Chaplan Sandra R, Guo Hong-Qing, Lee Doo Hyun, Luo Lin, Liu Changlu, Kuei Chester, Velumian Alexander A, Butler Matthew P, Brown Sean M, Dubin Adrienne E
Neuroscience, Johnson & Johnson Pharmaceutical Research and Development, San Diego, California 92121, USA.
J Neurosci. 2003 Feb 15;23(4):1169-78. doi: 10.1523/JNEUROSCI.23-04-01169.2003.
Neuropathic pain is a common and often incapacitating clinical problem for which little useful therapy is presently available. Painful peripheral neuropathies can have many etiologies, among which are trauma, viral infections, exposure to radiation or chemotherapy, and metabolic or autoimmune diseases. Sufferers generally experience both pain at rest and exaggerated, painful sensitivity to light touch. Spontaneous firing of injured nerves is believed to play a critical role in the induction and maintenance of neuropathic pain syndromes. Using a well characterized nerve ligation model in the rat, we demonstrate that hyperpolarization-activated, cyclic nucleotide-modulated (HCN) "pacemaker" channels play a previously unrecognized role in both touch-related pain and spontaneous neuronal discharge originating in the damaged dorsal root ganglion. HCN channels, particularly HCN1, are abundantly expressed in rat primary afferent somata. Nerve injury markedly increases pacemaker currents in large-diameter dorsal root ganglion neurons and results in pacemaker-driven spontaneous action potentials in the ligated nerve. Pharmacological blockade of HCN activity using the specific inhibitor ZD7288 reverses abnormal hypersensitivity to light touch and decreases the firing frequency of ectopic discharges originating in Abeta and Adelta fibers by 90 and 40%, respectively, without conduction blockade. These findings suggest novel insights into the molecular basis of pain and the possibility of new, specific, effective pharmacological therapies.
神经性疼痛是一个常见且往往使人丧失能力的临床问题,目前几乎没有有效的治疗方法。疼痛性外周神经病变可有多种病因,其中包括创伤、病毒感染、接触辐射或化疗以及代谢或自身免疫性疾病。患者通常在静息时感到疼痛,并且对轻触也会产生过度的疼痛敏感性。受损神经的自发放电被认为在神经性疼痛综合征的诱发和维持中起关键作用。利用大鼠中一个特征明确的神经结扎模型,我们证明超极化激活的、环核苷酸调节的(HCN)“起搏器”通道在源自受损背根神经节的触觉相关疼痛和神经元自发放电中发挥了以前未被认识到的作用。HCN通道,尤其是HCN1,在大鼠初级传入神经元胞体中大量表达。神经损伤显著增加了大直径背根神经节神经元中的起搏电流,并导致结扎神经中由起搏器驱动的自发放电动作电位。使用特异性抑制剂ZD7288对HCN活性进行药理学阻断可逆转对轻触的异常超敏反应,并分别使源自Aβ和Aδ纤维的异位放电频率降低90%和40%,且无传导阻滞。这些发现为疼痛的分子基础提供了新的见解,并提示了新的、特异性的、有效药理学治疗方法的可能性。