Department of Anesthesiology and Critical Care Medicine, Johns Hopkins University, School of Medicine, Baltimore, Maryland, USA.
Anesthesiology. 2010 Dec;113(6):1392-405. doi: 10.1097/ALN.0b013e3181fcd95c.
The sites of action and cellular mechanisms by which spinal cord stimulation reduces neuropathic pain remain unclear.
We examined the effect of bipolar electrical-conditioning stimulation (50 Hz, 0.2 ms, 5 min) of the dorsal column and lumbar dorsal roots on the response properties of spinal wide dynamic range (WDR) neurons in rats after L5 spinal nerve injury. The conditioning stimulation intensity was set at the lowest current that evoked a peak antidromic sciatic Aα/β-compound action potential without inducing an Aδ- or C-compound action potential.
Within 15 min of the dorsal column or root conditioning stimulation, the spontaneous activity rate of WDR neurons was significantly reduced in nerve-injured rats. Conditioning stimulation also significantly attenuated WDR neuronal responses to mechanical stimuli in nerve-injured rats and inhibited the C-component of the neuronal response to graded intracutaneous electrical stimuli applied to the receptive field in nerve-injured and sham-operated rats. It is noteworthy that dorsal column stimulation blocked windup of WDR neuronal response to repetitive intracutaneous electrical stimulation (0.5 Hz) in nerve-injured and sham-operated rats, whereas dorsal root stimulation inhibited windup only in sham-operated rats. Therefore, stimulation of putative spinal substrates at A-fiber intensities with parameters similar to those used by patients with spinal cord stimulators attenuated established WDR neuronal hyperexcitability in the neuropathic condition and counteracted activity-dependent increase in neuronal excitability (i.e., windup).
These results suggest a potential cellular mechanism underlying spinal cord stimulation-induced pain relief. This in vivo model allows the neurophysiologic basis for spinal cord stimulation-induced analgesia to be studied.
脊髓刺激减轻神经性疼痛的作用部位和细胞机制仍不清楚。
我们检查了双极电条件刺激(50 Hz,0.2 ms,5 min)对 L5 脊神经损伤后大鼠背柱和腰脊神经根的宽动态范围(WDR)神经元反应特性的影响。条件刺激强度设定为诱发无诱发 Aδ 或 C 复合动作电位的最大逆行坐骨 Aα/β 复合动作电位的最低电流。
在背柱或根条件刺激后 15 分钟内,神经损伤大鼠的 WDR 神经元自发放电率明显降低。条件刺激还显著减弱了神经损伤大鼠 WDR 神经元对机械刺激的反应,并抑制了应用于神经损伤和假手术大鼠感受野的分级皮内电刺激引起的神经元反应的 C 成分。值得注意的是,背柱刺激阻断了 WDR 神经元对重复皮内电刺激(0.5 Hz)的反应的缠结,而背根刺激仅在假手术大鼠中抑制了缠结。因此,用类似于脊髓刺激器患者使用的参数刺激假定的脊髓底物(A 纤维强度),可减轻神经性条件下已建立的 WDR 神经元过度兴奋,并抵消与活动相关的神经元兴奋性增加(即缠结)。
这些结果表明脊髓刺激引起的疼痛缓解的潜在细胞机制。这种体内模型允许研究脊髓刺激诱导镇痛的神经生理基础。
