In this study, we have examined the properties of synaptic transmission between dorsal root ganglion (DRG) and dorsal horn (DH) neurons, placed in co-culture. We also examined the effect of the anti-hyperalgesic gabapentinoid drug pregabalin (PGB) at this pharmacologically relevant synapse. The main method used was electrophysiological recording of excitatory post synaptic currents (EPSCs) in DH neurons. Synaptic transmission between DRG and DH neurons was stimulated by capsaicin, which activates transient receptor potential vanilloid-1 (TRPV1) receptors on small diameter DRG neurons. Capsaicin (1 μM) application increased the frequency of EPSCs recorded in DH neurons in DRG-DH co-cultures, by about 3-fold, but had no effect on other measured properties of the EPSCs. There was also no effect of capsaicin in the absence of co-cultured DRGs. Application of PGB (100 μM) for 40-48 h caused a reduction in the capsaicin-induced increase in EPSC frequency by 57%. In contrast, brief preincubation of PGB had no significant effect on the capsaicin-induced increase in EPSC frequency. In conclusion, this study shows that PGB applied for 40-48 h, but not acute application inhibits excitatory synaptic transmission at DRG-DH synapses, in response to nociceptive stimulation, most likely by a presynaptic effect on neurotransmitter release from DRG presynaptic terminals.     

Chronic pregabalin inhibits synaptic transmission between rat dorsal root ganglion and dorsal horn neurons in culture

In this study, we have examined the properties of synaptic transmission between dorsal root ganglion (DRG) and dorsal horn (DH) neurons, placed in co-culture. We also examined the effect of the anti-hyperalgesic gabapentinoid drug pregabalin (PGB) at this pharmacologically relevant synapse. The main method used was electrophysiological recording of excitatory post synaptic currents (EPSCs) in DH neurons. Synaptic transmission between DRG and DH neurons was stimulated by capsaicin, which activates transient receptor potential vanilloid-1 (TRPV1) receptors on small diameter DRG neurons. Capsaicin (1 μM) application increased the frequency of EPSCs recorded in DH neurons in DRG-DH co-cultures, by about 3-fold, but had no effect on other measured properties of the EPSCs. There was also no effect of capsaicin in the absence of co-cultured DRGs. Application of PGB (100 μM) for 40–48 h caused a reduction in the capsaicin-induced increase in EPSC frequency by 57%. In contrast, brief preincubation of PGB had no significant effect on the capsaicin-induced increase in EPSC frequency. In conclusion, this study shows that PGB applied for 40–48 h, but not acute application inhibits excitatory synaptic transmission at DRG-DH synapses, in response to nociceptive stimulation, most likely by a presynaptic effect on neurotransmitter release from DRG presynaptic terminals.     

大鼠急性低氧模型尿液蛋白质组的变化

本研究旨在探究急性低氧对大鼠尿液蛋白质组造成的影响。在该项研究中,大鼠被放置于模拟海拔5 000 m高原环境的低氧舱内24 h。在低氧后0、12、24 h收集尿液样本,并使用液相色谱-串联质谱技术（LC-MS/MS）对尿蛋白进行分析。与低氧0 h相比,低氧12 h组共鉴定到144个差异蛋白,低氧24 h组共鉴定到129个差异蛋白。功能分析显示,差异蛋白参与了一系列与低氧应激有关的生物学通路,如抗氧化应激、糖酵解、补体和凝血级联反应等。研究结果表明,尿液蛋白质组可以反映急性低氧刺激后的显著变化。这些发现可能提供了一种判断机体缺氧状态的方法,有助于辅助检测缺氧状态。     

Glutamate-immunoreactivity in the trigeminal and dorsal root ganglia, and intraspinal neurons and fibres in the dorsal horn of the rat

Summary Putative aspartergic and glutamatergic sensory neurons in the rat were identified by autoradiography and immunocytochemistry respectively. Approximately 3% of large L₄ dorsal root ganglion neurons (diameter 18–52 m) accumulated radiolabelled aspartate, whereas all satellite glia had high affinity for the amino acid. Glutamate-immunofluorescent (Glu-FITC) dorsal root ganglia neurons comprised 38.3% at S₁, 35.6% at L₂ 33.9% at C₅ and 28.8% at T₆. Numbers of immunoreactive neurons were higher with the more sensitive peroxidase-anti-peroxidase (Glu-PAP) method; and the cell counts totalled 42% (S₁), 41.2% (L₄), 35% (C₅) and 34.6% (T₆). The trigeminal ganglion (TG) contained 24% Glu-FITC and 32.3% Glu-PAP positive cells. The majority of glutamate-immunoreactive sensory neurons were small, ranging from 10–35 m with median diameters of 17.5m (C₅), 21m (S₁), 24.2m (TG) and 28.5 m (L₂). It is evident therefore, that a subgroup of class B cells are glutamatergic. Glutamate immunoreactivity in the spinal cord was similar in all segments and was localized in the superficial lamina and substantia gelatinosa of the dorsal horn. Stained interneurons were located among the immunoreactive fibres. The dorsolateral funiculus contained dense plexus of immunoreactive fibres which increased in prominence after intraperitoneal injection of L-glutamate, but penetration of exogenous glutamate into the grey matter was limited. Instead, the meninges and basal layers of the spinal blood vessels were intensely immunoreactive. The studies describe the subtypes of acidic amino acidergic neurons and relates the immunohistochemistry to a functional subclass.     

Synaptic connections of the neurokinin 1 receptor-like immunoreactive neurons in the rat medullary dorsal horn

The synaptic connections between neurokinin 1 (NK1) receptor-like immunoreactive (LI) neurons and γ-aminobutyric acid (GABA)-, glycine (Gly)-, serotonin (5-HT)- or dopamine-β-hydroxylase (DBH, a specific marker for norepinephrinergic neuronal structures)-LI axon terminals in the rat medullary dorsal horn (MDH) were examined under electron microscope by using a pre-embedding immunohistochemical double-staining technique. NK1 receptor-LI neurons were observed principally in laminae I and III, only a few of them were found in lamina II of the MDH. GABA-, Gly-, 5-HT-, or DBH-LI axon terminals were densely encountered in laminae I and II, and sparsely in lamina III of the MDH. Some of these GABA-, Gly-, 5-HT-, or DBH-LI axon terminals were observed to make principally symmetric synapses with NK1 receptor-LI neuronal cell bodies and dendritic processes in laminae I, II and III of the MDH. The present results suggest that neurons expressing NK1 receptor within the MDH might be modulated by GABAergic and glycinergic inhibitory intrinsic neurons located in the MDH and 5-HT- or norepinephrine (NE)-containing descending fibers originated from structures in the brainstem.     

Electron microscopic localization and experimental modification of NADPH-diaphorase activity in crustacean sensory axons

The origin and ultrastructural localization of NADPH-diaphorase (NADPH-d) in the olfactory afferent pathway of the crayfishPacifastacus leniusculus was investigated by means of histochemical techniques. Sensory axons in the antennular nerve and the olfactory lobe glomeruli of normal animals expressed NADPH-d staining properties. The NADPH-d staining of each glomerulus was regionalized showing pronounced staining in the apical cap-region. Following ablation of the chemosensory input for 30 days, the staining properties of the antennular nerve and the glomeruli were reduced. At the electron microscopic level, the NADPH-d precipitate was found to be distributed on various membranes in neuronal profiles and glial cells. Stained neuronal profiles were frequently observed in the glomeruli, whereas the number of positive glial cells was low. Almost all NADPH-d positive profiles in the neuropil had an intraglomerular localization. The present findings suggest that NADPH-d in the crayfish olfactory lobe neuropil is localized to terminals of olfactory sensory axons.     

大鼠脊髓背角神经元痛放电确定性行为的年龄相关变化

为阐明脊髓背角神经元痛放电的年龄相关的动力学变化,本研究采用非线性预报方法,对两组不同年龄大鼠(成年青龄鼠3～4月龄,老年鼠＞22月龄)组织损伤诱发的脊髓背角神经元痛放电峰峰间期序列进行了确定性行为的定量分析.结果显示,皮下注入蜜蜂毒,在两组大鼠均诱发脊髓背角广动力域神经元长时程放电,而老龄大鼠的痛放电峰峰间期序列表现出更高的可确定性.本研究表明,单个神经元的痛放电动力学在整个生命过程中并不是恒定不变的,伤害性神经元活动的年龄相关动力学变化可能是老年人群中多样化痛反应的内在机制之一.