Effects of early exercise training on the severity of autonomic dysreflexia following incomplete spinal cord injury in rodents.

Hemodynamic instability and cardiovascular (CV) dysfunction are hallmarks of patients living with cervical and high thoracic spinal cord injuries (SCI). Individuals experience bouts of autonomic dysreflexia (AD) and persistent hypotension which hamper the activities of daily living. Despite the widespread use of exercise training to improve health and CV function after SCI, little is known about how different training modalities impact hemodynamic stability and severity of AD in a model of incomplete SCI. In this study, we used implantable telemetry devices to assess animals with T2 contusions following 3.5 weeks of exercise training initiated 8 days post-injury: passive hindlimb cycling (T2-CYC, n = 5) or active forelimb swimming (T2-SW, n = 6). Uninjured and non-exercised SCI control groups were also included (CON, n = 6; T2-CON, n = 7; T10-CON, n = 6). Five weeks post-injury, both T2-CON and T2-CYC presented with resting hypotension compared to uninjured CON and T10-CON groups; no differences were noted in resting blood pressure in T2-SW versus CON and T10-CON. Furthermore, pressor responses to colorectal distention (AD) were larger in all T2-injured groups compared to T10-CON, and were not attenuated by either form of exercise training. Interestingly, when T2-injured animals were re-stratified based on terminal BBB scores (regardless of training group), animals with limited hindlimb recovery (T2-LOW, n = 7) had more severe AD responses. Our results suggest that the spontaneous recovery of locomotor and autonomic function after severe but incomplete T2 SCI also influences the severity of AD, and that short periods (3.5 weeks) of passive hindlimb cycling or active forelimb swimming are ineffective in this model.

Acute post-injury blockade of α2δ-1 calcium channel subunits prevents pathological autonomic plasticity after spinal cord injury.

After spinal cord injury (SCI), normally innocuous visceral or somatic stimuli can trigger uncontrolled reflex activation of sympathetic circuitry, causing pathological dysautonomia. We show that remarkable structural remodeling and plasticity occur within spinal autonomic circuitry, creating abnormal sympathetic reflexes that promote dysautonomia. However, when mice are treated early after SCI with human-equivalent doses of the US Food and Drug Administration (FDA)-approved drug gabapentin (GBP), it is possible to block multi-segmental excitatory synaptogenesis and abolish sprouting of autonomic neurons that innervate immune organs and sensory afferents that trigger pain and autonomic dysreflexia (AD). This "prophylactic GBP" regimen decreases the frequency and severity of AD and protects against SCI-induced immune suppression. These benefits persist even 1 month after stopping treatment. GBP could be repurposed to prevent dysautonomia in at-risk individuals with high-level SCI.

Minocycline Reduces the Severity of Autonomic Dysreflexia after Experimental Spinal Cord Injury.

Spinal cord injury (SCI) is a devastating neurological condition for which there is no effective treatment to restore neurological function. The development of new treatments for those with SCI may be hampered by the insensitivity of clinical tools to assess motor function in humans. Treatments aimed at preserving neuronal function through anti-inflammatory pathways (i.e., neuroprotection) have been a mainstay of pre-clinical SCI research for decades. Minocycline, a clinically available antibiotic agent with anti-inflammatory properties, has demonstrated promising neuroprotective effects in a variety of animal models and improved motor recovery in a Phase-2 human trial. Here, we leveraged our recently developed T3 severe contusion model in the rat to determine the ability of minocycline to preserve descending sympathoexcitatory axons and improve cardiovascular control after SCI. Forty-one male Wistar rats were randomized to either a treatment group (minocycline; n = 20) or a control group (vehicle; n = 21). All rats received a severe T3 contusion. Minocycline (or vehicle) was administered intraperitoneally at one hour post-injury (90 mg/kg), then every 12 h for two weeks (45 mg/kg). Neuroanatomical correlates (lesion area, descending sympathoexcitatory axons) were assessed, in addition to an assessment of cardiovascular control (hemodynamics, autonomic dysreflexia) and motor behavior. Here, we show that minocycline reduces lesion area, increases the number of descending sympathoexctitatory axons traversing the injury site, and ultimately reduces the severity of autonomic dysreflexia. Finally, we show that autonomic dysreflexia is a more sensitive marker of treatment stratification than motor function.

High Thoracic Contusion Model for the Investigation of Cardiovascular Function after Spinal Cord Injury.

Cardiovascular disease is the leading cause of death for individuals with spinal cord injury (SCI). Because of a lack of a standardized and accessible animal model for cardiovascular disease after SCI, few laboratories have conducted pre-clinical trials aimed at reinstating descending cardiovascular control. Here, we utilized common contusion methodology applied to the midline of the upper-thoracic cord of adult Wistar rats accompanied with telemetric blood pressure monitoring and FluoroGold retrograde neuronal tracing, as well as lesion site and lumbrosacral afferent immunohistochemistry. We demonstrate widespread cardiovascular (i.e., impaired resting hemodynamics, autonomic dysreflexia) and hindlimb dysfunction at 1 month post-injury. Further, we provide a description of the neuroanatomical changes that accompany cardiovascular abnormalities. Specifically, we describe 1) the injury site including white matter sparing as well as lesion volume, and their correlations to cardiovascular as well as motor outcomes; 2) the severity of injury-dependent changes in sympathoexcitatory medullary neuron spinal connectivity, as measured using FluoroGold tracing; and 3) the extent of aberrant afferent plasticity within the lumbosacral region of the spinal cord, which has been linked to the development of autonomic dysreflexia. We believe that this model, which utilizes equipment common to numerous SCI laboratories, can serve as a research standard for studies specifically aimed at investigating autonomic neuroprotective and regenerative strategies following SCI.

Olfactory ensheathing cells but not fibroblasts reduce the duration of autonomic dysreflexia in spinal cord injured rats.

Autonomic dysreflexia is a common complication after high level spinal cord injury and can be life-threatening. We have previously shown that the acute transplantation of olfactory ensheathing cells into the lesion site of rats transected at the fourth thoracic spinal cord level reduced autonomic dysreflexia up to 8weeks after spinal cord injury. This beneficial effect was correlated with changes in the morphology of sympathetic preganglionic neurons despite the olfactory cells surviving no longer than 3weeks. Thus the transitory presence of olfactory ensheathing cells at the injury site initiated long-term functional as well as morphological changes in the sympathetic preganglionic neurons. The primary aim of the present study was to evaluate whether olfactory ensheathing cells survive after transplantation within the parenchyma close to sympathetic preganglionic neurons and whether, in this position, they still reduce the duration of autonomic dysreflexia and modulate sympathetic preganglionic neuron morphology. The second aim was to quantify the density of synapses on the somata of sympathetic preganglionic neurons with the hypothesis that the reduction of autonomic dysreflexia requires synaptic changes. As a third aim, we evaluated the cell type-specificity of olfactory ensheathing cells by comparing their effects with a control group transplanted with fibroblasts. Animals transplanted with OECs had a faster recovery from hypertension induced by colorectal distension at 6 and 7weeks but not at 8weeks after T4 spinal cord transection. Olfactory ensheathing cells survived for at least 8weeks and were observed adjacent to sympathetic preganglionic neurons whose overall number of primary dendrites was reduced and the synaptic density on the somata increased, both caudal to the lesion site. Our results showed a long term cell type-specific effects of olfactory ensheathing cells on sympathetic preganglionic neurons morphology and on the synaptic density on their somata, and a transient cell type-specific reduction of autonomic dysreflexia.

Silencing spinal interneurons inhibits immune suppressive autonomic reflexes caused by spinal cord injury.

Spinal cord injury (SCI) at high spinal levels (e.g., above thoracic level 5) causes systemic immune suppression; however, the underlying mechanisms are unknown. Here we show that profound plasticity develops within spinal autonomic circuitry below the injury, creating a sympathetic anti-inflammatory reflex, and that chemogenetic silencing of this reflex circuitry blocks post-SCI immune suppression. These data provide new insights and potential therapeutic options for limiting the devastating consequences of post-traumatic autonomic hyperreflexia and post-injury immune suppression.

Characterizing the temporal development of cardiovascular dysfunction in response to spinal cord injury.

Spinal cord injury (SCI) is associated with rapid and sustained impairments in cardiovascular function that ultimately cause an early onset of cardiovascular disease. We know remarkably little about the temporal progression of cardiovascular disturbances, but such an understanding is critical to inform clinical management and develop appropriate intervention strategies. To characterize the cardiovascular response to SCI, six male Wistar rats were instrumented with telemetry and assessed for continuous arterial blood pressure (BP), core body temperature, and heart rate (HR) 7 days before and up to 28 days after T3 SCI. Hemodynamic variables were averaged day by day and hour by hour. Spontaneously occurring autonomic dysreflexia (AD) was characterized by applying a novel algorithm to continuous BP and HR data, and induced AD was assessed weekly via the BP response to colorectal distension. Systolic BP was reduced at all time points after SCI compared with before SCI (p<0.003), except at 4 and 6 days post-injury. Core body temperature was reduced at 2 days post-SCI only (p=0.001). The nocturnal dip in BP and temperature observed pre-SCI was absent during the first 14 days post-SCI, but returned from 21 days post-SCI on (p<0.024). The frequency and severity of spontaneously occurring AD events were significantly less between days 6 and 10 post-SCI compared all other time points (p<0.037). The pressor response to colorectal distension was greater at 14, 21, and 28 days post-SCI compared with at 7 days post-SCI (all p<0.004). In conclusion, SCI induces rapid and profound alterations in basal hemodynamics and diurnal rhythms that partially recover by 14 days post-SCI. AD, on the other hand, is acutely present post-SCI, but the frequency and severity of AD events increase substantially from 14 days post-SCI on.

Characterization of supraspinal vasomotor pathways and autonomic dysreflexia after spinal cord injury in F344 rats.

Cardiovascular dysfunction usually occurs after high thoracic and cervical spinal cord injury (SCI). The disruption of supraspinal vasomotor pathways (SVPs) results in the loss of bulbospinal regulation of sympathetic preganglionic neurons, leading to hypotension and compensatory tachycardia at rest. Episodic autonomic dysreflexia can develop upon sensory stimulation below the level of injury. In rodents, the precise spatial distribution of SVPs in the spinal cord originating from the rostral ventrolateral medulla (RVLM) has not been fully defined. To facilitate future studies of axon regeneration to regain cardiovascular control, we injected biotinylated dextran amine (BDA) bilaterally into the RVLM to anterogradely trace SVPs in Fischer 344 (F344) rats. Three weeks later, BDA-labeled descending projections were predominantly localized within the dorsolateral funiculus throughout the cervical and thoracic spinal segments as expected. Additionally, BDA-labeled fibers were also observed in ventral white matter. After a T4 dorsal hemisection to interrupt the dorsolateral funiculus, BDA labeled terminals originating from the ventral white matter as well as serotonergic projections were still detected in regions of autonomic nuclei below the injury. Based on these results, we examined cardiovascular responses after different lesions at spinal level T4, including lateral or dorsal hemisection, dorsolateral or complete transection. Hemodynamic dysfunction and autonomic dysreflexia were only elicited in rats with complete T4 transections when all SVPs were disrupted. Hence, F344 rats with complete T4 transections provide a reliable model for investigating means to improve cardiovascular functional recovery after SCI.

Cortical blindness associated with autonomic dysreflexia in a man with tetraplegia: a rare but serious complication.

CONTEXT: To describe a case of a 44-year-old man with complete C4 tetraplegia who developed transient cortical blindness in the subacute setting following episodes of autonomic dysreflexia. FINDINGS: Transient cortical blindness the day after surgery for appendicitis that had resulted in severe autonomic dysreflexia (AD) requiring aggressive blood pressure management. Imaging showed no evidence of acute stroke, but did show vasospasm in the occipital lobes. Vision improved over the next couple of months. CONCLUSION/CLINICAL RELEVANCE: This case illustrates a possible profound vasomotor phenomenon (cortical blindness) associated with AD and its symptomatic treatment. Early recognition of AD and treatment of its underlying cause cannot be overemphasized.

Headache attributed to autonomic dysreflexia: an underrecognized clinical entity.

OBJECTIVE: The recognition and the management of headache attributed to autonomic dysreflexia after spinal cord injury (SCI) are challenging issues. Given this, I systematically reviewed the literature to establish the features of the headache attributed to autonomic dysreflexia after SCI. METHODS: This review included all articles that addressed any feature of headache attributed to autonomic dysreflexia after SCI. The literature search addressed publications from 1950 until April 2010. The literature search was conducted using MEDLINE, CINAHL, EMBASE, and PsycINFO® databases. The literature search was limited to only articles written in English. RESULTS: Of the 273 publications captured in all 4 databases, 45 articles fulfilled our inclusion and exclusion criteria. Typically, the headache attributed to autonomic dysreflexia is a sudden-onset, severe headache accompanied by several signs and symptoms including increased blood pressure, altered heart rate, and diaphoresis cranial to the level of SCI, which is triggered by different noxious and nonnoxious stimuli. However, clinicians need to be aware of other headache features and the variety of potential triggers associated with the headache attributed to autonomic dysreflexia. CONCLUSIONS: The greater awareness of this clinical entity among clinicians, in particular neurologists, is crucial for early recognition and proper management of episodes of autonomic dysreflexia to prevent its complications.

Inhibition of CXCR1 and CXCR2 chemokine receptors attenuates acute inflammation, preserves gray matter and diminishes autonomic dysreflexia after spinal cord injury.

STUDY DESIGN: Female Wistar rats (225 g) underwent spinal cord injury (SCI) at the T4 segment and were assigned to one of the three groups treated with: (1) saline; (2) 7.5 mg kg(-1) Reparixin; or (3) 15 mg kg(-1) Reparixin. Reparixin is a small molecule, allosteric noncompetitive inhibitor of CXCR1 and CXCR2 chemokine receptors involved in inflammation. METHODS: Spinal cord homogenates at 12 and 72 h post-SCI were assayed for tumor necrosis factor α (TNF-α) and cytokine-induced neutrophil chemoattractant (CINC)-1 using enzyme-linked immunosorbant assay (ELISA). Myeloperoxidase activity and western blots for CD68, Fas and p75 content were used to assess inflammation and death receptor ligands, respectively. Histopathology and neurological outcomes were assessed by immunohistochemistry, locomotion scoring and cardiovascular measurement of autonomic dysreflexia 4 weeks post-SCI. RESULTS: Both 7.5 and 15 mg kg(-1) doses of Reparixin reduced levels of TNF-α and CINC-1 72 h post-SCI and decreased macrophage (CD68) content in the spinal cord lesion. Only 15 mg kg(-1) Reparixin reduced both Fas and p75 levels in the spinal cord compared with untreated SCI. We observed a reduced lesion area and increased neuron number in the gray matter of Reparixin-treated rats. Hindlimb motor scores at 7 and 28 days post-SCI were improved by 15 mg kg(-1) Reparixin treatment. Both 7.5 and 15 mg kg(-1) Reparixin reduced development of autonomic dysreflexia 4 weeks post-SCI. The change in mean arterial pressure, induced by cutaneous or visceral stimulation, was reduced by 40-50%. CONCLUSION: Acute treatment with 15 mg kg(-1) Reparixin reduces acute inflammation and is associated with minor improvements in motor function and a significant reduction in the severity of autonomic dysreflexia.

Autonomic dysreflexia associated with Charcot spine following spinal cord injury: a case report and literature review.

We report the case of a 50-year-old man presenting symptoms of autonomic dysreflexia associated with Charcot spine following complete C8 spinal cord injury. After posterior lumbar interbody fusion of L2/3 with simultaneous posterior instrumentation from L1 to L5, the patient recovered from the symptoms of autonomic dysreflexia. Although the patient began to faint when he sat up and transferred after surgery, it began to be resolved by continuous urinary catheterization, setting a limit to activity and prescription of alpha-, beta-stimulants. Within a few weeks after performing these treatment strategies, he could return to active wheelchair life, and no recurrence of any symptoms was noted at the 6-year follow-up. Although there are only a small number of cases with Charcot spine presenting autonomic dysreflexia, surgical stabilization of the affected lesion for patients with this condition should be recommended.

Olfactory ensheathing cells reduce duration of autonomic dysreflexia in rats with high spinal cord injury.

Autonomic dysreflexia is a common complication in high spinal cord injury and can result in serious consequences and death. Here we have examined the effect of acute transplantation of olfactory ensheathing cells on cardiovascular functions in rats. After T4 transection, radio-telemetric recording in conscious animals was used to study blood pressure and heart rate at rest and during autonomic dysreflexia for up to 8 weeks post-injury. Olfactory ensheathing cells from syngeneic rats were transplanted at the injury site; control animals received culture medium only. At the study end point, we examined morphometric features of sympathetic preganglionic neurons above and below the injury. T4 transection resulted in a fall in resting mean arterial pressure and an increase in resting heart rate. Colorectal distension, used to trigger autonomic dysreflexia, caused episodic hypertension and bradycardia. Although the cell transplantation had no effect on resting cardiovascular parameters, it led to a significantly faster recovery from hypertension, with the recovery time shortened by approximately 25%. The transection resulted in an increase in soma size of sympathetic preganglionic neurons above and below the injury. OEC transplantation normalised this change below the injury and increased dendritic length of preganglionic neurons above the injury, compared to controls. It has been proposed that changes in sympathetic preganglionic neurons following spinal cord transection may be related to the development of autonomic dysreflexia. Our results suggest that olfactory ensheathing cells may alter the morphology of these neurons, and hence modify their activity in the neuronal networks responsible for the dysreflexic reaction.

Distinct subtypes of myelitis in systemic lupus erythematosus.

OBJECTIVE: Myelitis causes pain, weakness, and sphincteric deficits, and is 1,000-fold more prevalent in patients with systemic lupus erythematosus (SLE) than in the general population. For the last century, descriptions of SLE myelitis have been primarily limited to case reports. In contrast, larger-scale cohort studies have revealed that myelitis occurring in the idiopathic demyelinating diseases (i.e., multiple sclerosis versus neuromyelitis optica) represents distinct syndromes. This study was undertaken to determine whether SLE myelitis similarly encapsulates distinct syndromes. METHODS: We analyzed a cohort of 22 patients with SLE and myelitis. Patients were assessed for neurologic variables related to myelitis and for clinical and serologic features of SLE. Magnetic resonance images of the spine, cerebrospinal fluid profiles, and autoantibody profiles were obtained. RESULTS: Eleven patients presented with signs of gray matter dysfunction (i.e., flaccidity and hyporeflexia), whereas 11 patients presented with signs of white matter dysfunction (i.e., spasticity and hyperreflexia). Patients with gray matter dysfunction were more likely to have irreversible paraplegia (P < 0.01), despite presenting with a monophasic versus polyphasic course (P = 0.01), higher levels of SLE activity (mean SLE Disease Activity Index 9.8 versus 2.0; P = 0.01), and a cerebrospinal fluid profile indistinguishable from bacterial meningitis. Prior to irreversible paraplegia, these patients presented with prodromes of fever and urinary retention, but were misdiagnosed by physicians of different specialties as having urinary tract infections. Patients with white matter dysfunction were more likely to meet criteria for neuromyelitis optica (P = 0.04) and were also more likely to have antiphospholipid antibodies (lupus anticoagulant) (P = 0.01). CONCLUSION: Our findings indicate that SLE myelitis encapsulates 2 distinct and previously unrecognized syndromes that can be distinguished clinically by gray matter versus white matter findings. Recognition of fever and urinary retention as prodromes of irreversible paraplegia may allow earlier diagnosis and treatment in SLE patients presenting with gray matter findings.

Hardware failure and spinal pseudoarthrosis causing autonomic dysreflexia: a report of two cases.

STUDY DESIGN: Case report. OBJECTIVES: To describe two cases of hardware failure with pseudoarthrosis causing autonomic dysreflexia. The first patient was a 24-year-old woman with T3 ASIA (American Spinal Injury Association)-A paraplegia who developed complete failure and breakage of the Luque rods at the T11-12 region. The second woman was a 36-year-old T5 ASIA-A complete paraplegic who fractured her Harrington rods at T12 and L1 bilaterally. SETTING: Saskatoon City Hospital, Saskatchewan, Canada. METHODS AND RESULTS: Both patients underwent operation for surgical fixation. In both cases, stabilization and fusion of the spinal deformity abolished the autonomic dysreflexia. CONCLUSION: Owing to the failure of spine-stabilizing hardware, sitting upright may cause an afferent stimulus that triggers the onset and worsening of symptoms associated with autonomic dysreflexia. Therefore, in contrast to current acute treatment regimes, lying down may be preferred to sitting upright (to decrease blood pressure) as a means to relieve the afferent stimulus. Surgical correction and hardware replacement alleviated the symptoms in these two patients.

Reversible posterior leukoencephalopathy in a patient with autonomic dysreflexia: a case report.

STUDY DESIGN: Case report. OBJECTIVES: To report a case of reversible posterior leukoencephalopathy (RPL) in a patient with traumatic cervical spinal cord injury. SETTING: Neurologic inpatient Unit, Lahey Clinic, Burlington, MA, USA. METHODS: A 55-year-old woman with a residual spastic quadriparesis from a traumatic C5-C6 fracture developed, during an assisted cough maneuver, sudden severe headache followed by cortical blindness in the setting of high blood pressure. Magnetic resonance imaging (MRI) showed T2 hyperintensities in the subcortical white matter of both medial occipital lobes and left post-central gyrus. RESULTS: Elevation of the head of the bed during subsequent cough maneuvers with occasional use of sublingual nifedipine prevented further episodes of acute arterial hypertension and development of new symptoms. Repeat MRI of the head done one month later was normal. CONCLUSION: RPL can occur in the setting of autonomic dysreflexia in patients with traumatic cervical cord injury. The prompt recognition of this syndrome is of importance to prevent further morbidity and mortality in patients with spinal cord injury.

The expression of Fos-labeled spinal neurons in response to colorectal distension is enhanced after chronic spinal cord transection in the rat.

The present study used Fos-like immunoreactivity to examine neuronal activation in response to colorectal distension in rats at 1 day or 30 days following spinal cord transection or sham transection. Fifty-five Wistar rats were anesthetized and an incision was made to expose the T(5) spinal segment. The dura was reflected away in all rats and a complete transection at the rostral end of the T(5) segment was given to the lesioned group. At 1 day (acute) or 30 days (chronic) post-surgery, conscious rats were subjected to a 2 h period of intermittent colorectal distension. Rats were perfused and spinal segments L(5)-S(2) were removed and processed for Fos-like immunoreactivity. Spinal cord transection alone had no effect on Fos-labeling in either acute or chronic rats. In acute rats, colorectal distension produced significant increases in Fos-labeling in the superficial and deep dorsal horn regions. In chronic rats, colorectal distension produced a three-fold increase in Fos-labeled neurons that was manifest throughout all laminar regions. These results indicate that the number of neurons expressing Fos in response to colorectal distension is much greater after a chronic spinal cord transection than after an acute transection. Since Fos is an indicator of neuronal activation, the results show that many more neurons become active in response to colorectal distension following a chronic spinal injury. This suggests that a functional reorganization of spinal circuits occurs following chronic spinal cord transection. This may ultimately result in altered visceral and somatic functions associated with spinal cord injury in humans.

Autonomic dysreflexia in a mouse model of spinal cord injury.

Most experimental studies of spinal cord injury have centered on the rat as an experimental model. A shift toward a mouse model has occurred in recent years because of its usefulness as a genetic tool. While many studies have concentrated on motor function and the inflammatory response following spinal cord injury in the mouse, the development of autonomic dysreflexia after injury has yet to be described. Autonomic dysreflexia is a condition in which episodic hypertension develops after injuries above the mid-thoracic segment of the spinal cord. In this study 129Sv mice received a spinal cord transection at the second thoracic segment. The presence of autonomic dysreflexia was assessed 2 weeks later. Blood pressure responses to stimulation were as follows: moderate cutaneous pinch caudal to the injury (35+/-6 mm Hg), tail pinch (25+/-7 mm Hg), and a 0.3 ml balloon distension of the colon (37+/-4 mm Hg). Previous reports have suggested that small diameter primary afferent fiber sprouting after spinal cord injury may be responsible for the development of autonomic dysreflexia. In order to determine whether autonomic dysreflexia in the mouse may be caused by a similar mechanism, the size of the small diameter primary afferent arbor in spinal cord-injured and sham-operated animals was assessed by measuring the area occupied by calcitonin gene-related peptide-immunoreactive fibers. The percentage increase in the area of the small diameter primary afferent arbor in transected over sham-operated spinal cords was 46%, 45% and 80% at spinal segments thoracic T5-8, thoracic T9-12 and thoracic T13-lumbar L2 respectively. This study demonstrates the development of autonomic dysfunction in a mouse model of spinal cord injury that is associated with sprouting of calcitonin gene-related peptide fibers. These results provide strong support for the use of this mouse model of spinal cord injury in the study of autonomic dysreflexia.

Afferent pathways of sympathetic skin response in spinal cord: a clinical and electrophysiological study.

BACKGROUND: Sympathetic skin response (SSR) recording is an established test of sudomotor autonomic functions. However, knowledge of its pathways in spinal cord is putative. OBJECTIVE: This study involved subjects with isolated spinal cord lesions to evaluate the afferent pathways of SSR. METHODS: Clinical examination was done according to standard neurological classification of spinal cord injury. Electrophysiological evaluation included: (1) conventional nerve conduction studies to exclude peripheral nerve lesions, (2) scalp somato-sensory-evoked potentials (SEP) with posterior tibial nerve (PTN) stimulation and (3) SSR recording from palm by stimulating supra orbital nerve (SON) at forehead, and PTN at ankle. Subjects with absent SSR in palm to SON stimulation were excluded. In such patients, the afferent tracts were considered abnormal when SSR was absent in palm on stimulation of PTN. RESULTS: Among 37 subjects (age-28.1+/-12.8 years), the afferent tracts of SSR were affected in 13. Sparing of afferent SSR tracts correlated with preservation of bladder sensations (P<0.01). There was no correlation between SSR and SEP. CONCLUSIONS: Spinal cord lesions frequently involve afferent tracts of SSR. Spinal afferents of SSR are closely related with tracts of bladder sensations and are different from pathways for SEP.

Increased innervation of rat preganglionic sympathetic neurons by substance P containing nerve fibers in response to spinal cord injury.

Substance P (SP) is elevated in the intermediate zone caudal to a spinal cord lesion presumably due to sprouting of intraspinal and primary afferent axons. It is unclear, however, if axon terminals are in direct contact with preganglionic neurons located within the different autonomic subnuclei. Therefore, the innervation of preganglionic sympathetic neurons by SP was quantified using confocal imaging and morphometric image analysis. The number of SP-immunoreactive varicosities apposed to nitric oxide synthase-positive neurons significantly increased bilaterally in all sympathetic areas of segment T2 one week after low cervical hemisection at C6/7. Consequently, direct excitatory effects of SP on preganglionic neurons may play an important role in the dysregulation of arterial blood pressure observed in patients with spinal cord injury at the cervical or upper thoracic level.