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ABSTRACT: During development of the nervous system, the formation of connections (synapses) between neurons is dependent upon electrical activity in those neurons, and neurotrophic factors produced by target cells play a pivotal role in such activity-dependent sculpting of the neural networks. A similar interplay between neurotransmitter and neurotrophic factor signaling pathways mediates adaptive responses of neural networks to environmental demands in adult mammals, with the excitatory neurotransmitter glutamate and brain-derived neurotrophic factor (BDNF) being particularly prominent regulators of synaptic plasticity throughout the central nervous system. Optimal brain health throughout the lifespan is promoted by intermittent challenges such as exercise, cognitive stimulation and dietary energy restriction, that subject neurons to activity-related metabolic stress. At the molecular level, such challenges to neurons result in the production of proteins involved in neurogenesis, learning and memory and neuronal survival; examples include proteins that regulate mitochondrial biogenesis, protein quality control, and resistance of cells to oxidative, metabolic and proteotoxic stress. BDNF signaling mediates up-regulation of several such proteins including the protein chaperone GRP-78, antioxidant enzymes, the cell survival protein Bcl-2, and the DNA repair enzyme APE1. Insufficient exposure to such challenges, genetic factors may conspire to impair BDNF production and/or signaling resulting in vulnerability of the brain to injury and neurodegenerative disorders including Alzheimer's, Parkinson's and Huntington's diseases. Further, BDNF signaling is negatively regulated by glucocorticoids. Glucocorticoids impair synaptic plasticity in the brain by negatively regulating spine density, neurogenesis and LTP, effects that are potentially linked to glucocorticoid regulation of BDNF. Findings suggest that BDNF signaling in specific brain regions mediates some of the beneficial effects of exercise and energy restriction on peripheral energy metabolism and the cardiovascular system. Collectively, the findings described in this article suggest the possibility of developing prescriptions for optimal brain health based on activity-dependent BDNF signaling.
Neuroscience 10/2012; · 3.38 Impact Factor
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ABSTRACT: Parkinson's disease (PD) patients often exhibit impaired regulation of heart rate by the autonomic nervous system (ANS) that may precede motor symptoms in many cases. Results of autopsy studies suggest that brainstem pathology, including the accumulation of α-synuclein, precedes damage to dopaminergic neurons in the substantia nigra in PD. However, the molecular and cellular mechanisms responsible for the early dysfunction of brainstem autonomic neurons are unknown. Here we report that mice expressing a mutant form of α-synuclein that causes familial PD exhibit aberrant autonomic control of the heart characterized by elevated resting heart rate and an impaired cardiovascular stress response, associated with reduced parasympathetic activity and accumulation of α-synuclein in the brainstem. These ANS abnormalities occur early in the disease process. Adverse effects of α-synuclein on the control of heart rate are exacerbated by a high energy diet and ameliorated by intermittent energy restriction. Our findings establish a mouse model of early dysregulation of brainstem control of the cardiovascular system in PD, and further suggest the potential for energy restriction to attenuate ANS dysfunction, particularly in overweight individuals.
Neurobiology of aging 08/2012; · 5.94 Impact Factor
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ABSTRACT: Alzheimer's disease (AD) and Parkinson's disease (PD) are the two most common neurodegenerative disorders and exact a burden on our society greater than cardiovascular disease and cancer combined. While cognitive and motor symptoms are used to define AD and PD, respectively, patients with both disorders exhibit sleep disturbances including insomnia, hypersomnia and excessive daytime napping. The molecular basis of perturbed sleep in AD and PD may involve damage to hypothalamic and brainstem nuclei that control sleep-wake cycles. Perturbations in neurotransmitter and hormone signaling (e.g., serotonin, norepinephrine and melatonin) and the neurotrophic factor BDNF likely contribute to the disease process. Abnormal accumulations of neurotoxic forms of amyloid β-peptide, tau and α-synuclein occur in brain regions involved in the regulation of sleep in AD and PD patients, and are sufficient to cause sleep disturbances in animal models of these neurodegenerative disorders. Disturbed regulation of sleep often occurs early in the course of AD and PD, and may contribute to the cognitive and motor symptoms. Treatments that target signaling pathways that control sleep have been shown to retard the disease process in animal models of AD and PD, suggesting a potential for such interventions in humans at risk for or in the early stages of these disorders.
Neuromolecular medicine 05/2012; 14(3):194-204. · 5.00 Impact Factor
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ABSTRACT: Overweight sedentary individuals are at increased risk for cardiovascular disease, diabetes, and some neurological disorders. Beneficial effects of dietary energy restriction (DER) and exercise on brain structural plasticity and behaviors have been demonstrated in animal models of aging and acute (stroke and trauma) and chronic (Alzheimer's and Parkinson's diseases) neurological disorders. The findings described later, and evolutionary considerations, suggest brain-derived neurotrophic factor (BDNF) plays a critical role in the integration and optimization of behavioral and metabolic responses to environments with limited energy resources and intense competition. In particular, BDNF signaling mediates adaptive responses of the central, autonomic, and peripheral nervous systems from exercise and DER. In the hypothalamus, BDNF inhibits food intake and increases energy expenditure. By promoting synaptic plasticity and neurogenesis in the hippocampus, BDNF mediates exercise- and DER-induced improvements in cognitive function and neuroprotection. DER improves cardiovascular stress adaptation by a mechanism involving enhancement of brainstem cholinergic activity. Collectively, findings reviewed in this paper provide a rationale for targeting BDNF signaling for novel therapeutic interventions in a range of metabolic and neurological disorders.
Annals of the New York Academy of Sciences 04/2012; 1264(1):49-63. · 3.15 Impact Factor
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ABSTRACT: Recent clinical data have implicated chronic adverse stress as a potential risk factor in the development of Alzheimer’s disease
(AD) and data also suggest that normal, physiological stress responses may be impaired in AD. It is possible that pathology
associated with AD causes aberrant responses to chronic stress, due to potential alterations in the hypothalamic–pituitary–adrenal
(HPA) axis. Recent study in rodent models of AD suggests that chronic adverse stress exacerbates the cognitive deficits and
hippocampal pathology that are present in the AD brain. This review summarizes recent findings obtained in experimental AD
models regarding the influence of chronic adverse stress on the underlying cellular and molecular disease processes including
the potential role of glucocorticoids. Emerging findings suggest that both AD and chronic adverse stress affect hippocampal
neural networks in a similar fashion. We describe alterations in hippocampal plasticity, which occur in both chronic stress
and AD including dendritic remodeling, neurogenesis, and long-term potentiation. Finally, we outline potential roles for oxidative
stress and neurotrophic factor signaling as the key determinants of the impact of chronic stress on the plasticity of neural
networks and AD pathogenesis.
KeywordsAlzheimer’s disease-Chronic stress-Glucocorticoids-Hippocampal plasticity
NeuroMolecular Medicine 04/2012; 12(1):56-70. · 5.00 Impact Factor
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Eitan Okun,
Boaz Barak,
Ravit Saada-Madar, Sarah M Rothman,
Kathleen J Griffioen,
Nicholas Roberts,
Kamilah Castro,
Mohamed R Mughal,
Mario A Pita,
Alexis M Stranahan,
Thiruma V Arumugam,
Mark P Mattson
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ABSTRACT: Toll-like receptors (TLRs) play essential roles in innate immunity and increasing evidence indicates that these receptors are expressed in neurons, astrocytes and microglia in the brain where they mediate responses to infection, stress and injury. Very little is known about the roles of TLRs in cognition. To test the hypothesis that TLR4 has a role in hippocampus-dependent spatial learning and memory, we used mice deficient for TLR4 and mice receiving chronic TLR4 antagonist infusion to the lateral ventricles in the brain. We found that developmental TLR4 deficiency enhances spatial reference memory acquisition and memory retention, impairs contextual fear-learning and enhances motor functions, traits that were correlated with CREB up-regulation in the hippocampus. TLR4 antagonist infusion into the cerebral ventricles of adult mice did not affect cognitive behavior, but instead affected anxiety responses. Our findings indicate a developmental role for TLR4 in shaping spatial reference memory, and fear learning and memory. Moreover, we show that central TLR4 inhibition using a TLR4 antagonist has no discernible physiological role in regulating spatial and contextual hippocampus-dependent cognitive behavior.
PLoS ONE 01/2012; 7(10):e47522. · 4.09 Impact Factor
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ABSTRACT: Ceruloplasmin (Cp) is a ferroxidase involved in iron metabolism by converting Fe(2+) to Fe(3+), and by regulating cellular iron efflux. In the ceruloplasmin knockout (CpKO) mouse, the deregulation of iron metabolism results in moderate liver and spleen hemosiderosis, but the impact of Cp deficiency on brain neurochemistry and behavior in this animal model is unknown. We found that in contrast to peripheral tissues, iron levels in the hippocampus are significantly reduced in CpKO mice. Although it does not cause any discernable deficits in motor function or learning and memory, Cp deficiency results in heightened anxiety-like behavior in the open field and elevated plus maze tests. This anxiety phenotype is associated with elevated levels of plasma corticosterone. Previous studies provided evidence that anxiety disorders and long-standing stress are associated with reductions in levels of serotonin (5HT) and brain-derived neurotrophic factor (BDNF) in the hippocampus. We found that levels of 5HT and norepinephrine (NE), and the expression of BDNF and its receptor trkB, are significantly reduced in the hippocampus of CpKO mice. Thus, Cp deficiency causes an anxiety phenotype by a mechanism that involves decreased levels of iron, 5HT, NE, and BDNF in the hippocampus.
Journal of Neurochemistry 01/2012; 120(1):125-34. · 4.06 Impact Factor
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ABSTRACT: Chronic stress may be a risk factor for developing Alzheimer's disease (AD), but most studies of the effects of stress in models of AD utilize acute adverse stressors of questionable clinical relevance. The goal of this work was to determine how chronic psychosocial stress affects behavioral and pathological outcomes in an animal model of AD, and to elucidate underlying mechanisms. A triple-transgenic mouse model of AD (3xTgAD mice) and nontransgenic control mice were used to test for an affect of chronic mild social stress on blood glucose, plasma glucocorticoids, plasma insulin, anxiety, and hippocampal amyloid β-particle (Aβ), phosphorylated tau (ptau), and brain-derived neurotrophic factor (BDNF) levels. Despite the fact that both control and 3xTgAD mice experienced rises in corticosterone during episodes of mild social stress, at the end of the 6-week stress period 3xTgAD mice displayed increased anxiety, elevated levels of Aβ oligomers and intraneuronal Aβ, and decreased brain-derived neurotrophic factor levels, whereas control mice did not. Findings suggest 3xTgAD mice are more vulnerable than control mice to chronic psychosocial stress, and that such chronic stress exacerbates Aβ accumulation and impairs neurotrophic signaling.
Neurobiology of aging 08/2011; 33(4):830.e1-12. · 5.94 Impact Factor
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ABSTRACT: Inflammatory proteins were quantified in bilateral dorsal root ganglions (DRGs) at 1 hour and 1 day using a multiplexed assay after 2 different unilateral nerve root compression injuries.
To quantify cytokines and a chemokine in the DRG after nerve root compression with and without a chemical injury to determine contributing inflammatory factors in the DRG that may mediate radicular nociception in clinically relevant nerve root pathologies.
Inflammatory cytokines are known to relate to the behavioral hypersensitivity induced after injuries to the nerve root. However, the relative expression of these proteins in the DRG after cervical nerve root compression are not known.
The right C7 nerve root underwent transient compression (10 gf) or transient compression with a chemical irritation (10 gf + chr). The chemical injury was also given alone (chr), and the nerve root was exposed (sham), providing 2 types of controls. Mechanical allodynia was measured to assess behavioral outcomes. Interleukin (IL)-1b, IL-6, tumor necrosis factor-a, and macrophage inflammatory protein 3 (MIP3) were quantified in bilateral DRGs at 1 hour and 1 day using a multiplexed assay.
Ipsilateral allodynia at day 1 after 10 gf + chr was significantly increased over both 10 gf and chr (P < 0.049). Cytokines and MIP3 were not statistically increased over sham at 1 hour. By day 1 after 10 gf + chr, all proteins (IL-1β, IL-6, tumor necrosis factor-a, MIP3) were significantly increased over both normal and sham in the ipsilateral DRG (P < 0.036), and the cytokines were also significantly increased over chr (P < 0.029). Despite allodynia at day 1, cytokines at that time were not increased over normal or sham after either 10 gf or chr.
Nerve root compression alone may not be sufficient to induce early increases in proinflammatory cytokines in the DRG after radiculopathy and this early protein response may not be directly responsible for nociception in this type of injury.
Spine 02/2011; 36(3):197-202. · 2.08 Impact Factor
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ABSTRACT: Nerve root compression induces persistent behavioral hypersensitivity and spinal glial reactivity. Viscoelastic properties of neural tissues suggest that physiologic outcomes may depend on the duration of an applied nerve root compression. This study evaluated the time-dependent properties of the root under compression in the context of pain-related behavioral and physiologic outcomes. The decrease in applied load measured by load relaxation under compression was quantified for rat cervical (C6-C8) roots in situ for durations of 30 sec, 3 min, or 15 min (n = 6). Immediately following compression, the change in the root width relative to its original width was quantified as a measure of its structural recovery. Both load relaxation and structural recovery were significantly (p < 0.05) correlated with duration of compression. After 30 sec of compression, load relaxed by 22 +/- 10%; increasing to 36 +/- 18% and 56 +/- 20% at 3 and 15 min, respectively. Following 30 sec, 3 min, and 15 min of compression, the root recovered to 91 +/- 5%, 88 +/- 5 and 72 +/- 13% of its original width, respectively. A companion in vivo study imposed these same compression durations and sham procedures to the C7 root to evaluate pain symptoms and spinal glial reactivity. Allodynia was assessed for 7 days to measure behavioral sensitivity. Immunohistochemistry and quantitative densitometry detected GFAP and OX-42 in the dorsal horn at day 7. Significant correlations were detected between compression duration and allodynia (p < 0.03), and astrocyte and microglial activation (p < 0.01). These biomechanical and glial results imply that a similar duration of compression may modulate both sustained pain and spinal glial reactivity.
Journal of neurotrauma 05/2010; 27(5):803-14. · 4.25 Impact Factor
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ABSTRACT: Relationships between nerve root compression, behavioral sensitivity, spinal cytokines, and glial reactivity are not fully defined for painful cervical nerve root compression. Spinal cytokines were quantified after mechanical root compression (10gf), root exposure to inflammatory chromic gut material (chr), the combination of both insults together (10gf + chr) or sham. TNFalpha and IL-1beta significantly increased at 1 h (p < 0.029). IL-1alpha was significantly increased over normal, sham and chr at 1 h following 10gf and over normal and sham after 10gf + chr (p < 0.048). By day 1, only IL-1beta after 10gf remained elevated over normal (p = 0.038). Accordingly, the soluble TNF receptor-1 (sTNFR1) and the IL-1 receptor antagonist (IL-1ra) were separately administered at early time points after each injury. With sTNFR1, behavioral sensitivity was significantly decreased for 7 days after both 10gf and 10gf + chr (p < 0.005). Treatment with IL-1ra significantly reduced sensitivity for 10gf + chr (p < 0.034) but not for 10gf. Sensitivity remained significantly elevated over sham at all time points (p < 0.044). Spinal astrocytic reactivity significantly decreased for both treatments after 10gf (p < 0.002); but, only IL-1ra following 10gf + chr significantly reduced astrocytic reactivity (p < 0.001). Early increases in spinal TNFalpha, IL-1beta, and IL-1alpha may induce pain, affect spinal astrocytic responses, and appear to have differential effects in mediating the behavioral hypersensitivity produced by different types of painful cervical radicular injuries.
Annals of biomedical engineering 03/2010; 38(8):2563-76. · 2.41 Impact Factor
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ABSTRACT: Although spinal glia acquire a reactive profile in radiculopathy, glial cell proliferation remains largely unstudied. This study investigated spinal glial proliferation in a model simulating painful disc herniation; the C7 nerve root underwent compression and chromic gut suture exposure or sham procedures. A subset of injured rats received minocycline injections prior to injury. Allodynia was assessed and bromodeoxyuridine (BrdU) was injected 2 hr before tissue harvest on day 1 or 3. Spinal cell proliferation and phenotype identification were assayed by fluorescent colabeling with antibodies to BrdU and either glial fibrillary acidic protein (astrocytes) or Iba1 (microglia). At day 1, ipsilateral allodynia was significantly increased (P < 0.001) for injury over sham. Minocycline treatment significantly decreased ipsilateral allodynia to sham levels at day 1 (P < 0.001). At day 3, ipsilateral allodynia remained and contralateral allodynia was also present for injury (P< 0.003) over sham. The number of BrdU-positive cells in the ipsilateral spinal dorsal horn at day 1 after injury was significantly elevated (P < 0.001) over sham. Approximately 70% of BrdU-positive cells labeled positively for Iba1; dividing microglia were significantly increased (P < 0.004) in the ipsilateral dorsal horn at day 1 following injury compared with sham. Spinal cellular proliferation after injury was not changed by minocycline injection. By day 3, the number of BrdU-positive cells had returned to sham levels bilaterally. Data indicate that spinal microglia proliferate after injury but that proliferation is not abolished by minocycline treatment that attenuates allodynia, indicating that spinal microglial proliferation may be related to injury and may not be linked to changes in sensory perception.
Journal of Neuroscience Research 05/2009; 87(12):2709-17. · 2.74 Impact Factor
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ABSTRACT: Inflammatory cytokines contribute to lumbar radiculopathy. Regulation of cytokines for transient cervical injuries, with or without longer-lasting inflammation, remains to be defined. The C7 root in the rat underwent compression (10gf), chromic gut suture exposure (chr), or their combination (10gf+chr). Ipsilateral C7 spinal cord and dorsal root ganglia (DRG) were harvested at 1 hour after injury for real-time PCR analysis of IL-1beta, IL-6, and TNF-alpha. Cytokine mRNA increased after all 3 injuries. TNF-alpha mRNA in the DRG was significantly increased over sham after 10gf+chr (P = .026). Spinal IL-1beta was significantly increased over sham after 10gf and 10gf+chr (P < .024); IL-6 was significantly increased after 10gf+chr (P < .024). In separate studies, the soluble TNF-alpha receptor was administered at injury and again at 6 hours in all injury paradigms. Allodynia was assessed and tissue samples were harvested for cytokine PCR. Allodynia significantly decreased with receptor administration for 10gf and 10gf+chr (P < .005). Treatment also significantly decreased IL-1beta and TNF-alpha mRNA in the DRG for 10gf+chr (P < .028) at day 1. Results indicate an acute, robust cytokine response in cervical nerve root injury with varying patterns, dependent on injury type, and that early increases in TNF-alpha mRNA in the DRG may drive pain-related signaling for transient cervical injuries. PERSPECTIVE: Inflammatory cytokine mRNA in the DRG and spinal cord are defined after painful cervical nerve root injury. Studies describe a role for TNF-alpha in mediating behavioral sensitivity and inflammatory cytokines in transient painful radiculopathy. Results outline an early response of inflammatory cytokine upregulation in cervical pain.
The journal of pain: official journal of the American Pain Society 10/2008; 10(1):90-9. · 3.78 Impact Factor
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ABSTRACT: Both chemical irritation and mechanical compression affect radicular pain from disc herniation. However, relative effects of these insults on pain symptoms are unclear. This study investigated chemical and mechanical contributions for painful cervical nerve root injury. Accordingly, the C7 nerve root separately underwent chromic gut exposure, 10gf compression, or their combination. Mechanical allodynia was assessed, and glial reactivity in the C7 spinal cord tissue was assayed at days 1 and 7 by immunohistochemistry using GFAP and OX-42 as markers of astrocytes and microglia, respectively. Both chromic gut irritation and 10gf compression produced ipsilateral increases in allodynia over sham (p<0.048); combining the two insults significantly (p<0.027) increased ipsilateral allodynia compared to either insult alone. Behavioral hypersensitivity was also produced in the contralateral forepaw for all injuries, but only the combined insult was significantly increased over sham (p<0.031). Astrocytic activation was significantly increased over normal (p<0.001) in the ipsilateral dorsal horn at 1 day after either compression or the combined injury. By day 7, GFAP-reactivity was further increased for the combined injury compared to day 1 (p<0.001). In contrast, spinal OX-42 staining was generally variable, with only mild activation at day 1. By day 7 after the combined injury, there were significant (p<0.003) bilateral increases in OX-42 staining over normal. Spinal astrocytic and microglial reactivity follow different patterns after chemical root irritation, compression, and a combined insult. The combination of transient compression and chemical irritation produces sustained bilateral hypersensitivity, sustained ipsilateral spinal astrocytic activation and late onset bilateral spinal microglial activation.
Brain Research 11/2007; 1181:30-43. · 2.73 Impact Factor
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ABSTRACT: Study Design. Behavioral and immunohistochemical analysis in rat models of persistent and transient allodynia.
Objectives. To examine separate cervical nerve root injuries (compression, transection) for producing behavioral hypersensitivity and investigate spinal neuropeptides to understand relationships to pain symptoms.
Summary of Background Data. Mechanical cervical nerve root injury can be a source of neck pain. Painful lumbar radiculopathy models show that different nerve root ligation intensities produce differential allodynia responses. Spinal neuropeptides can mediate pain responses. Yet, little is known about their contributions to pain in the cervical spine.
Methods. Rats underwent separate procedures on the right C7 nerve roots: transection (n = 12), 10-gf compression for 15 minutes (n = 11), or sham (n = 5). Ipsilateral forepaw mechanical allodynia was measured after surgery for 7 days. C7 spinal cord tissue was analyzed by immunohistochemistry for substance P and calcitonin gene-related peptide (CGRP) expression on days 1 and 7 for each injury; densitometry quantified immunoreactivity in lamina I of the ipsilateral dorsal horn.
Results. Both injuries immediately produced significant increases in allodynia. Sensitivity was sustained following root compression, and at day 7, was not different from day 1. By day 7 after transection, allodynia had returned to baseline and sham levels, significantly decreasing from day 1 (P = 0.0012). Spinal substance P and CGRP were increased over normal at day 1 for both injuries and decreased with time for CGRP after transection, which paralleled behaviors. For individual rats, substance P was significantly (P < 0.001) correlated with CGRP expression for both injuries.
Conclusions. Compression and transection of the cervical nerve root produce different forepaw allodynia responses, with persistent and transient sensitivity, respectively. Spinal neuropeptide expression in these models parallels this sensitivity, suggesting their potential role in pain symptoms.
Spine 11/2005; 30(22):2491-2496. · 2.08 Impact Factor
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ABSTRACT: Behavioral and immunohistochemical analysis in rat models of persistent and transient allodynia.
To examine separate cervical nerve root injuries (compression, transection) for producing behavioral hypersensitivity and investigate spinal neuropeptides to understand relationships to pain symptoms.
Mechanical cervical nerve root injury can be a source of neck pain. Painful lumbar radiculopathy models show that different nerve root ligation intensities produce differential allodynia responses. Spinal neuropeptides can mediate pain responses. Yet, little is known about their contributions to pain in the cervical spine.
Rats underwent separate procedures on the right C7 nerve roots: transection (n = 12), 10-gf compression for 15 minutes (n = 11), or sham (n = 5). Ipsilateral forepaw mechanical allodynia was measured after surgery for 7 days. C7 spinal cord tissue was analyzed by immunohistochemistry for substance P and calcitonin gene-related peptide (CGRP) expression on days 1 and 7 for each injury; densitometry quantified immunoreactivity in lamina I of the ipsilateral dorsal horn.
Both injuries immediately produced significant increases in allodynia. Sensitivity was sustained following root compression, and at day 7, was not different from day 1. By day 7 after transection, allodynia had returned to baseline and sham levels, significantly decreasing from day 1 (P = 0.0012). Spinal substance P and CGRP were increased over normal at day 1 for both injuries and decreased with time for CGRP after transection, which paralleled behaviors. For individual rats, substance P was significantly (P < 0.001) correlated with CGRP expression for both injuries.
Compression and transection of the cervical nerve root produce different forepaw allodynia responses, with persistent and transient sensitivity, respectively. Spinal neuropeptide expression in these models parallels this sensitivity, suggesting their potential role in pain symptoms.
Spine 11/2005; 30(22):2491-6. · 2.08 Impact Factor
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Sarah M Rothman
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ABSTRACT: As many as 30% of Americans suffer from chronic pain. Both chemical irritation and mechanical compression have been implicated in nerve root-mediated pain. However, the relative effects of these neural insults on pain symptoms are unclear. In vivo pain models characterize tissue injury, pain symptoms, and the physiologic nociceptive mechanisms relating the two. However, differences in spinal inflammation have not been defined for painful transient cervical nerve root compression injuries. The central hypothesis of this work was that persistent cervical nerve root-mediated pain produced by mechanical injury alone is mediated through different inflammatory pathways than the pain resulting from a combined mechanical and chemical injury. Behavioral hypersensitivity was quantified after nerve root compression with and without a chemical insult to define the relative roles of each of a mechanical compression and chemical irritation in inducing persistent pain. Although spinal glial reactivity has been detected in pain models, not all of the hallmarks of glial reactivity were described and the relationships between behavioral hypersensitivity and spinal glial reactivity have not been quantified for transient mechanical loading of the cervical nerve root. Accordingly, spinal glial reactivity was temporally assessed after injury using markers of activation and cellular proliferation. Also, inflammatory cytokines in the DRG and spinal cord were quantified temporally after both painful nerve root compression injury types and the spinal cellular source of interleukin-1α was identified. Pharmacologic agents were used to selectively block cytokine signaling in order to identify relationships between inflammatory cytokines, behavioral hypersensitivity and spinal glial reactivity in painful nerve root injury. Finally, it remains unknown how the duration of applied compression affects resulting pain symptoms and spinal inflammation. As such, coordinated in situ and in vivo studies were completed to establish relationships between the duration of applied nerve root compression, the mechanical response of the root, and inflammatory outcomes in order to define mechanical responses induced by compression that transduce nociceptive signals and mediate pain. Collectively, studies establish relationships between nerve root compression and chemical irritation, pain symptoms, and spinal inflammation, and lay a foundation for understanding the mechanisms of nerve root injury that lead to persistent pain.
Dissertations available from ProQuest.
