Peripheral nerve injury frequently leads to neuropathic pain like hyperalgesia, spontaneous pain, mechanical allodynia, thermal allodynia. It is uncertain where the neuropathic pain originates and how it is transmitted to the central nervous system. This study was performed in order to determine which peripheral component may lead to the symptoms of neuropathic pain. Under halothane anesthesia, male Sprague-Dawley rats were subjected to neuropathic surgery by tightly ligating and cutting the tibial and sural nerves and leaving the common peroneal nerve intact. Behavioral tests for mechanical allodynia, thermal allodynia, and spontaneous pain were performed for 2 weeks postoperatively. Subsequently, second operation was performed as follows: in experiment 1, the neuroma was removed; in experiment 2, the dorsal roots of the L4-L6 spinal segments were cut; in experiment 3, the dorsal roots of the L2-L6 spinal segments were cut. Behavioral tests were performed for 4 weeks after the second operation. Following the removal of the neuroma, neuropathic pain remained in experiment 1. After the cutting of the L4-L6 or L2-L6 dorsal roots, neuropathic pain was reduced in experiments 2 and 3. The most remarkable relief was seen after the cutting of the L2-L6 dorsal roots in experiment 3. According to the fact that the sciatic nerve is composed of the L4-L6 spinal nerves and the femoral nerve is composed of the L2-L4 spinal nerves, neuropathic pain is transmitted to the central nervous system via not only the injured nerves but also adjacent intact nerves. These results also suggest that the dorsal root ganglion is very important in the development of neuropathic pain syndrome.
Animal ; Ganglia, Spinal/physiopathology ; Male ; Nervous System Diseases/physiopathology* ; Nervous System Diseases/complications ; Pain/physiopathology* ; Pain/etiology ; Rats ; Rats, Sprague-Dawley ; Spinal Nerve Roots/physiopathology ; Spinal Nerves/physiopathology

Traumatic injury or inflammatory irritation of the peripheral nervous system often leads to persistent pathophysiological pain states. It has been well-documented that, after peripheral nerve injury or inflammation, functional and anatomical alterations sweep over the entire peripheral nervous system including the peripheral nerve endings, the injured or inflamed afferent fibers, the dorsal root ganglion (DRG), and the central afferent terminals in the spinal cord. Among all the changes, ectopic discharge or spontaneous activity of primary sensory neurons is of great clinical interest, as such discharges doubtless contribute to the development of pathological pain states such as neuropathic pain. Two key sources of abnormal spontaneous activity have been identified following peripheral nerve injury: the injured afferent fibers (neuroma) leading to the DRG, and the DRG somata. The purpose of this review is to provide a global account of the abnormal spontaneous activity in various animal models of pain. Particular attention is focused on the consequence of peripheral nerve injury and localized inflammation. Further, mechanisms involved in the generation of spontaneous activity are also reviewed; evidence of spontaneous activity in contributing to abnormal sympathetic sprouting in the axotomized DRG and to the initiation of neuropathic pain based on new findings from our research group are discussed. An improved understanding of the causes of spontaneous activity and the origins of neuropathic pain should facilitate the development of novel strategies for effective treatment of pathological pain.
Animals ; Axotomy ; Ganglia, Spinal ; cytology ; Humans ; Neuralgia ; physiopathology ; Neurons, Afferent ; cytology ; Peripheral Nerve Injuries ; physiopathology ; Spinal Cord ; cytology

The excitability of nociceptive neurons increases in the intact dorsal root ganglion (DRG) after a chronic compression, but the underlying mechanisms are still unclear. The aim of this study was to investigate the ionic mechanisms underlying the hyperexcitability of nociceptive neurons in the compressed ganglion. Chronic compression of DRG (CCD) was produced in adult rats by inserting two rods through the intervertebral foramina to compress the L4 DRG and the ipsilateral L5 DRG. After 5-7 d, DRG somata were dissociated and placed in culture for 12-18 h. In sharp electrode recording model, the lower current threshold and the depolarized membrane potential in the acutely dissociated CCD neurons were detected, indicating that hyperexcitability is intrinsic to the soma. Since voltage-gated K(+) (Kv) channels in the primary sensory neurons are important for the regulation of excitability, we hypothesized that CCD would alter K(+) current properties in the primary sensory neurons. We examined the effects of 4-aminopyridine (4-AP), a specific antagonist of A-type potassium channel, on the excitability of the control DRG neurons. With 4-AP in the external solution, the control DRG neurons depolarized (with discharges in some cells) and their current threshold decreased as the CCD neurons demonstrated, indicating the involvement of decreased A-type potassium current in the hyperexcitability of the injured neurons. Furthermore, the alteration of A-type potassium current in nociceptive neurons in the compressed ganglion was investigated with the whole-cell patch-clamp recording model. CCD significantly decreased A-type potassium current density in nociceptive DRG neurons. These data suggest that a reduction in A-type potassium current contributes, at least in part, to the increase in neuron excitability that may lead to the development of pain and hyperalgesia associated with CCD.
Animals ; Female ; Ganglia, Spinal ; physiopathology ; Hyperalgesia ; etiology ; physiopathology ; Neurons, Afferent ; physiology ; Nociceptors ; physiology ; Pain ; physiopathology ; Potassium Channels ; physiology ; Radiculopathy ; physiopathology ; Rats ; Rats, Sprague-Dawley

No abstract available.
Animals ; Colon/*metabolism ; Constipation/*physiopathology ; Diarrhea/*physiopathology ; Female ; Ganglia, Spinal/*cytology ; Humans ; Irritable Bowel Syndrome/*physiopathology ; Male ; Nociceptors/*physiology ; Receptor, PAR-2/*physiology

The cell body or soma in the dosal root ganglion (DRG) is normally excitable and this excitability can increase and persist after an injury of peripheral sensory neurons. In a rat model of radicular pain, an intraforaminal implantation of a rod that chronically compressed the lumbar DRG ("CCD" model) resulted in neuronal somal hyperexcitability and spontaneous activity that was accompanied by hyperalgesia in the ipsilateral hind paw. By the 5th day after onset of CCD, there was a novel upregulation in neuronal expression of the chemokine, monocyte chemoattractant protein-1 (MCP-1 or CCL2) and also its receptor, CCR2. The neurons developed, in response to topically applied MCP-1, an excitatory response that they normally do not have. CCD also activated non-neuronal cells including, for example, the endothelial cells as evidenced by angiogenesis in the form of an increased number of capillaries in the DRG after 7 days. A working hypothesis is that the CCD induced changes in neurons and non-neuronal cells that may act together to promote the survival of the injured tissue. The release of ligands such as CCL2, in addition to possibly activating nociceptive neurons (maintaining the pain), may also act to preserve injured cells in the face of ischemia and hypoxia, for example, by promoting angiogenesis. Thus, somal hyperexcitability, as often said of inflammation, may represent a double edged sword.
Animals ; Chemokine CCL2 ; metabolism ; Ganglia, Spinal ; cytology ; pathology ; Hyperalgesia ; pathology ; Neuroglia ; cytology ; Nociceptors ; cytology ; Pain ; pathology ; Rats ; Rats, Sprague-Dawley ; Spinal Cord Compression ; physiopathology ; Up-Regulation

OBJECTIVETo study the effect of botulinum toxin type A (BTXA) on spontaneous discharge and sympathetic- sensory coupling in chronically compressed dorsal root ganglion (DRG) neurons in rats.

METHODSIn chronically compressed rat DRG, spontaneous activities of the single fibers from DRG neurons were recorded and their changes observed after BTAX application on the damaged DGR. Sympathetic modulation of the spontaneous discharge from the compressed DRG neurons was observed by electric stimulation of the lumbar sympathetic trunk, and the changes in this effect were evaluated after intravenous BTXA injection in the rats.

RESULTSActive spontaneous discharges were recorded in the injured DRG neurons, and 47 injured DRG neurons responded to Ca2+-free artificial cerebrospinal fluid but not to BTXA treatment. Sixty-four percent of the neurons in the injured DRG responded to sympathetic stimulation, and this response was blocked by intravenously injection of BTXA.

CONCLUSIONBTXA does not affect spontaneous activities of injured DRG neurons, but blocks sympathetic-sensory coupling in these neurons.

Action Potentials ; drug effects ; Animals ; Botulinum Toxins, Type A ; pharmacology ; Ganglia, Spinal ; cytology ; drug effects ; physiopathology ; Nerve Compression Syndromes ; physiopathology ; Neurons ; drug effects ; Rats ; Rats, Sprague-Dawley

Injury or inflammation affecting sensory neurons in the dorsal root ganglia (DRG) causes hyperexcitability of DRG neurons that can lead to spinal central sensitization and neuropathic pain. Recent studies have indicated that, following chronic compression of DRG (CCD) or acute dissociation of DRG (ADD) treatment, both hyperexcitability of neurons in intact DRG and behaviorally expressed hyperalgesia are maintained by activity in cGMP-PKG signaling pathway. Here, we provide evidence supporting the idea that CCD or ADD treatment activates cGMP-PKA signaling pathway in the DRG neurons. The results showed that CCD or ADD results in increase of levels of cGMP concentration and expression of PKG-I mRNA, as well as PKG-I protein in DRG. CCD or ADD treated-DRG neurons become hyperexcitable and exhibit increased responsiveness to the activators of cGMP-PKG pathway, 8-Br-cGMP and Sp-cGMP. Hyperexcitability of the injured neurons is inhibited by cGMP-PKG pathway inhibitors, ODQ and Rp-8-pCPT-cGMPS. In vivo delivery of Rp-8-pCPT-cGMPS into the compressed ganglion within the intervertebral foramen suppresses CCD-induced thermal hyperalgesia. These findings indicate that the in vivo CCD or in vitro ADD treatment can activate the cGMP-PKG signaling pathway, and that continuing activation of cGMP-PKG pathway is required to maintain DRG neuronal hyperexcitability and/or hyperalgesia after these two dissimilar forms of injury-related stress.
Animals ; Cyclic GMP ; analogs & derivatives ; metabolism ; Cyclic GMP-Dependent Protein Kinases ; metabolism ; Ganglia, Spinal ; physiopathology ; Hyperalgesia ; physiopathology ; Rats ; Rats, Sprague-Dawley ; Signal Transduction ; Thionucleotides ; metabolism

Dorsal root ganglion (DRG) neurons have peripheral terminals in skin, muscle, and other peripheral tissues, and central terminals in the spinal cord dorsal horn. Hyperpolarization-activated current (I(h)) of the hyperpolarization-activated, cyclic nucleotide-gated (HCN) channels are present in the DRG. The genes encoding HCN channels have four subtypes named HCN1 to HCN4. HCN channels are permeable to both K(+) and Na(+). They underlie the depolarization that modulates the rhythmic generations of action potentials (APs), contribute to the resting membrane potential, and modify the waveform of propagated synaptic and generator potentials. Neuropathic pain is characterized by spontaneous pain, hyperalgesia and allodynia. After spinal nerve injury, the cell bodies of the primary sensory neurons in segmental DRG become hyperexcitable, characterized for some neurons by the presence of spontaneous firing (or ectopic discharge). In the following, we summarize our observations on the role of HCN channels in DRG neurons in neuropathic pain. 1 HCN subtypes and I(h) in DRG neurons Immunohistochemical staining revealed a subgroup of neurons in the DRG that were stained with rabbit polyclonal antibodies specific for HCN1, 2, 3 and 4. The most prominently expressed HCN subtype was HCN1. HCN1-positive cells in DRG were medium to large in size and doubly labeled with neurofilament-200 (NF-200), and were not labeled with isolectin B4 (IB4), a C fiber marker. In contrast, HCN2, 3 or 4 was expressed in all DRG neurons at a lower level. HCN4 was confined to small neurons. DRG neurons expressed I(h). When membrane was hyperpolarized, the channel was activated, mediating a slowly activated, inward current. I(h) was distributed mainly in large and medium-sized DRG neurons. 2 Changes in expression of HCN in DRG after spinal nerve ligation Western blotting was used to detect the changes in the expression of HCN subtypes in the DRG after spinal nerve ligation. HCN1 mRNA and protein were reduced in the DRG whose spinal nerve had been ligated. HCN1 expression was decreased to the lowest level at day 14 and restored at day 28 after spinal nerve ligation. HCN2 mRNA and medium molecular weight protein was also decreased in spinal-nerve ligated DRG. HCN3 and 4 in the same ganglion remained unchanged as evidenced by immunohistochemical staining, until day 28 when they became significantly decreased. HCN4 mRNA in DRG did not change, and protein expression slightly increased. Interestingly, abundant axonal accumulation of HCN channel protein at the injured sites in chronic constriction injury (CCI) rats. Electron immunomicroscopy showed strong positive immunolabeling on the axolemma of myelinated thick axons. 3 Role of I(h) in neuronal excitability and ectopic discharges after spinal nerve ligation ZD7288, a specific I(h) blocker, inhibited I(h) in a time- and concentration-dependent manner. With patch-clamp recording on acutely isolated DRG neurons, it was found that ZD7288 perfusion resulted in a decrease of both I(h) activity and the activation time constant. ZD7288 decreased the number of repetitive APs and caused an increase in AP rise time, accompanied by a small hyperpolarization of the membrane resting potential. The results demonstrated that I(h) was involved in AP firing, and possessed the physiological functions to facilitate neuronal excitability and ectopic firing. Extracellular electrophysiological recording from dorsal root fibers associated with the spinal nerve-ligated ganglion revealed three different firing patterns of ectopic discharges: tonic or regular, bursting and irregular. The average frequency of ectopic discharges and the proportions of active filaments also changed rapidly, both parameters reaching a peak within 24 h then declining gradually in the following days. It was also found that proportions of three different firing patterns changed dynamically over time. The tonic and bursting types were dominant patterns in the first 24 h, while the irregular became the only pattern at day 14. We found that all three firing patterns (tonic, bursting and irregular) were dose- and time-dependently inhibited by local application of ZD7288 to DRG. The rate of suppression was negatively related to the frequency of firing prior to the application of ZD7288. We also found that, while the tonic firing pattern was gradually transformed to bursting type by application of 100 mumol/L ZD7288, it could be transformed to integer multiples firing by 1000 mumol/L ZD7288. 4 Effects of administration of ZD7288 on mechanical allodynia after spinal nerve ligation or CCI After spinal nerve ligation, i.t. injection of 30 mug ZD7288 significantly increased the 50% paw withdrawal threshold, ipsilateral to the ligated nerve. ZD7288 had no effect if the dose was lower than 15 mug, but resulted in motor deficits if the dose was higher than 60 mug. ZD7288 produced much better effects in the early stage (5 or 14 days after spinal nerve ligation) than that in the late stage (28 days after spinal nerve ligation). In CCI rats, ZD7288 application to the injured sited also significantly suppressed the ectopic discharges from injured nerve fibers with no effect on impulse conduction. Moreover, mechanical allodynia was inhibited. In conclusion, these results demonstrated that I(h) participated in the development and maintenance of peripheral sensitivity associated with neuropathic pain and that it is a potential target for the design of novel analgesics in the future.
Action Potentials ; Animals ; Cyclic Nucleotide-Gated Cation Channels ; metabolism ; Ganglia, Spinal ; physiopathology ; Hyperalgesia ; physiopathology ; Membrane Potentials ; Nerve Fibers ; pathology ; Neuralgia ; physiopathology ; Neurons, Afferent ; pathology ; Rats ; Rats, Sprague-Dawley ; Spinal Nerves ; pathology

OBJECTIVETo screen and identify differentially expressed genes in the dorsal root ganglion (DRG) in early experimental diabetic rats.

METHODSDiabetic model rats were induced by single intraperitoneal injection of streptozotocin (STZ). At the second week after STZ injection, the sensory nerve conduction velocities (SNCV) of sciatic nerve were measured as an indicator of neuropathy. The technique of silver-staining mRNA differential display polymerase chain reaction (DD-PCR) was used to detect the levels of differentially expressed genes in rat DRG. The cDNA fragments that displayed differentially were identified by reverse-hybridization, cloned and sequenced subsequently, and then confirmed by Northern blot.

RESULTSThe SNCV in the diabetic model group [n = 9, (45.25+/-10.38) m/s] reduced obviously compared with the control group [n = 8, (60.10+/-11.92) m/s] (P < 0.05). Seven distinct cDNA clones, one was up-regulated gene and the others were down-regulated ones, were isolated by silver-staining mRNA differential display method and confirmed by Northern blot. According to the results of sequence alignment with GenBank data, majority of the clones had no significant sequence similarity to previously reported genes except only one that showed high homology to 6-pyruvoyl-tetrahydropterin synthase mRNA (accession No. BC059140), which had not been reported to relate to diabetic neuropathy.

CONCLUSIONThese differentially expressed genes in the diabetic DRG may contribute to the pathogenesis of diabetic peripheral neuropathy.

Animals ; Blotting, Northern ; Diabetes Mellitus, Experimental ; genetics ; physiopathology ; Diabetic Neuropathies ; genetics ; physiopathology ; Ganglia, Spinal ; physiopathology ; Gene Expression ; Gene Expression Profiling ; Male ; RNA, Messenger ; analysis ; Rats ; Rats, Sprague-Dawley ; Reverse Transcriptase Polymerase Chain Reaction ; Sciatic Nerve ; physiopathology

Tetanic stimulation of the sciatic nerve (TSS) induces long-term potentiation (LTP) of both C- and A-fiber-evoked field potentials in the spinal dorsal horn and long-lasting mechanical allodynia in rats. Though central mechanisms underlying those phenomena have been well studied, peripheral mechanisms still remain poorly known. Nuclear factor kappa B (NFκB) is an important transcription factor. In the spinal cord, NFκB plays a key role in regulating the expression of numerous pro-inflammation factors and contributes to glial activation in central nervous system, suggesting the involvement of spinal NFκB in central sensitization. To address whether NFκB in the dorsal root ganglion (DRG) participates in peripheral sensitization, we examined NFκB expression in the DRG and the effect of inhibiting NFκB activation on neuropathic pain using behavior test, Western blot analysis and immunohistochemical approaches. The results showed that TSS induced long-lasting mechanical allodynia in bilateral hind paws and increased phospho-NFκB expression in the bilateral DRG. The activated NFκB mainly expressed in nuclei not only of neurons, but also of Schwann cells and satellite glial cells. Moreover, NFκB inhibitor pyrrolidine dithiocarbamate (PDTC) significantly alleviated TSS-induced allodynia. Our results suggest that peripheral NFκB may be involved in TSS-induced neuropathic pain, and provide new evidence for the peripheral mechanism of 'mirror pain'.
Animals ; Ganglia, Spinal ; metabolism ; Hyperalgesia ; physiopathology ; Long-Term Potentiation ; NF-kappa B ; metabolism ; Neuroglia ; metabolism ; Pain Measurement ; Rats ; Rats, Sprague-Dawley ; Schwann Cells ; metabolism ; Sciatic Neuropathy ; physiopathology ; Signal Transduction ; Spinal Cord ; metabolism