Carl Y. Saab

Altered Sodium Channel Expression in Second-Order Spinal Sensory Neurons Contributes to Pain after Peripheral Nerve Injury

Peripheral nerve injury is known to upregulate the rapidly repriming Nav1.3 sodium channel within first-order spinal sensory neurons. In this study, we hypothesized that (1) after peripheral nerve injury, second-order dorsal horn neurons abnormally express Nav1.3, which (2) contributes to the responsiveness of these dorsal horn neurons and to pain-related behaviors. To test these hypotheses, adult rats underwent chronic constriction injury (CCI) of the sciatic nerve. Ten days after CCI, allodynia and hyperalgesia were evident. In situ hybridization, quantitative reverse transcription-PCR, and immunocytochemical analysis revealed upregulation of Nav1.3 in dorsal horn nociceptive neurons but not in astrocytes or microglia, and unit recordings demonstrated hyperresponsiveness of dorsal horn sensory neurons. Intrathecal antisense oligodeoxynucleotides targeting Nav1.3 decreased the expression of Nav1.3 mRNA and protein, reduced the hyperresponsiveness of dorsal horn neurons, and attenuated pain-related behaviors after CCI, all of which returned after cessation of antisense delivery. These results demonstrate for the first time that sodium channel expression is altered within higher-order spinal sensory neurons after peripheral nerve injury and suggest a link between misexpression of the Nav1.3 sodium channel and central mechanisms that contribute to neuropathic pain after peripheral nerve injury.

PREEMPTIVE INTRATHECAL KETAMINE INJECTION PRODUCES A LONG-LASTING DECREASE IN NEUROPATHIC PAIN BEHAVIORS IN A RAT MODEL

BACKGROUND AND OBJECTIVES Ketamine is an N-Methyl-D-Aspartate (NMDA) receptor antagonist, which has been found to effectively treat somatic and neuropathic pain. This study examines the effect (on neuropathic pain) of preemptive ketamine using different routes of administration (intrathecal versus intraperitoneal). METHODS The Institutional Animal Care and Use Committee approved the study. Thirty male Sprague-Dawley rats (250-275 g) were divided into three treatment groups [intrathecal saline/intraperitoneal saline or Control (CTL), intrathecal ketamine/intraperitoneal saline (ITK), and intrathecal saline/intraperitoneal ketamine (IPK)] prior to undergoing surgery to induce neuropathic pain by tight ligation of the left L5 and L6 spinal nerves. All drugs were given 15 minutes before nerve ligation. The ITK group received intrathecal ketamine (0.5% solution, 1 mg/kg), the IPK group received intraperitoneal ketamine (0.5% solution, 1 mg/kg), saline was given in equal volume (approximately 0.05 mL). Mechanical allodynia, cold allodynia, and ongoing pain behaviors indicative of neuropathic pain were assessed on postoperative days 1, 3, 7, and 14 using validated methods. RESULTS Compared with the CTL group, the ITK group showed a state of decreased mechanical allodynia, cold allodynia, and ongoing pain as revealed by the von Frey hair, acetone, and cold plate testing, respectively. Further, this decrease was sustained for at least 2 weeks. The IPK group showed intermediate results between the CTL and ITK. CONCLUSIONS Neuropathic pain behaviors were significantly reduced for at least 2 weeks after intrathecal ketamine was preemptively administered to animals undergoing surgery to induce neuropathic pain. The mechanism of action is thought to be prevention of spinal cord sensitization.

Sodium channel blockade with phenytoin protects spinal cord axons, enhances axonal conduction, and improves functional motor recovery after contusion SCI

Accumulation of intracellular sodium through voltage-gated sodium channels (VGSCs) is an important event in the cascade leading to anatomic degeneration of spinal cord axons and poor functional outcome following traumatic spinal cord injury (SCI). In this study, we hypothesized that phenytoin, a sodium channel blocker, would result in protection of axons with concomitant improvement of functional recovery after SCI. Adult male Sprague-Dawley rats underwent T9 contusion SCI after being fed normal chow or chow containing phenytoin; serum levels of phenytoin were within therapeutic range at the time of injury. At various timepoints after injury, quantitative assessment of lesion volumes, axonal degeneration, axonal conduction, and functional locomotor recovery were performed. When compared to controls, phenytoin-treated animals demonstrated reductions in the degree of destruction of gray and white matter surrounding the lesion epicenter, sparing of axons within the dorsal corticospinal tract (dCST) and dorsal column (DC) system rostral to the lesion site, and within the dorsolateral funiculus (DLF) caudal to the lesion site, and enhanced axonal conduction across the lesion site. Improved performance in measures of skilled locomotor function was observed in phenytoin-treated animals. Based on these results, we conclude that phenytoin provides neuroprotection and improves functional outcome after experimental SCI, and that it merits further examination as a potential treatment strategy in human SCI.

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

Fractalkine (FKN) evokes nociceptive behavior in naïve rats, whereas minocycline attenuates pain acutely after neuronal injury. We show that, in naïve 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 naïve and neuropathic rats acutely, but not chronically, after injury.

Unilateral Focal Burn Injury Is Followed by Long-Lasting Bilateral Allodynia and Neuronal Hyperexcitability in Spinal Cord Dorsal Horn

UNLABELLED Pain after burn injury can be intense and long lasting. Treatment is often ineffective, and there is a need for increased knowledge of the underlying pain mechanisms. In the present study, we established a unilateral partial-thickness burn injury model, which produces ipsilateral mechanical allodynia soon after injury, followed by contralateral allodynia. Chronic bilateral allodynia lasts up to 8 weeks postinjury in this model. In addition to the change in pain behavior, electrophysiological analyses showed that dorsal horn neurons become hyperexcitable and display significantly increased evoked activity with enlarged receptive fields, initially on the side ipsilateral to the injury, and subsequently on both sides of the spinal cord. It is known that, following nerve injury, activation of p38 mitogen-activated protein kinase (MAPK) pathways within spinal microglia contributes to the pathogenesis of pain. In our burn injury model, rapid and prolonged activation of phospho-p38-expressing microglia occurs bilaterally in the spinal cord dorsal horn. Taken together, these data demonstrate that a unilateral peripheral burn injury can produce long-lasting allodynia that can spread to the contralateral limb, together with dorsal horn neuronal hyperexcitability and microglial activation on both ipsilateral and contralateral sides of the spinal cord. Our results suggest that central neuropathic mechanisms can contribute to pain after burn injury. PERSPECTIVE Mechanisms contributing to pain following burn injury are incompletely understood. In a novel animal model of burn injury, we have demonstrated hyperexcitability of second-order sensory neurons, activation of microglia, and chronic bilateral pain following the burn injury. This work identifies potential therapeutic targets to alleviate pain after burn injury.

Neutrophils invade lumbar dorsal root ganglia after chronic constriction injury of the sciatic nerve.

To test whether neutrophils (PMN) target lumbar dorsal root ganglia (DRG) following axonal injury leading to neuropathic pain, we visualized PMN infiltration in DRG tissue sections and estimated PMN count by flow cytometry following sciatic chronic constriction injury (CCI). Seven days after CCI, results show PMN within DRG where their count increased by three fold ipsilateral to injury compared to contralateral or sham, concomitant with peak neuropathic pain behavior. Superoxide burst in PMN isolated from rats d7 after CCI was elevated by 170% +/-18 compared to naïve and MCP-1 mRNA expression in DRG increased by 8.9+/-2.9 fold, but that of MIP-2, CINC-1, and RANTES did not change. We conclude that CCI causes PMN invasion of the DRG whereby the functional implication of their close proximity to neuronal axon and soma remains unknown.

Pain-related changes in the brain: diagnostic and therapeutic potentials

Emerging evidence suggests that chronic pain is a disease that can alter brain function. Imaging studies have demonstrated structural remapping and functional reorganization of brain circuits under various pain conditions. In parallel, preclinical models have demonstrated that chronic pain causes long-term neuroplasticity. For example, thalamo-cortical oscillations are dysregulated and neurons in the sensory thalamus undergo ectopic firing linked to misexpression of membrane ion channels. In theory, physiological changes at the single-unit, multi-unit, and circuitry levels can be used as predictors of pain, and possibly to guide targeted neuromodulation of specific brain regions for therapeutic purposes. Therefore, multidisciplinary research into the mechanisms of pain-related phenomena in the brain may offer insights into novel approaches for the diagnosis, monitoring, and management of persistent pain.

High-frequency stimulation in the ventral posterolateral thalamus reverses electrophysiologic changes and hyperalgesia in a rat model of peripheral neuropathic pain

Summary Rats with peripheral neuropathy manifest a range of abnormal firing patterns of single neurons in the ventral posterolateral thalamus, whereas high‐frequency, but not low‐frequency, microstimulation within the ventral posterolateral thalamus reverses these changes and attenuates hyperalgesia. ABSTRACT Chronic neuropathic pain is associated with long‐term changes at multiple levels of the neuroaxis, including in the brain, where electrical stimulation has been used to manage severe pain conditions. However, the clinical outcome of deep brain stimulation is often mixed, and the mechanisms are poorly understood. By means of electrophysiologic methods, we sought to characterize the changes in neuronal activity in the ventral posterolateral nucleus of the thalamus (VPL) in a rat model of peripheral neuropathic pain, and to reverse these changes with low‐voltage, high‐frequency stimulation (HFS) in the VPL. Extracellular single‐unit neuronal activity was recorded in naive rats and in those with sciatic chronic constriction injury (CCI). Seven days after CCI, brush‐ and pinch‐evoked firing, as well as spontaneous firing and afterdischarge, were significantly increased compared to naive rats. Spontaneous rhythmic oscillation in neuronal firing was also observed in rats with CCI. HFS decreased neuronal firing rates in rats with CCI up to ∼50% except for spontaneous activity, whereas low‐frequency stimulation had no effect. Compared to naive rats, burst firing properties (burst events, percentage of spikes in burst, and mean interburst time) were altered in rats with CCI, whereas these changes were reversed to near normal after HFS. Thermal hyperalgesia in rats with CCI was significantly attenuated by HFS. Therefore, this study demonstrates that electrical stimulation within the VPL can effectively modulate some nociceptive phenomena associated with peripheral neuropathic pain.

Minocycline injection in the ventral posterolateral thalamus reverses microglial reactivity and thermal hyperalgesia secondary to sciatic neuropathy.

We hypothesized that microglia in the ventral posterolateral (VPL) nucleus of the thalamus are reactive following peripheral nerve injury, and that inhibition of microglia by minocycline injection in the VPL attenuates thermal hyperalgesia. Our results show increased expression of OX-42 co-localized with phosphorylated p38MAPK (P-p38) in the VPL seven days after chronic constriction injury (CCI) of the sciatic nerve. However, astrocytic GFAP expression in the VPL is unchanged 7 and 14 days after CCI. Microinjection of minocycline into the VPL contralateral to CCI reverses thermal hyperalgesia, whereas vehicle injection has no effect on paw withdrawal latency. Minocycline abrogates the increased expression of OX-42 in the VPL after CCI. Therefore, peripheral nerve injury favors a hyperactive microglial phenotype in the VPL, suggesting remote neuroimmune signaling from the damaged nerve to the brain, concomitant with neuropathic behavior that is reversed by local intervention in the VPL to inhibit microglia.

Alarm or curse? The pain of neuroinflammation.

The nociceptive nervous system and the immune system serve to defend and alarm the host of imminent or actual damage. However, persistent or recurring exposure of neurons to activated immune cells is associated with an increase in painful behavior following experimental neuropathic injuries. Our understanding of the functional consequences of immune cell-neuron interaction is still incomplete. The purpose of this review is to focus on a seriously detrimental consequence of chronic activation of these two systems, by discussing the contributions of microglia and polymorphonuclear neutrophils to neuropathic pain following experimental spinal cord injury or peripheral nerve injury. Identification of molecules mediating pro-nociceptive signaling between immune cells and neurons, as well as the distinction between neuroprotective versus neuroexcitatory effects of activated immune cells, may be useful in the development of pharmacotherapy for the management of chronic pain and restoration of the beneficial alarm function of pain.