Differential effects of lithium on agonist-stimulated inositol polyphosphate formation in rat cerebral cortex slices: Selective actions on muscarinic cholinergic responses

Recent data indicate that BMY 7378 demonstrates high affinity, selectivity and low intrinsic activity at hippocampal 5-HT_1A receptors, suggesting that BMY 7378 may represent the first selective 5-HT_1A functional antagonist. The present study examined the agonist and antagonist properties of BMY 7378 at spinal cord 5-HT_1A receptors. In electrophysiological studies, iontophoretic administration of either the 5-HT_1A agonist 8-OH-DPAT (43.8 ± 5.4 nA) or BMY 7378 (46.3 ± 5.2 nA) significantly inhibited the firing rate of wide-dynamic-range dorsal horn units indicating that BMY 7378 demonstrates significant intrinsic activity at spinal cord 5-HT_1A receptors. Concomitant BMY 7378 and 8-OH-DPAT administration identified no BMY 7378 ejection current (20–100 nA) which antagonized the 8-OH-DPAT induced inhibition of dorsal horn unit activity. In behavioral studies in the spinal rat, 8-OH-DPAT increased the animals' sensitivity to noxious levels of mechanical stimulation (ED₅₀ = 269 ± 24 nmol/kg) as did BMY 7378 (ED₅₀ = 295 ± 70 nmol/kg) with no statistically significant difference in the maximal response (Y_max) observed. Concomitant BMY 7378 and 8-OH-DPAT administration identified no BMY 7378 dose (10–1100 nmol/kg) which blocked the hyperalgesic effect of 8-OH-DPAT, rather, each drug produced similar effects which were additive. Further, the 5-HT_1A agonist effects of BMY 7378 were blocked by the 5-HT_1A antagonist, spiperone. Therefore, both the electrophysiologic and reflex data indicate that BMY 7378 possesses significant intrinsic activity at spinal cord 5-HT_1A receptors, and like 8-OH-DPAT is a partial agonist at these receptors. Differences in BMY 7378 intrinsic activity at spinal cord as opposed to hippocampal 5-HT_1A receptors are discussed in terms of regional differences in G-proteins coupled to 5-HT_1A receptors in these two CNS regions.     

Some problems of projections and actions of cortico- and rubro-spinal fibres.

A review of a number of known, partly known and to be established properties of the cortico- and rubro-spinal tract systems in relation to: (1) multiple projections of individual neurones, or functional subgroups of neurones in the motor cortex and in the red nucleus, (2) identification of spinal target cells of these neurones, and (3) the mechanisms of interactions between the two systems.     

Constitutive expression of CCR2 chemokine receptor and inhibition by MCP-1/CCL2 of GABA-induced currents in spinal cord neurones

In the CNS, immune-like competent cells (microglia and astrocytes) were first described as potential sites of chemokine synthesis, but more recent evidence has indicated that neurones might also express chemokines and their receptors. The aim of the present work was to investigate further, both in vivo and in vitro, CC Chemokine Family Receptor 2 (CCR2) expression and functionality in rat spinal cord neurones. First, we demonstrated by RT-PCR and western blot analysis that CCR2 mRNA and protein were present in spinal extracts. Furthermore, we showed by immunolabelling that CCR2 was exclusively expressed by neurones in spinal sections of healthy rat. Finally, to test the functionality of CCR2, we used primary cultures of rat spinal neurones. In this model, similar to what was observed in vivo, CCR2 mRNA and protein were expressed by neurones. Cultured neurones stimulated with Monocyte Chemoattractant Protein-1 (MCP-1)/CCL2, the best characterized CCR2 agonist, showed activation of the Akt pathway. Finally, patch-clamp recording of cultured spinal neurones was used to investigate whether MCP-1/CCL2 could modulate their electrophysiological properties. MCP-1 alone did not affect the electrical properties of spinal neurones, but potently and efficiently inhibited GABA(A)-mediated GABAergic responses in these neurones. These data constitute the first demonstration of a modulatory role of MCP-1 on GABAergic neurotransmission and contribute to our understanding of the roles of CCR2 and MCP-1/CCL2 in spinal cord physiology, in particular with respect to nociceptive transmission, as well as the implication of this chemokine in neuronal adaptation or dysfunction during neuropathy.     

Prolonged primary afferent induced alterations in dorsal horn neurones, an intracellular analysis in vivo and in vitro

1.) Peripheral tissues injury produces long lasting sensory and motor disturbances in man that present as the post-injury hypersensitivity syndrome with a reduction in the threshold required to elicit either pain or the flexion withdrawal reflex and an exaggeration of the normal response to suprathreshold stimuli. 2.) Two mechanisms contribute to these changes; sensitization of the peripheral terminals of high threshold primary afferents and an increase in the excitability of the spinal cord; a phenomenon known as central sensitization. 3.) Central sensitization has previously been shown by our laboratory to be the consequence of activity in unmyelinated primary afferents. Brief (20 s) C-fibre strength conditioning stimuli have the capacity to produce both a prolonged heterosynaptic facilitation of the flexion reflex and an alteration in the response properties of dorsal horn neurones, that long outlast the conditioning stimulus. 4.) In the adult decerebrate-spinal rat preparation we have, using intracellular recordings of dorsal horn neurones, examined the time course of the central effects of different types of orthodromic inputs. The hemisected spinal cord preparation isolated from 12-14 day rat pups has been used to see whether prolonged alterations in dorsal horn properties induced by orthodromic inputs can be studied in vitro. 5.) Single stimuli applied to a cutaneous nerve at graded strengths to successively recruit A beta, A delta and C-afferents produce, in the majority of neurones recorded in the deep dorsal horn in vivo, a series of post synaptic potentials that last from between ten and several hundred milliseconds. 6.) Repeated low frequency stimulation of C but not A-afferent fibres results in a pattern of progressive response increment or windup in a proportion of dorsal horn neurones. In some of the neurones the windup is associated with a depolarization that outlasts the stimulus period for tens of seconds. 7.) Application of the chemical irritant mustard oil to the skin activates chemosensitive C-afferent fibres for 1-3 minutes. Such a conditioning stimulus results however in an expansion in the size and an alteration in the response properties of the receptive fields of dorsal horn neurones that lasts for tens of minutes. 8.) In dorsal horn neurones recorded intracellularly in the isolated hemisected spinal cord, both intrinsic membrane properties and the orthodromic responses to primary afferent input can be studied. Repeated stimulation of a dorsal root produces in some neurones a prolonged heterosynaptic facilitation with both an augmentation of the response to the conditioning root (homosynaptic potentiation) and to adjacent test roots (heterosynaptic potentiation).(ABSTRACT TRUNCATED AT 400 WORDS)     

Functional corticotropin-releasing factor receptors in neonatal rat spinal cord

The present study localized corticotropin-releasing factor (CRF) receptors and studied the actions of CRF in the neonatal rat spinal cord preparation. Lumbar CRF receptors were present in highest concentrations in laminae I and II with progressively lower concentrations in lamina IX and intermediate and central zones respectively. CRF directly and indirectly depolarized lumbar motoneurons in a concentration-related manner and the putative receptor antagonist, alpha helical oCRF(9–41), partially blocked the depolarizing response to CRF. The electrophysiological responses to CRF and the distribution of receptors within the spinal cord suggest that CRF may play a physiological role in regulating spinal cord reflex function.     

Developmental biomechanics of the cervical spine: Tension and compression

Epidemiological data and clinical indicia reveal devastating consequences associated with pediatric neck injuries. Unfortunately, neither injury prevention nor clinical management strategies will be able to effectively reduce these injuries or their effects on children, without an understanding of the cervical spine developmental biomechanics. Thus, we investigated the relationship between spinal development and the functional (stiffness) and failure biomechanical characteristics of the cervical spine in a baboon model. A correlation study design was used to define the relationships between spinal tissue maturation and spinal biomechanics in both tension and compression. Eighteen baboon cervical spine specimens distributed across the developmental spectrum (1–26 human equivalent years) were dissected into osteoligamentous functional spinal units. Using a servo-hydraulic MTS, these specimens (Oc–C2, C3–C4, C5–C6, C7–T1) were non-destructively tested in tension and compression and then displaced to failure in tension while measuring the six-axes of loads and displacements. The functions describing the developmental biomechanical response of the cervical spine for stiffness and normalized stiffness exhibited a significant direct relationship in both tension and compression loading. Similarly, the tensile failure load and normalized failure load demonstrated significant maturational increases. Further, differences in biomechanical response were observed between the spinal levels examined and all levels exhibited clinically relevant failure patterns. These data support our understanding of the child cervical spine from a developmental biomechanics perspective and facilitate the development of injury prevention or management schema for the mitigation of child spine injuries and their deleterious effects.     

Amphibian sympathetic ganglia as a model system for investigating regeneration in the vertebrate peripheral nervous system

1. The paravertebral sympathetic ganglion of the bullfrog serves as an excellent experimental system in which to study the response of vertebrate neurones to axotomy and the mechanisms associated with regeneration. 2. Various types of lesions to the axons (axotomy) of these neurones promote distinct and reproducible changes in the electrophysiological properties of the cell bodies which are not a consequence of changes in cell body morphology. 3. The axotomy-induced increase in spike width and decrease in the amplitude of the action potential after-hyperpolarization may allow an increase in Ca2+ influx and thereby promote regrowth. 4. The axotomy-induced decrease in after-hyperpolarization duration may reflect the disconnection of the neurone with its target and the loss of available nerve growth factor (NGF) from the target. 5. Experiments with NGF antibodies provide evidence that an NGF-like substances serves to maintain the normal electrophysiological characteristics of amphibian sympathetic neurones.     

BMY 7378: Partial agonist at spinal cord 5-HT1A receptors

Recent data indicate that BMY 7378 demonstrates high affinity, selectivity and low intrinsic activity at hippocampal 5-HT_1A receptors, suggesting that BMY 7378 may represent the first selective 5-HT_1A functional antagonist. The present study examined the agonist and antagonist properties of BMY 7378 at spinal cord 5-HT_1A receptors. In electrophysiological studies, iontophoretic administration of either the 5-HT_1A agonist 8-OH-DPAT (43.8 ± 5.4 nA) or BMY 7378 (46.3 ± 5.2 nA) significantly inhibited the firing rate of wide-dynamic-range dorsal horn units indicating that BMY 7378 demonstrates significant intrinsic activity at spinal cord 5-HT_1A receptors. Concomitant BMY 7378 and 8-OH-DPAT administration identified no BMY 7378 ejection current (20–100 nA) which antagonized the 8-OH-DPAT induced inhibition of dorsal horn unit activity. In behavioral studies in the spinal rat, 8-OH-DPAT increased the animals' sensitivity to noxious levels of mechanical stimulation (ED₅₀ = 269 ± 24 nmol/kg) as did BMY 7378 (ED₅₀ = 295 ± 70 nmol/kg) with no statistically significant difference in the maximal response (Y_max) observed. Concomitant BMY 7378 and 8-OH-DPAT administration identified no BMY 7378 dose (10–1100 nmol/kg) which blocked the hyperalgesic effect of 8-OH-DPAT, rather, each drug produced similar effects which were additive. Further, the 5-HT_1A agonist effects of BMY 7378 were blocked by the 5-HT_1A antagonist, spiperone. Therefore, both the electrophysiologic and reflex data indicate that BMY 7378 possesses significant intrinsic activity at spinal cord 5-HT_1A receptors, and like 8-OH-DPAT is a partial agonist at these receptors. Differences in BMY 7378 intrinsic activity at spinal cord as opposed to hippocampal 5-HT_1A receptors are discussed in terms of regional differences in G-proteins coupled to 5-HT_1A receptors in these two CNS regions.     

Conductance states activated by glycine and GABA in rat cultured spinal neurones

Summary The conductance properties of single Cl^– channels activated by glycine and gamma-aminobutyric acid (GABA) were examined in rat spinal cord neurones grown in cell culture. The majority (85%) of spinal neurones were sensitive to both glycine and GABA as were most (83%) outside-out patches tested. Glycine and GABA activated multiple conductance state Cl^– channels with linear current-voltage properties when the chloride activities of the solutions bathing both sides of the membrane were similar. Glycine activated six distinct conductance states with conductances of 14, 20, 30, 43, 64 and 93 pS, whereas GABA activated five states with conductances of 13, 20, 29, 39 and 71 pS. The 30 and 43 pS states and the 20 and 29 pS states were observed most frequently with glycine and GABA, respectively. As the values of the glycine- and GABA-activated conductance states form a geometric progression when arranged in ascending order, we concluded that the channels do not consist of a cluster of identical pores. Additional conductance states (50 and 100 pS) were activated by glycine occasionally. The similarity between the conductances of the states activated by the two transmitters is consistent with the proposal that they both activate the same type of Cl^– channel.     

Time and concentration dependency of the toxicity of excitatory amino acids on cerebral neurones in primary culture

The cytotoxicity of the glutamate receptor agonists, N-methyl- -aspartate (NMDA), kainate (KA) and (RS)--amino-3-hydroxy-5-methyl-isoxazole-4-propionate (AMPA) on cultured cerebral cortex neurones was monitored as a function of exposure time and concentration by following the release into the culture medium of the cytoplasmic enzyme lactate dehydrogenase from the neurones. Chronic exposure of the cells to different concentrations of the agonists showed that AMPA was the most potent excitotoxin (ED₅₀ 10 μM) followed in potency by NMDA (ED₅₀ 65 μM) and KA (ED₅₀ 100 μM). Experiments in which the neurones were exposed for different periods of time to fixed concentrations of the agonists showed that after short exposure times (1–3 min) cells survived for more than 24 h after removal of the agonists but after longer exposure times (5–10 min) cells survived for time periods ranging from 25 min to 6 h depending upon the exposure time and the nature of the agonist. The results of the latter experiments indicate that even short exposure times trigger processes in the cell membranes which even after removal of the excitotoxin will lead to neuronal death.     

Multiple embryonic benzodiazepine binding sites: Evidence for functionality

We have found high-affinity binding (site-A) and low-affinity binding (site-B) of benzodiazepines to membrane homogenates of embryonic chick brain and spinal cord. A new technique was developed to permit the determination of complete electrophysiological dose-response curves on single neurons in cell culture, eliminating cell-to-cell variability as a problem that complicates the interpretation of pooled data. The electrophysiological potencies and binding affinities of a series of benzodiazepines correlate well for site-A but not for site-B or the micromolar site reported in adult rat brain. Site-A and the electrophysiological response are sensitive to photoaffinity blockade with flunitrazepam (FNZM) by about 75% while site-B is resistant to blockade. The FNZM-photolinked benzodiazepine receptor/GABA receptor complex is not chronically potentiated and thus exists in an ‘unpotentiated’ state. These experiments suggest that site-A in embryonic CNS membranes corresponds to a functional benzodiazepine receptor/GABA receptor complex in spinal cord cell cultures.     

Age-related changes in the gastrointestinal tract: a functional and immunohistochemical study in guinea-pig ileum

It is known that there is an age-related increase in gastrointestinal diseases. However, there is a lack of studies dealing with the correlation between age-related changes in function and intrinsic innervation in the gastrointestinal tract. The purpose of this work was to study this subject in the guinea pig ileum, whose functional and structural features are well known in the young age. Ileal longitudinal muscle — myenteric plexus (LMMP) preparations were obtained from 3-to 24-month-old guinea pigs. Both functional and immunohistochemical techniques were applied. The force of the contraction elicited by excitatory stimuli (electrical stimulation, acetylcholine, substance P, and opioid withdrawal) increased in parallel with an age-dependent reduction in the density of excitatory motor neurones to the longitudinal muscle, whereas other subpopulations of neurones, including inhibitory motor neurones, decreased much more slowly. Although the increase in responsiveness could be related to the age/weight-related increment in muscle bulk, some compensatory modifications to the lowered density of excitatory neurones could also be involved. On the other hand, the acute inhibitory response to morphine remained unaltered in old animals, whilst in vitro tolerance was lower. These results suggest that although age-dependent neuronal loss does not cause dramatic changes in intestinal motility, it is a factor that could contribute to disturbing normal responsiveness and, perhaps, underlie the higher frequency of gastrointestinal diseases encountered in the elderly.     

Distribution of binding sites for the plant lectin Ulex europaeus agglutinin I on primary sensory neurones in seven different mammalian species

There is an increasing body of evidence to suggest that different functional classes of neurones express characteristic cell-surface carbohydrates. Previous studies have shown that the plant lectin Ulex europaeus agglutinin-I (UEA) binds to a population of small to medium diameter primary sensory neurones in rabbits and humans. This suggests that a fucose-containing glycoconjugate may be expressed by nociceptive primary sensory neurones. In order to determine the extent to which this glycoconjugate is expressed by other species, in the current study, we have examined the distribution of UEA-binding sites on primary sensory neurones in seven different mammals. Binding sites for UEA were associated with the plasma membrane and cytoplasmic granules of small to medium dorsal root ganglion cells and their axon terminals in laminae I–III of the grey matter of the spinal cord, in the rabbit, cat and marmoset monkey. However, no binding was observed in either the dorsal root ganglia or spinal cord in the mouse, rat, guinea pig or flying fox. These results indicate an inter-species variation in the expression of cell-surface glycoconjugates on mammalian primary sensory neurones.     

Simultaneous Brain–Cervical Cord fMRI Reveals Intrinsic Spinal Cord Plasticity during Motor Sequence Learning

The spinal cord participates in the execution of skilled movements by translating high-level cerebral motor representations into musculotopic commands. Yet, the extent to which motor skill acquisition relies on intrinsic spinal cord processes remains unknown. To date, attempts to address this question were limited by difficulties in separating spinal local effects from supraspinal influences through traditional electrophysiological and neuroimaging methods. Here, for the first time, we provide evidence for local learning-induced plasticity in intact human spinal cord through simultaneous functional magnetic resonance imaging of the brain and spinal cord during motor sequence learning. Specifically, we show learning-related modulation of activity in the C6–C8 spinal region, which is independent from that of related supraspinal sensorimotor structures. Moreover, a brain–spinal cord functional connectivity analysis demonstrates that the initial linear relationship between the spinal cord and sensorimotor cortex gradually fades away over the course of motor sequence learning, while the connectivity between spinal activity and cerebellum gains strength. These data suggest that the spinal cord not only constitutes an active functional component of the human motor learning network but also contributes distinctively from the brain to the learning process. The present findings open new avenues for rehabilitation of patients with spinal cord injuries, as they demonstrate that this part of the central nervous system is much more plastic than assumed before. Yet, the neurophysiological mechanisms underlying this intrinsic functional plasticity in the spinal cord warrant further investigations.     

Physiological properties of sympathetic preganglionic neurones in the thoracic intermediolateral nucleus of the cat

Extracellular spikes were recorded from cell bodies of sympathetic preganglionic neurones in spinal segments T1-T3 of the cat. Each neurone was identified by its antidromic response to electrical stimulation of the sympathetic chain and was found in histological sections to lie within the intermediolateral nucleus. Physiological properties studied in detail included basal activity, spike configuration, and latency of antidromic activation. Also studied, in tests with paired stimuli, were the threshold interstimulus interval evoking two responses, as well as changes in amplitude and latency of the second spike which occurred at intervals near this threshold. Approximately 60% of the units studied were spontaneously active, the rest were silent. Spontaneous activity was characterized by a slow (mean = 3.1 +/- 2.6 (SD) spikes/s), irregular pattern of discharge. With approximately one-third of the cases there was a periodic pattern of discharge in phase with oscillations in blood pressure. This correlation of phasic activity suggests that many of the units studied were involved specifically in cardiovascular function. Silent and spontaneously active units could not be differentiated on the basis of latency of antidromic activation or threshold interstimulus interval; mean latency for the two groups was 7.2 +/- 4.9 ms, mean threshold interval was 6.4 +/- 4.7 ms. Thus, with the exception of basal activity, the physiological properties studied failed to indicate more than a single population of neurones. These results therefore suggest that the sympathetic preganglionic neurones in the intermediolateral nucleus subserving varied autonomic functions share overlapping physiological properties, and that functional differentiation of these neurones may be based on differences in synaptic inputs.     

Functional reinnervation of the neostriatum in the adult rat by use of intraparenchymal grafting of dissociated cell suspensions from the substantia nigra

Summary Dissociated cell suspensions were prepared from the substantia nigra of 15–17 day-old rat embryos and grafted via an intraparenchymal injection into the depth of the neostriatum of adult recipient rats. The survival and fibre outgrowth of the dopamine-containing neurones in the implants were studied by fluorescence histochemistry, and the functional capacity of the grafts was monitored by repeated testing of the amphetamine-induced turning behaviour of the implanted rats.Before transplantation the target neostriatum of the recipient rats was denervated of its normal dopaminergic innervation by an injection of 6-hydroxydopamine into the ipsilateral nigrostriatal dopamine pathway. The completeness of the denervation was ascertained by measurement of the intensity of the amphetamine-induced turning response. After injection of the dissociated cells large numbers of dopamine-containing neurones were found in clusters at the site of injection as well as scattered in the apparently intact neostriatal tissue up to a distance of about 0.5 mm from the site of injection. Extensive dopamine-containing fibre networks had developed around the implant. These newly formed fibres, which were most abundant around the cell clusters at the injection site, extended in a loose network into large areas of the initially denervated caudate-putamen. In all animals with surviving dopamine neurones the amphetamine-induced turning response was reduced, and in the most extensively reinnervated cases even reversed, within 3–5 weeks after transplantation. This strongly suggests that the implanted dopamine neurones are capable of restoring dopaminergic neurotransmission in the denervated neostriatum, probably via reinnervation of the denervated neostriatal tissue.The use of dissociated brain tissue preparations thus permits reliable intraparenchymal grafting of neurones to plausibly any desired site within the central nervous system, and should open entirely new possibilities for investigation of neuronal growth dynamics and functional reconstruction of damaged brain circuits, perhaps even in brains of larger mammals.     

Current source-density analysis in the mushroom bodies of the honeybee (Apis mellifera carnica)

Summary Information processing in the mushroom bodies which are an important part of most invertebrate central nervous systems was analysed by extracellular electrophysiological techniques. The mushroom bodies consist of layers of parallel intrinsic neurons which make synaptic contact with extrinsic input and output neurons. The intrinsic neurons (approximately 170,000/mushroom body) have very small axon diameters (0.1–1 m) which makes it difficult to record their activity intracellularly. In order to analyse the functional properties of this neuropil field potentials were measured extracellularly.Series of averaged evoked potentials (AEPs) were recorded along electrode tracks at consecutive depth intervals in different parts of the mushroom bodies of the bee. These potentials were elicited by olfactory, mechanical and visual stimuli.In order to locate the synaptic areas generating these potentials, current source-densities (CSD) were calculated using the consecutively measured evoked potentials. The conductivities of the extracellular space along the electrode tracks in the pedunculus and calyx and in part of the alpha-lobe of the mushroom bodies were found to be constant.The CSD analysis reveals a complex pattern of source-sink distributions in the mushroom bodies. There is a high degree of correlation between current sinks and sources detected by CSD analysis and the morphological distribution of neurons.The CSD analysis shows that the inputs and outputs of the mushroom bodies involve multimodal synaptic interactions, whereas information processing in the intrinsic Kenyon-cells is limited to sensory inputs from the antenna.Comparison of the electrophysiological with the histological results shows that the intrinsic cells of the mushroom bodies are physiologically not a homogeneous group as is often proposed. Among the intrinsic neurons clearly defined areas of current sources and sinks can be identified and attributed to Kenyon-cells in different layers.Abbreviations AEP averaged evoked potentials - AGT antennoglomerular tract - CSD current source-density - PCT antennoglomerular tract     

Effects of progesterone in the spinal cord of a mouse model of multiple sclerosis

The spinal cord is a target of progesterone (PROG), as demonstrated by the expression of intracellular and membrane PROG receptors and by its myelinating and neuroprotective effects in trauma and neurodegeneration. Here we studied PROG effects in mice with experimental autoimmune encephalomyelitis (EAE), a model of multiple sclerosis characterized by demyelination and immune cell infiltration in the spinal cord. Female C57BL/6 mice were immunized with a myelin oligodendrocyte glycoprotein peptide (MOG_40–54). One week before EAE induction, mice received single pellets of PROG weighing either 20 or 100 mg or remained free of steroid treatment. On average, mice developed clinical signs of EAE 9–10 days following MOG administration. The spinal cord white matter of EAE mice showed inflammatory cell infiltration and circumscribed demyelinating areas, demonstrated by reductions of luxol fast blue (LFB) staining, myelin basic protein (MBP) and proteolipid protein (PLP) immunoreactivity (IR) and PLP mRNA expression. In motoneurons, EAE reduced the expression of the alpha 3 subunit of Na,K-ATPase mRNA. In contrast, EAE mice receiving PROG showed less inflammatory cell infiltration, recovery of myelin proteins and normal grain density of neuronal Na,K-ATPase mRNA. Clinically, PROG produced a moderate delay of disease onset and reduced the clinical scores. Thus, PROG attenuated disease severity, and reduced the inflammatory response and the occurrence of demyelination in the spinal cord during the acute phase of EAE.     

A computational model coupling mechanics and electrophysiology in spinal cord injury

Traumatic brain injury and spinal cord injury have recently been put under the spotlight as major causes of death and disability in the developed world. Despite the important ongoing experimental and modeling campaigns aimed at understanding the mechanics of tissue and cell damage typically observed in such events, the differentiated roles of strain, stress and their corresponding loading rates on the damage level itself remain unclear. More specifically, the direct relations between brain and spinal cord tissue or cell damage, and electrophysiological functions are still to be unraveled. Whereas mechanical modeling efforts are focusing mainly on stress distribution and mechanistic-based damage criteria, simulated function-based damage criteria are still missing. Here, we propose a new multiscale model of myelinated axon associating electrophysiological impairment to structural damage as a function of strain and strain rate. This multiscale approach provides a new framework for damage evaluation directly relating neuron mechanics and electrophysiological properties, thus providing a link between mechanical trauma and subsequent functional deficits.     

Dynorphin-A-(1–13) antagonizes morphine analgesia in the brain and potentiates morphine analgesia in the spinal cord

Intrathecal injection of subanalgesic doses of morphine (7.5 nmol) and dynorphin-A-(1–13) (1.25 nmol) in combination resulted in a marked analgesic effect as assessed by tail flick latency in the rat. The analgesic effect of the composite dynorphin/morphine was dose-dependent in serial dilutions so that a composition of 1/8 of the analgesic dose of dynorphin and 1/3 that of morphine produced an analgesic effect equipotent to full dose of either drug applied separately. The analgesic effect induced by dynorphin/morphine mixture was not accompanied by motor dysfunction and was easily reversed by a small dose (0.5 mg/kg) of naloxone. Contrary to the augmentatory effect of dynorphin on morphine analgesia in the spinal cord, intracerevroventricular (ICV) injection of 20 nmol of dynorphin-A-(1–13) exhibited a marked antagonistic effect on the analgesia produced by morphine (120 nmol, ICV). The theoretical considerations and practical implications of the differential interactions between dynorphin-A-(1–13) and morphine in the brain versus spinal cord are discussed.