实验旨在探讨钙/钙调蛋白依赖性蛋白激酶Ⅱ（calcium/calmodulin-dependentprotein kinase Ⅱ，CaMKII）在脊髓背C-纤维诱发电位长时程增强（long-term potentiation，LTP）的诱导和维持中的作用。用western blot技术分别检测LTP形成30min和3h脊髓背角（L4-L6）CaMKⅡ的含量及其磷酸化水平。同时观察脊髓局部给予CaMKⅡ选择性抑制剂KN-93后对脊髓背角LTP和CaMKⅡ磷酸化的影响。观察结果如下：（1）诱导LTP后30min，CaMKⅡ的磷酸化水平明显高于对照组，而CaMKⅡ的总量无变化；诱导LTP后3h CaMKⅡ的磷酸化水平进一步升高，而且CaMKⅡ的总量也叫显增力（n=4）；（2）强直刺激前30min于脊髓局部给予CaMKⅡ的特异性抑制剂KN-93（100μmol/L)，可阻断LTP的诱导，同时明显抑制CaMKⅡ的磷酸化水平；（3）诱导LTP后30min给予KN-93，可显著抑制LTP的维持，同时CaMKII的磷酸化水平与未用药组相比也明显降低（n=3）；（4）LTP3h后给予KN-93，LTP的幅值不受影响，磷酸化的CaMKⅡ的含量与用药前相比也无差别（n=3）。根据卜述实验结果可以认为，CaMKⅡ的激活参与脊髓背角C-纤维诱发电化LTP的诱导和早期维持过程。

Long-term potentiation (LTP) of C-fiber-evoked field potentials in spinal dorsal horn may be relevant to hyperalgesia, an increased response to noxious stimulation. The mechanism underlying this form of synaptic plasticity is, however, still unclear. Considerable evidence has shown that calcium/calmodulin-dependent protein kinase II (CaMKII), protein kinase A (PKA), and protein kinase C (PKC) are important for LTP in hippocampus. In this study, the roles of these three protein kinases in the induction and maintenance of LTP of C-fiber-evoked field potentials were evaluated by application of specific inhibitors of CaMKII (KN-93 and AIP), PKA (Rp-CPT-cAMPS), and PKC (chelerythrine and Go6983) at the recording segments before and after LTP induction in urethaneanesthetized Sprague-Dawley rats. We found both KN-93 and AIP, when applied at 30min prior to tetanic stimulation, completely blocked LTP induction. At 30min after LTP induction, KN-93 and AIP reversed LTP completely, and at 60min after LTP induction, they depressed spinal LTP in most rats tested. Three hours after LTP induction, however, KN-93 or AIP did not affect the spinal LTP. Rp-CPT-cAMPS, chelerythrine, and Go 6983 blocked the spinal LTP when applied at 30min before tetanic stimulation and reversed LTP completely at 15min after LTP induction. In contrast, at 30min after LTP induction, the drugs never affected the spinal LTP. These results suggest that activation of CaMKII, PKA, and PKC may be crucial for the induction and the early-phase but not for the late-phase maintenance of the spinal LTP.

Transection of the L5 spinal nerve in rats results in allodynia- and hyperalgesia-like behavior to mechanical stimulation which are thought to be mediated by ectopic activity arising in lesioned afferent neurons mainly in the dorsal root ganglion (DRG). It has been suggested that the neuropathic pain behavior is dependent on the sympathetic nervous system. In rats 3

After mechanical injury of a peripheral nerve some axotomized afferent neurons develop spontaneous activity, which is thought to trigger abnormal pain behavior in rats and neuropathic pain in humans. Here, we analysed the ectopic activity in axotomized afferent fibers recorded from the L5 dorsal root in different time periods after L5 spinal nerve lesion and the effects of sympathectomy on it. The following results were obtained: (1) Up to 6 hours after spinal nerve transection there was almost no spontaneous activity in axotomized afferents, except short-lasting injury discharges at the time of transection; (2) Three to 8 days following spinal nerve lesion, the rate of spontaneous activity was 7:3

Use-dependent long-term potentiation of synaptic strength (LTP) is an intensively studied model for learning and memory in vertebrates. Induction of LTP critically depends on the stimulation parameters of presynaptic fibres with synchronous high-frequency bursts being most effective at many central synapses. It is, however, not known whether naturally occurring discharge patterns may induce LTP and whether LTP has any biological function in sensory systems. Here we have investigated the LTP of excitatory synaptic transmission between primary afferent C-fibres, many of which are nociceptors, and neurons in rat superficial spinal dorsal horn. LTP that lasted for 4-6 h could not only be induced by electrical stimulation of sural nerve but also by natural stimulation of heat-, mechano- or chemosensitive nociceptors in the skin or by acute nerve injury. Maintenance of LTP was not affected when afferent nerves were cut 1h or 5min after noxious skin stimulation, indicating that an ongoing afferent barrage is not required. Natural noxious stimuli induced LTP in animals which were spinalized but were ineffective in intact animals. Thus, induction of LTP is suppressed by tonically active supraspinal descending systems. We conclude that the natural non-synchronized discharge patterns that are evoked by noxious stimulation may induce LTP and that this new form of LTP may be an underlying mechanism of afferent induced hyperalgesia.