Timecourse for receptive field plasticity following spinal cord hemisection

Previously, we demonstrated that between 5 days and 3 months following a partial spinal cord hemisection, proximal hindlimb receptive fields of neurons in the ipsilateral L7 dorsal horn of cats become enlarged. In this study, we used somatotopic mapping procedures, applied bilaterally, to demonstrate that this change in receptive field size occurs between 10 and 14 days postoperatively.     

Electrical stimulation reveals relatively ineffective sural nerve projections to dorsal horn neurons in the cat

Electrical stimulation of the sural nerve (SN) revealed input from sural nerve afferents to L6 and L7 dorsal horn neurons that were not apparent using natural mechanical stimuli, especially in cells with variable latency responses to SN stimulation. Nearly all (31/32) cells that had reliable, fixed latency responses to SN stimulation also had an excitatory receptive field (RF) in the region of skin innervated by the sural nerve (SN region). About one-third (20/57) of the cells with variable latency responses to SN stimulation, however, had an RF outside the SN region. Most (130/146) cells with no response to SN stimulation had RFs outside the SN region. There were no obvious differences between variable latency cells with RFs in the SN region vs those with RFs outside it in latency of response to SN stimulation, recording depth, RF sizes or modality properties. In a subsample of 31 postsynaptic dorsal column neurons all cells responding to SN stimulation also had an RF in the SN region. Strengthening of relatively ineffective projections from the sural nerve by lesions might be expected to lead to an increase in the proportion of cells responding with impulses to natural stimulation of the skin innervated by the sural nerve, and, hence, to an increase in average RF size.     

The contralateral input to the dorsal horn of the spinal cord in the decerebrate spinal rat

Input from the contralateral limb and tail was examined in the lumbar dorsal horn of decerebrate spinal rats. Fifty-three cells were recorded from laminae 4, 5 and 6 and classified according to their ipsilateral response to natural and electrical stimulation. Twenty-nine (54%) of these cells were found to have inhibitory contralateral fields. This inhibition was evoked by noxious pinching or heating of the skin. In most cases the inhibitory field was a mirror image of the excitatory ipsilateral field although it also often included the tail. Activity evoked by natural and electrical stimulation as well as spontaneous activity was inhibited by contralateral skin stimulation. Noxious specific and wide dynamic range cells displayed these fields but low threshold mechanoreceptive cells did not. Twenty-six cells (49%) received direct short-latency excitatory input from the contralateral sciatic nerve; this correlated well with the presence of contralateral fields. Trains of stimuli applied to the contralateral sciatic nerve at Aδ- and C-fibre strength resulted in inhibition of the cell whereas trains of Aβ strength had no effect. The results demonstrate the existence of segmental contralateral control over dorsal horn cell activity, not involving supraspinal pathways.     

A comparison of axonal numbers in dorsal roots following spinal cord hemisection in neonate and adult rats

This study presentsd mtelinated and unmyelinated axon counts from thoracic dorsal roots of rats whose spinal cords were hemisected at birth or at 1 year of age. Axonal numbers from a root on the unoperated side are compared to numbers from the root of the same segment on the operated side of the animal. Counts were made 3 segments cranially and 3 segments caudally from the hemisection. In animals hemisected at birth and sacrified at 3–8 months, there is a statistically significant increase in unmyelinated axons in roots of the operated as compared to the normal side. We interpret this as sprouting of unmyelinated axons. In animals hemisected at 1 year of age, the statistically significant change was a drop in myelinated axons in roots of the operated side. We interpret this as a loss of myelinated axon cell bodies due to axon section in the dorsal funiculus. Thus axonal sprouting occurs in young rats in our paradigm and a loss of myelinated axons occurs in older animals. We emphasize that different axonal populations respond to hemisection in different ways at different times.     

Dendritic changes in the spinal dorsal horn following transection of a peripheral nerve

Microinjections of different doses of bicuculline methiodide (BM) were performed into the mesencephalic central gray (CG), the medial hypothalamus (MH) and lateral hypothalamus (LH). Flight reactions could be induced by microinjections of BM into either the CG or the MH. However, the type of flight behavior was different whether the injection was made in the CG or the MH. Furthermore, microinjections of 35 ng of BM in either structure produced an increase in locomotor activity whose time course differed according to the injected structure, and an increase in rearings was induced at MH but not at CG sites. At lateral hypothalamic sites, BM produced an increase in locomotor activity and rearings but no jump. These effects were antagonized in a dose-dependent manner by a local pretreatment with 4,5,6,7-tetrahydroisoxazolo(5,4-c)pyridin-3-ol (THIP), a GABA agonist. These results suggest that (1) at the level of both the MH and the CG, a GABAergic link is involved in the inhibition of a substrate whose activation produces aversive effects, and (2) the aversive effect induced by CG BM microinjection seems to be different from that induced by MH BM microinjection.     

Synaptic and non-synaptic components of the dorsal horn potential in isolated hamster spinal cord

Slow negative potentials, evoked by stimulation of the lumbar dorsal roots, have been demonstrated in the dorsal horn of an isolated, hemisected spinal cord preparation from golden hamsters. Paired stimuli revealed a period of partial suppression of this slow potential persisting for up to 2 s following the conditioning stimulus, but with high stimulation frequencies this effect was masked and above 20 Hz a tetanic train of stimuli produced a smoothly rising potential. The response evoked by tetanic stimulation was shown to consist of two components, a manganese-sensitive, synaptically generated component, and a manganese-resistant, frequency-dependent element. Treatment with 10⁻⁴ M 4-aminopyridine blocked the manganese-resistant tetanic response but did not reduce the manganese-sensitive component. Bicuculline, picrotoxin and tubocurare had little effect upon the tetanic response, but 10⁻³ M procaine blocked it completely. The possibility that the manganese-resistant response was due to the release of potassium ions is considered.     

Substance pin spinal cord dorsal horn decreases following peripheral nerve injury

Substance P was located in the spinal cord of rats by immunocytochemistry.Section and ligation of the sciatic nerve produced a depleted area low in substance P in the medial two-thirds of laminae 1 and 2 of segments L4 and 5.The time of depletion began about 5 days after the nerve had been cut and substance P reached a steady minimum by about 9 days and remained depleted for the entire period examined, 31 days.Crush lesions of the sciatic nerve failed to produce the marked and rapid changes of spinal cord substance P observed after section and ligation.     

Changes in synaptic populations in the spinal dorsal horn following a dorsal rhizotomy in the monkey

Studies in monkeys have shown substantial neuronal reorganization and behavioral recovery during the months following a cervical dorsal root lesion (DRL; Darian‐Smith [2004] J. Comp. Neurol. 470:134–150; Darian‐Smith and Ciferri [2005] J. Comp. Neurol. 491:27–45, [2006] J. Comp. Neurol. 498:552–565). The goal of the present study was to identify ultrastructural synaptic changes post‐DRL within the dorsal horn (DH). Two monkeys received a unilateral DRL, as described previously (Darian‐Smith and Brown [2000] Nat. Neurosci. 3:476–481), which removed cutaneous and proprioceptive input from the thumb, index finger, and middle finger. Six weeks before terminating the experiment at 4 post‐DRL months, hand representation was mapped electrophysiologically within the somatosensory cortex, and anterograde tracers were injected into reactivated cortex to label corticospinal terminals. Sections were collected through the spinal lesion zone. Corticospinal terminals and inhibitory profiles were visualized by using preembedding immunohistochemistry and postembedding γ‐aminobutyric acid (GABA) immunostaining, respectively. Synaptic elements were systematically counted through the superficial DH and included synaptic profiles with round vesicles (R), pleomorphic flattened vesicles (F; presumed inhibitory synapses), similar synapses immunolabeled for GABA (F‐GABA), primary afferent synapses (C‐type), synapses with dense‐cored vesicles (D, mostly primary afferents), and presynaptic dendrites of interneurons (PSD). Synapse types were compared bilaterally via ANOVAs. As expected, we found a significant drop in C‐type profiles on the lesioned side (∼16% of contralateral), and R profiles did not differ bilaterally. More surprising was a significant increase in the number of F profiles (∼170% of contralateral) and F‐GABA profiles (∼315% of contralateral) on the side of the lesion. Our results demonstrate a striking increase in the inhibitory circuitry within the deafferented DH. J. Comp. Neurol. 518:103–117, 2010. © 2009 Wiley‐Liss, Inc.     

Clinical utility of dorsal sural nerve conduction studies

A technique of testing sensory nerve conduction of the dorsal sural nerve in the foot was used in 38 normal subjects and 70 patients with peripheral neuropathies. The normal dorsal sural sensory nerve action potential (SNAP) had a mean amplitude of 8.9 microV (range 5-15 microV), mean latency to negative peak of 4.0 ms (range 3.2-4.7 ms), and mean conduction velocity of 34.8 m/s (range 30-44 m/s). Optimal placement of the recording electrodes to obtain a maximal nerve action potential was proximal to digits 4 and 5. Cooling to below 25 degrees C prolonged the latency but did not decrease the SNAP amplitude. Among the patients with peripheral neuropathy, dorsal sural SNAP was absent in 68 (97%), whereas only 54 (77%) showed abnormalities of sural sensory conduction. The diagnostic sensitivity of sensory nerve conduction studies in peripheral neuropathies may be significantly improved by the use of this technique for evaluating the action potential of the dorsal sural nerve.     

Changes in the somatotopic organization of the cat lumbar spinal cord following peripheral nerve transection and regeneration

Glass microelectrodes were used to record the activity of neurones in the left dorsal horn of the L6 segment of the spinal cord of normal cats and cats in which the left sciatic and saphenous nerves had been cut 1 or 9 months previously. In the normal animals the receptive fields of L6 dorsal horn neurones excited by tactile stimulation of the leg were somatotopically organized, with neurones in the medial and central dorsal horn having receptive fields on the distal parts of the leg, particularly the toes, and neurones in the lateral dorsal horn having receptive fields on the proximal parts of the leg, buttock and lower back. This somatotopy has been shown before. One month after nerve section no cells responded to tactile stimulation of the distal leg and cells in the medial and central parts of the dorsal horn now had receptive fields on the proximal leg, buttock and back. There did not appear to be any somatotopic organization of these new receptive fields. Lateral dorsal horn neurones had normal receptive fields. Nine months after nerve section neurones in the medial and central parts of the lumbar dorsal horn had receptive fields on the distal leg but they showed several abnormal features and there was no evidence of a return of the somatotopic organization seen in normal animals. Lateral dorsal horn cells still had normal receptive fields.     

Altered transcription of glutamatergic and glycinergic receptors in spinal cord dorsal horn following spinal cord transection is minimally affected by passive exercise of the hindlimbs

Gene expression is altered following a spinal transection (STx) in both motor and sensory systems. Exercise has been shown to influence gene expression in both systems post‐STx. Gene expression alterations have also been shown in the dorsal root ganglia and nociceptive laminae of the spinal cord following either an incomplete spinal cord injury (SCI) or a contusive SCI. However, the effect of STx and exercise on gene expression in spinal cord laminae I‐III has not fully been examined. Therefore, the purpose of this study was to determine whether gene expression in laminae I‐III is altered following STx and determine whether superimposed passive exercise of the hindlimbs would influence gene expression post‐STx in laminae I‐III. Laser capture microdissection was used to selectively harvest laminae I‐III of lumbar spinal cord sections, and quantitative RT‐PCR was used to examine relative expression of 23 selected genes in samples collected from control, STx and STx plus exercise rats. We demonstrate that post‐STx, gene expression for metabotropic glutamate receptors 1, 5 and 8 were up‐regulated, whereas ionotropic glutamatergic receptor (Glur2) and glycinergic subunit GLRA1 expression was down‐regulated. Daily exercise attenuated the down‐regulation of Glur2 gene expression in laminae I‐III. Our results demonstrate that in a STx model, gene expression is altered in laminae I‐III and that although passive exercise influences gene expression in both the motor and sensory systems, it had a minimal effect on gene expression in laminae I‐III post‐STx.     

The properties of neurones recorded in the superficial dorsal horn of the rat spinal cord

The physiological properties of neurones in the superficial laminae of the dorsal horn of the fourth and fifth lumbar segments of the rat spinal cord have been investigated in decerebrate spinal animals. Both extracellular recordings with platinum-plated tungsten microelectrodes (n = 72) and intracellular recordings with glass microelectrodes (N = 79) were made. Attempts were made to fill cells intracellularly with horseradish peroxidase or Lucifer Yellow. Thirty-seven percent of the intracellularly injected neurones were recovered after histological processing and their cell bodies found to be in lamina 1 or 2 and in the dorsal white matter overlying lamina 1. The dendritic spread of the stained neurones was maximal in the rostrocaudal plane with a restricted mediolateral spread. The physiological properties of the extracellularly recorded units, the intracellularly unidentified units, and the intracellularly stained units were the same. The neurones were characterized by low background activity and all had excitatory receptive fields on the lower limb. Some neurones responded only to low-threshold mechanical stimulation of the skin or only to noxious skin stimulation but the majority of units (58%) were wide-dynamic-range cells responding to both types of stimuli. Receptive field classification was made questionable, however, by the existence of cells (9%) that exhibited a spontaneous shift in the size of their receptive fields and in the type of stimulus that elicited a response. The neurones in the superficial dorsal horn commonly showed a marked inhibition to repeated cutaneous stimuli (27%) or a prolonged afterdischarge followed a single stimulus (20%). Afferent input from the sural nerve was found to be from A and C fibres in both extra- and intracellular recordings. Aδ- and C-mediated excitations were most common although convergent inputs from Ab?-fibres occurred in 40% of units. No correlation was found between cell structure or distribution of dendritic fields and physiological properties in our small sample of intracellularly stained cells. The morphology of the cells was highly diverse, as were the different receptive fields. There was, however, some correlation between the location of cell bodies and their responses. Neurones responding only to low-threshold stimuli were distributed either in the dorsal white matter or in inner lamina 2. Wide-dynamic-range cells were distributed throughout the superficial dorsal horn. These results suggest that neurones of different shapes and positions may subserve the same function and, conversely, that neurones of the same shape and position may subserve different functions.     

Interfacing peripheral nerve with macro-sieve electrodes following spinal cord injury

Macro-sieve electrodes were implanted in the sciatic nerve of five adult male Lewis rats following spinal cord injury to assess the ability of the macro-sieve electrode to interface regenerated peripheral nerve fibers post-spinal cord injury. Each spinal cord injury was performed via right lateral hemisection of the cord at the T_(9–10) site. Five months post-implantation, the ability of the macro-sieve electrode to interface the regenerated nerve was assessed by stimulating through the macro-sieve electrode and recording both electromyography signals and evoked muscle force from distal musculature. Electromyography measurements were recorded from the tibialis anterior and gastrocnemius muscles, while evoked muscle force measurements were recorded from the tibialis anterior, extensor digitorum longus, and gastrocnemius muscles. The macro-sieve electrode and regenerated sciatic nerve were then explanted for histological evaluation. Successful sciatic nerve regeneration across the macro-sieve electrode interface following spinal cord injury was seen in all five animals. Recorded electromyography signals and muscle force recordings obtained through macro-sieve electrode stimulation confirm the ability of the macro-sieve electrode to successfully recruit distal musculature in this injury model. Taken together, these results demonstrate the macro-sieve electrode as a viable interface for peripheral nerve stimulation in the context of spinal cord injury.     

Peripheral noxious stimulation induces phosphorylation of the NMDA receptor NR1 subunit at the PKC-dependent site, serine-896, in spinal cord dorsal horn neurons

The N‐methyl‐D ‐aspartate receptor (NMDAR) contributes to central sensitization in the spinal cord and the generation of pain hypersensitivity. NMDAR function is modulated by post‐translational modifications including phosphorylation, and this is proposed to underlie its involvement in the production of pain hypersensitivity in the spinal cord. We now show that a noxious heat stimulus applied to the rat hindpaw induces phosphorylation of the NMDAR NR1 subunit at a protein kinase C (PKC)‐dependent site, serine‐896, in superficial dorsal horn neurons. Phosphorylation of NR1 serine‐896 is essentially absent in the superficial dorsal horn laminae of naïve rats, but there is rapid (< 2 min) induction following a noxious but not innocuous heat stimulus. The number of pNR1‐immunoreactive neuronal profiles in the superficial dorsal horn peaks 30 min after noxious heat stimulation and persists for up to 1 h. pNR1serine896 induction occurs in the endoplasmic reticulum, suggesting that it contributes to trafficking of the receptor from intracellular stores to the membrane. The phosphorylation of the subunit is attenuated by intrathecal injection of the NMDAR antagonist, MK801, suggesting that the NMDAR is involved via a feed‐forward mechanism in its own phosphorylation. The pNR1serine896‐positive neurons are highly co‐localized with PKCdelta and only rarely with PKCgamma. These data provide evidence for an activity‐dependent NMDAR phosphorylation at the PKC‐dependent site, serine‐896, in spinal cord dorsal horn neurons initiated by peripheral noxious stimuli.     

Neurotensin inhibits background K+ channels and facilitates glutamatergic transmission in rat spinal cord dorsal horn

Neurotensin (NT) is a neuropeptide involved in the modulation of nociception. We have investigated the actions of NT on cultured postnatal rat spinal cord dorsal horn (DH) neurons. NT induced an inward current associated with a decrease in membrane conductance in 46% of the neurons and increased the frequency of glutamatergic miniature excitatory synaptic currents in 37% of the neurons. Similar effects were observed in acute slices. Both effects of NT were reproduced by the selective NTS1 agonist JMV449 and blocked by the NTS1 antagonist SR48692 and the NTS1/NTS2 antagonist SR142948A. The NTS2 agonist levocabastine had no effect. The actions of NT persisted after inactivation of G(i/o) proteins by pertussis toxin but were absent after inactivation of protein kinase C (PKC) by chelerythrine or inhibition of the MAPK (ERK1/2) pathway by PD98059. Pre- and postsynaptic effects of NT were insensitive to classical voltage- and Ca(2+) -dependent K(+) channel blockers. The K(+) conductance inhibited by NT was blocked by Ba(2+) and displayed no or little inward rectification, despite the presence of strongly rectifying Ba(2+) -sensitive K(+) conductance in these neurons. This suggested that NT blocked two-pore domain (K2P) background K(+) -channels rather than inwardly rectifying K(+) channels. Zn(2+) ions, which inhibit TRESK and TASK-3 K2P channels, decreased NT-induced current. Our results indicate that in DH neurons NT activates NTS1 receptors which, via the PKC-dependent activation of the MAPK (ERK1/2) pathway, depolarize the postsynaptic neuron and increase the synaptic release of glutamate. These actions of NT might modulate the transfer and the integration of somatosensory information in the DH.     

Effect of propofol on glutamate-induced activation and related inflammatory cytokines of astrocytes from spinal cord dorsal horn★

BACKGROUND： Astrocytes participate in central nervous system-mediated physiological or pathological processes, such as pain. Activated dorsal horn astrocytes from the spinal cord produce nerve active substances and proinflammatory cytokines, such as interleukin-lbeta （IL-1 β ）, IL-6, and tumor necrosis factor- α （TNF-α ）, which play important roles in pain transduction and regulation. OBJECTIVE： To investigate the effects of different doses of propofol on activation of cultured spinal cord dorsal horn astrocytes induced by glutamate, as well as changes in IL-1β, IL-6, and TNF- α, and 1L-10 （anti-inflammatory cytokine） expression in rats, and to explore the dose relationship of propofol. DESIGN, TIME AND SETTING： The cellular and molecular biology experiment was performed at the Central Laboratory of Yunyang Medical College between March 2006 and December 2007. MATERIALS： Forty healthy, Wistar rats, aged 2-3 days, were selected. Propofol was provided by Zeneca, UK; glutamate by Sigma, USA; EPICS XL flow cytometry by Beckman culture, USA; rabbit-anti-mouse glial fibrillary acidic protein （GFAP） antibody kit and inflammatory cytokine detection kit were provided by Zhongshan Biotechnology Company Ltd., Beijing; multimedia color pathologic image analysis system was a product of Nikon, Japan. METHODS： Astrocytes were harvested from T11- L6 spinal cord dorsal horn of Wistar rats and incubated for 3 weeks. The cells were divided into seven groups, according to various treatment conditions： control group was cells cultured in Hank＇s buffered saline solution; intralipid group was cells cultured in intralipid （0.2 mL/L）; glutamate group was cells cultured with 100 u mol/L glutamate; propofol group was cells cultured with 250 u mol/L propofol; three glutamate plus propofol groups were cultured in 100 11 mol/L of glutamate, followed by 5, 25, and 250 u mol/L of propofol 10 minutes later. MAIN OUTCOME MEASURES： GFAP-labeled astrocytes were analyzed using a multimedia pathology imaging a     

The actions of neuropeptides on dorsal horn neurons in the rat spinal cord slice preparation: an intracellular study

Responses of dorsal horn neurons to bath application of substance P, somatostatin and enkephalin were studied by intracellular recording in the neonatal spinal cord slice preparation. Substance P depolarized dorsal horn neurons and increased their excitability. The depolarization was most commonly associated with an increase in neuronal input resistance. Somatostatin and enkephalin hyperpolarized dorsal horn neurons and caused reduction or abolition of spontaneous firing. While the hyperpolarization produced by enkephalin was always associated with a fall in neuronal input resistance, in the case of somatostatin the similar effect was less consistently observed.     

Primary neurons maintain their central axonal arbors in the spinal dorsal horn following peripheral nerve injury: an anatomical analysis using transganglionic transport of horseradish peroxidase

This study in adult cats demonstrates that primary neurons of all sizes survive following the transection and capping with a polyethylene tube of their peripheral processes in the superficial radial nerve. The central axonal arbors of these injured primary neurons remain intact and maintain their normal topographic position across laminae I–VI of the cervical (C6–C8) dorsal horn. In addition, they maintain their synaptic vesicles, some of their synaptic connections and their ability to transport horseradish peroxidase transganglionically.     

Selective excitation of neurons in the mammalian spinal dorsal horn by aspartate and glutamate in vitro: correlation with location and excitatory input

The electrical activity of mammalian dorsal horn neurons was recorded with pipette microelectrodes in an in vitro spinal cord slice preparation with dorsal roots intact. Addition of relatively low concentrations of aspartate or glutamate to the superfusion solution or through the recording pipette with small iontophoretic currents excited only a subset of neurons. The majority of these excited neurons were located in the superficial dorsal horn (Rexed's laminae I and II) and a preponderance were excited by the C-fiber components of dorsal root volleys. These findings are consistent with the idea that aspartate or glutamate may function as a synaptic mediator for some neurons terminating in the superficial dorsal horn.     

脊髓半切后损伤区周围ERK1／2活性的改变

目的 观察大鼠脊髓半切后ERK1/2活性的变化及发生变化的细胞类型。方法 大鼠行脊髓半横断术后3d，用免疫组织化学法和免疫荧光双标记法观察磷酸化ERK1/2的变化及其与各种神经细胞标记物的共存状况。结果 观察到脊髓半切3d大鼠的ERK1/2磷酸化程度明显升高。阳性细胞为分布于邻近损伤区周围的具有短突起的小胞体细胞。双标记表明其中的大部分阳性细胞为小胶质细胞和寡突胶质细胞。结论 本研究提示脊髓半横断3d，ERKl/2参与了小胶质细胞和寡突胶质细胞的活化，有可能在脊髓损伤的/继发性过程中具有重要作用。