Opioid peptide response to spinal cord stimulation in chronic critical limb ischemia

Twelve patients with chronic critical limb ischemia in whom a spinal cord stimulation (SCS) system had been implanted for at least one year had increased microvascular flow and achieved healing of trophic acral lesions. After switching off the system, the clinical improvement persisted for 10 days and the neurohormonal pattern showed high plasma values of beta-endorphin and Met-enkephalin, normal dynorphin B, endothelin-1 and catecholamines, and low nitric oxide. Met-enkephalin levels were further increased (P < 0.01) immediately after switching on the electrical stimulation again. The persistence of high plasma opioid levels after switching off the spinal cord stimulation explains the absence of subjective complaints and suggests an involvement of opioids in the regulation and improvement of the microcirculation.     

Treatment of spinal spasticity by electrical stimulation

We present the results and the methodology of trials using transcutaneous electrical stimulation. The aim of our work was to decrease spasticity in 44 patients with traumatic damage to the spinal cord; 35 non-electrically stimulated spastics were used as controls. Both groups were randomly selected from inpatients in the Paraplegic Department at the Hospital Rehabilitation Centre. This electrical stimulation procedure leads to a long-lasting reduction in spasticity, an increased range of passive and active movements, the facilitation of lost functions, an improvement in breathing, an increase in pulmonary capacity, the reappearance of some neurological reflexes, and a diminution of supersensitivity to skin irritation. Blood pressure and neurogenic bladder functions were restored to normal. In addition to clinical observations, we investigated muscle force and the electromyogram; other measurements used in the trials involved the use of a specially adapted neurological hammer, a pendulum test, spirometry, cystometry, sphincterometry and biochemical estimations.     

Effects of spinal cord stimulation on spasticity and spasms secondary to myelopathy

16 subjects with severe spasms secondary to traumatic and nontraumatic myelopathy underwent epidural spinal cord stimulation. 4 patients had a complete motor and sensory spinal cord lesion. 6 of the subjects with an incomplete spinal cord lesion were ambulatory. All patients had previously undergone extensive trials with medications and physical therapy. All 14 subjects in whom a satisfactory placement of the electrode could be obtained had a reduction in the severity of the spasms. In 6 patients, the spasms were almost abolished. Extremity, trunkal and abdominal spasms were affected. Clonus in the upper extremities was consistently reduced. Marked improvement in bladder and bowel function was observed in each of 2 subjects. In over 1-year follow-up, 5 subjects show persistence of the results, with less stimulation required to maintain the therapeutic effects. No neurological deterioration occurred following the procedure or after long-term spinal stimulation. 1 patient showed after several months of continuous stimulation increased voluntary motor control present only when spinal cord stimulation was activated. Complications included 1 system infection, 1 electrode migration, 1 wire breakage and skin breakdown at a connector site, development of high impedance in 1 electrode and 1 skin breakdown over the lead.     

Prolonged poststimulation inhibition of bladder activity induced by tibial nerve stimulation in cats

Inhibition of bladder activity by tibial nerve stimulation was investigated in α-chloralose-anesthetized cats with an intact spinal cord. Short-duration (3-5 min) tibial nerve stimulation at both low (5 Hz) and high (30 Hz) frequencies applied repeatedly during rhythmic isovolumetric bladder contractions was effective in inhibiting reflex bladder activity. Both frequencies of stimulation were also effective in inducing inhibition that persisted after the termination of the stimulation. The poststimulation inhibitory effect induced by the short-duration stimulation significantly increased bladder capacity to 181.6 ± 24.36% of the control capacity measured before applying the stimulation. Thirty-minute continuous stimulation induced prolonged poststimulation inhibition of bladder activity, which lasted for more than 2 h and significantly increased bladder capacity to 161.1 ± 2.9% of the control capacity. During the poststimulation periods, 5-Hz stimulation applied during the cystometrogram elicited a further increase (~30% on average) in bladder capacity, but 30-Hz stimulation was ineffective. These results in cats support the clinical observation that tibial nerve neuromodulation induces a long-lasting poststimulation inhibitory effect that is useful in treating overactive bladder symptoms.     

Cadence control system for paediatric functional electrical stimulation cycling

Functional electrical stimulation can be used to enable spinal cord injured children to participate in cycling training as part of a fitness programme or exercise testing procedure. Exercise can reduce the impact of secondary health conditions due to the injury. Functional electrical stimulation has shown promising results in adults with a spinal cord injury, but additional considerations are needed to realise the method for the child with spinal cord injury, partly owing to their limited force producing capacity. An electric motor provides a practical means of performing cycling at controlled cadences, exercising for longer durations and can also be used for recreational outdoor cycling. Here, a novel real-time control technique is developed for cadence regulation during cycling. A feedback control structure is developed based on an empirical model derived from separate identification tests and pole placement and then verified in a series of reference-tracking tests. The system produced cadence responses in close agreement with reference values in all cases and demonstrated satisfactory robustness of stability characteristics. This approach moves towards the practical application of the technology as a training tool for paediatric spinal cord injured subjects.     

低频电刺激联合间歇导尿及Motomed运动训练对脊髓损伤致神经源性膀胱患者膀胱内压力及膀胱容量的影响

目的:探讨低频电刺激联合间歇导尿及Motomed运动训练对脊髓损伤致神经源性膀胱患者膀胱内压力及膀胱容量的影响。方法:选取我院2015年12月～2018年2月收治的脊髓损伤致神经源性膀胱患者92例,根据随机数字表法将其分为对照组(n=46)与研究组(n=46)。两组均给予间歇性导尿、盆底肌训练、膀胱功能训练等常规干预,对照组在此基础上采取低频电刺激,研究组于对照组基础上采取Motomed运动训练,两组均干预2个月。比较两组的临床疗效、治疗前及治疗2个月后的排尿情况(日均单次排尿量、日单次最大排尿量、日均排尿次数)、尿动力学情况(最大尿流率、膀胱容量、残余尿量、膀胱内压力)、LUTS(国际下尿路症状评分)及USDS(泌尿症状困扰评分)。结果:治疗后,研究组总有效率(93.48%)显著高于对照组(78.26%)(P0.05);治疗2个月后,两组日均单次排尿量、日单次最大排尿量、日均排尿次数、最大尿流率、膀胱容量、膀胱内压力均较治疗前显著增多,且研究组以上指标均明显高于对照组(P0.05);两组LUTS及USDS分值均较治疗前显著降低,且研究组以上指标均显著低于对照组(P0.05)。结论:间歇导尿联合低频电刺激与Motomed运动训练可有效改善脊髓损伤致神经源性膀胱患者尿动力学状态及排尿情况,增大膀胱容量及膀胱内压力等,缓解下尿路症状及泌尿症状困扰程度,提高治疗效果。     

Alterations in spinal cord Fos protein expression induced by bladder stimulation following cystitis

These studies examined Fos protein expression in spinal cord neurons synaptically activated by stimulation of bladder afferent pathways after cyclophosphamide (CYP)-induced bladder inflammation. In urethan-anesthetized Wistar rats with cystitis, intravesical saline distension significantly (P 相似文献   

Cortical potentials evoked by epidural stimulation of the cervical and thoracic spinal cord in man

Scalp somatosensory evoked potentials (SEPs) were recorded after electrical stimulation of the spinal cord in humans. Stimulating electrodes were placed at different vertebral levels of the epidural space over the midline of the posterior aspect of the spinal cord. The wave form of the response differed according to the level of the stimulating epidural electrodes. Cervical stimulation elicited an SEP very similar to that produced by stimulation of upper extremity nerves, e.g., bilateral median nerve SEP, but with a shorter latency. Epidural stimulation of the lower thoracic cord elicited an SEP similar to that produced by stimulation of lower extremity nerves. The results of upper thoracic stimulation appeared as a mixed upper and lower extremity type of SEP. The overall amplitudes of SEPs elicited by the epidural stimulation were higher than SEPs elicited by peripheral nerve stimulation. In 4 patients the CV along the spinal cord was calculated from the difference in latencies of the cortical responses to stimulation at two different vertebral levels. The CVs were in the range of 45–65 m/sec. The method was shown to be promising for future study of spinal cord dysfunctions.     

Increased expression of spinal cord Fos protein induced by bladder stimulation after spinal cord injury

These studies examined Fos protein expression in spinal cord neurons synaptically activated by stimulation of bladder afferent pathways after spinal cord injury (SCI). In urethan-anesthetized Wistar rats after SCI for 6 wk, intravesical saline distension significantly (P 相似文献   

Stimulation of the spinal cord in the treatment of traumatic injuries of cervical spine

Since 1974, clinical experiments have been conducted at the Rehabilitation Clinic in Konstancin (Poland) on the effects of electrostimulation on the damaged spinal cord. 30 patients with stimulation after injury to the cervical spinal cord are reported. Patients with complete and incomplete cervical cord injury were compared. The patients were treated by surgical decompression with simultaneous implantation of stimulating electrodes in contact with the spinal cord. The control group of patients were operated upon in the same period for similar injuries, but had no stimulators implanted. Neurological improvement was better in the stimulated compared to the nonstimulated patients, both as regards number of neurological improvements as well as quality of neurological function. The comparison also confirmed a favorable effect of spinal cord stimulation on the development of bladder automatism.     

Locomotion induced by spinal cord stimulation in the neonate rat in vitro.

The present studies employed the neonate rat brain stem-spinal cord preparation to determine whether electrical stimulation of the lumbosacral enlargement (LE) of the spinal cord itself can be used to elicit locomotion, and whether or not such stimulation persists in inducing locomotion following midthoracic spinal cord transection or hindlimb deafferentation. Results suggest that (1) stimulation of the dorsal columns or ventral funiculus of the LE is effective in inducing airstepping in the neonatal rat brain stem-spinal cord limb-attached preparation; (2) central disconnection by midthoracic spinal cord transection does not alter LE-stimulation-induced airstepping and may lead to an increase in stepping frequency if suprathreshold stimulation is used; and (3) dorsal root section also leads to an increase in the frequency of suprathreshold LE-stimulation-induced locomotion, but there is not further increase in frequency if a spinal cord transection is performed in addition to dorsal rhizotomy.     

Segmental release of amino acid neurotransmitters from transcranial stimulation

The present study used microdialysis techniques in an intact rabbit model to measure the release of amino acids within the lumbar spinal cord in response to transcranial electrical stimulation. Dialysis samples from the extracellular space were obtained over a stimulation period of 90 minutes and were examined using high pressure liquid chromatography. Neuronal excitation was verified by recerding corticomotor evoked potentials (CMEPs) from the spinal cord. A significant increase in the release of glycine and taurine compared to sham animals was measured after 90 minutes of transcranial stimulation. Glutamate and aspartate release was not significantly elevated. GABA concentrations were consistently low. CMEP components repeatedly showed adequate activation of descending fiber pathways and segmental interneuron pools during dialysis sampling. Since glycine, and to a lesser extent taurine, have been shown to inhibit motor neuron activity and are closely associated with segmental interneuron pools, suprasegmental modulation of motor activity may be, in part, through these inhibitory amino acid neurotransmitters in the rabbit lumbar spinal cord.     

Optimal stimulation of paralyzed muscle after human spinal cord injury.

Muscle properties change profoundly as a result of disuse after spinal cord injury. To study the extent to which these changes can be reversed by electrical stimulation, tibialis anterior muscles in complete spinal cord-injured subjects were stimulated for progressively longer times (15 min, 45 min, 2 h, and 8 h/day) in 6-wk intervals. An index of muscle endurance to repetitive stimulation doubled (from 0.4 to 0.8), contraction and half-relaxation times increased markedly (from 70 to approximately 100 ms), but little or no change was measured in twitch or tetanic tension with increasing amounts of stimulation. The changes observed with 2 h/day of stimulation brought the physiological values close to those for normal (control) subjects. A decrease in the stimulation period produced a reversal of the changes. No effects were observed in the contralateral (unstimulated) muscle at any time, nor was there evidence of decreased numbers of motor units in these subjects secondary to spinal cord injury. Motor unit properties changed in parallel with those of the whole muscle. The occasional spasms occurring in these subjects are not sufficient to maintain normal muscle properties, but these properties can largely be restored by 1-2 h/day of electrical stimulation.     

Spinal cord stimulation revisited: psychological effects

97 patients undergoing spinal cord stimulation (SCS) were studied for a median of 24 days after initiation of treatment. SCS was associated with significant improvement in memory, visuo-spatial integration, activation, cognitive efficiency, attention and overall psychological status. Significant emotional improvement in self-image, anxiety and depression was also confirmed following SCS. Diagnosis did not differentially affect psychological outcome except for relief of anxiety, which was less pronounced in the case of torticollis and multiple sclerosis. The role of spinal cord modulation of behavioral activation and physiological arousal was discussed.     

Botulinum toxin A inhibits ATP release from bladder urothelium after chronic spinal cord injury

The effects of mechanoreceptor stimulation and subsequent ATP release in spinal cord injured and normal bladders was examined to demonstrate if spinal cord injury (SCI) modulates the basal or evoked release of ATP from bladder urothelium and whether intravesical botulinum toxin A (BTX-A) administration inhibits urothelial ATP release, a measure of sensory nerve activation. A Ussing chamber was used to isolate and separately measure resting and mechanoreceptor evoked (e.g. hypoosmotic stimulation) ATP release from urothelial and serosal sides of the bladder. Following spinal cord injury, resting urothelial release of ATP was ninefold higher than that of normal rats. Botulinum toxin A instillation did not significantly affect the resting release of ATP after spinal cord injury. Evoked ATP release following hypoosmotic stimulation was significantly higher in chronic spinal cord injured compared to normal rat bladders. However, botulinum toxin A treatment markedly reduced ATP release in spinal cord injured bladders by 53% suggesting that ATP release by mechanoreceptor stimulation, as opposed to basal release, occurs by exocytotic mechanisms. In contrast, there was no significant difference in basal or evoked ATP release from bladder serosa following spinal cord injury. Moreover, intravesical instillation of botulinum toxin A did not affect ATP release from the serosal side after spinal cord injury, suggesting that its effects were confined to the urothelial side of the bladder preparation. In summary: (1) increased release of ATP from the urothelium of spinal cord injured bladders may contribute to the development of bladder hyperactivity and, (2) mechanoreceptor stimulated vesicular ATP release, as opposed to basal non-vesicular release of ATP, is significantly inhibited in spinal cord injured bladders by intravesical instillation of botulinum toxin A. These results may have important relevance in our understanding of the mechanisms underlying plasticity of bladder afferent pathways following SCI.     

Electrostimulation: a future treatment option for patients with neurogenic urodynamic disorders?

This paper provides an overview of electrical stimulation of the nervous system as a treatment option for urodynamic dysfunction and of some of the recent results in this field. The set-up used in our studies for improved bladder filling in spinal cord injured patients by conditional stimulation of the dorsal penile/clitoral nerve is a highly efficient way to limit neurogenic detrusor overactivity and increase bladder capacity. Ongoing studies suggest that recording of bladder nerve activity is stable over time and may be a technique for chronic monitoring of bladder activity. Bladder emptying exploiting an anodal blocking technique permits bladder emptying without simultaneous urethral-perineal contraction, thus enabling a physiological voiding pattern in one continuous sequence. In patients with supraspinal lesions, deep brain electrical stimulation is established only as treatment for a subgroup of patients suffering from Parkinson's disease. Yet, with improved electrode designs and increased clinical experience and experimental results, probably other groups of patients may be candidates for deep brain stimulation. In our study in pigs there was a trend towards increased bladder capacity and compliance in response to stimulation, which is encouraging as several neurological diseases are accompanied by overactive bladder with reduced capacity.     

Mechanisms of spinal cord electrical stimulation action on autonomic functions

The method of transcutaneous electrical stimulation of the spinal cord (ESSC) has recently begun to be actively used for both experimental studies of human motor functions and the rehabilitation of motor function in patients with spinal cord pathology. The spinal cord is the most important center of the regulation of vital functions, and ESSC affects as spinal locomotor networks as the visceral system too, which should be taken into account for the development of an improved method of rehabilitation and its use in experiments on healthy volunteers. We present a review of studies on the possible mechanisms of ESSC effects on the peripheral and cerebral circulation, cardiovascular, respiratory, excretory, and digestive systems of mammals.     

Effects of chronic electrical stimulation on paralyzed expiratory muscles.

Following spinal cord injury, the expiratory muscles develop significant disuse atrophy characterized by reductions in their weight, fiber cross-sectional area, and force-generating capacity. We determined the extent to which these physiological alterations can be prevented with electrical stimulation. Because a critical function of the expiratory muscles is cough generation, an important goal was the maintenance of maximal force production. In a cat model of spinal cord injury, short periods of high-frequency lower thoracic electrical spinal cord stimulation (SCS) at the T(10) level (50 Hz, 15 min, twice/day, 5 days/wk) were initiated 2 wk following spinalization and continued for a 6-mo period. Airway pressure (P)-generating capacity was determined by SCS. Five acute, spinalized animals served as controls. Compared with controls, initial P fell from 43.9 +/- 1.0 to 41.8 +/- 0.7 cmH(2)O (not significant) in the chronic animals. There were small reductions in the weight of the external oblique, internal oblique, transverses abdominis, internal intercostal, and rectus abdominis muscles (not significant for each). There were no significant changes in the population of fast muscle fibers. Because prior studies (Kowalski KE, Romaniuk JR, DiMarco AF. J Appl Physiol 102: 1422-1428, 2007) have demonstrated significant atrophy following spinalization in this model, these results indicate that expiratory muscle atrophy can be prevented by the application of short periods of daily high-frequency stimulation. Because the frequency of stimulation is similar to the expected pattern of clinical use for cough generation, the daily application of electrical stimulation could potentially serve the dual purpose of maintenance of expiratory muscle function and airway clearance.     

L’erection et l’ejaculation psychogenes: Mythe ou realite? Intérêt de leur recherche chez le blessé médullaire

Erection and ejaculation can be induced by two forms of stimulation. The first is mechanical: touching of the penis, scrotum and anus stimulates the pudendal nerves and a reflex erection appears via the parasympathetic pathway. The second form of sexual stimulation is psychological: erotic pictures and fantasies stimulate the splanchnic nerves and the hypogastric plexus, via the orthosympathetic dorso-lumbar pathway, and induce a psychogenic erection. Spinal injury can destroy a part of these neurological routes and cause impotence and/or failures of ejaculation. We have studied 35 patients reporting a sexual dysfunction after a spinal injury, and have tried to generate an erection and ejaculation first with mechanical stimulation, and then with erotic pictures without mechanical genital stimulation. Tumescence was registered using a plethysmograph and semen was collected in order to study spermatogenesis. The spinal cord was destroyed in 12 patients, but orthosympathetic stimulation produced a psychogenic erection in 15 cases, followed by ejaculation in six cases. This form of stimulation seems to be better than prostaglandin or electrical stimulation.