The anti-nociceptive effect of bufalin,an active ingredient from toad venom via modulating voltage-gated sodium channels

OBJECTIVE Toad venom(Venenum Bufonis)isalways used for analgesia in China from ancient to modern times,but the effective component of it remains unclear.METHODS In the present study,we investigated the anti-nociceptive effect and the underlying mechanism ofbufalin,an active ingredient fromtoad venom by animal behavior,patch clamp and calcium imaging.RESULTS Bufalin could significantly relieve formalin-induced spontaneous flinching and licking response as well as carrageenan-induced mechanical and thermal hyperalgesia.Using the whole-cel patch-clamp recording,bufalincaused remarkable suppressive effect on the peak currents of Na+channels in dorsal root ganglion neuroblastoma ND7-23 cel line in a U-shaped dependent manner.In addition,bufalinprompted the voltage-dependent activationand caused a negative shift of the fast-state inactivation of Na+channels.However,bufalin produced insignificant effect not onlyon voltage-dependent Kv4.2,Kv4.3 and BK channels,but also on the capsaicin induced Ca2+influx.CONCLUSION The present results indicate bufalin is capable of producing remarkable anti-nociceptive effects whichis probably ascribed to its specific modulation of voltage-gated Na+channels.

Voltage-gated Sodium Channels and Blockers:An Overview and Where Will They Go?

Voltage-gated sodium(Nav)channels are critical players in the generation and propagation of action potentials by triggering membrane depolarization.Mutations in Nav channels are associated with a variety of channelopathies,which makes them relevant targets for pharmaceutical intervention.Sofar,the cryoelectron microscopic structure of the human Nav 1.2,Nav 1.4,and Nav 1.7 has been reported,which sheds light on the molecular basis of functional mechanism of Nav channels and provides a path toward structure-based drug discovery.In this review,we focus on the recent advances in the structure,molecular mechanism and modulation of Nav channels,and state updated sodium channel blockers for the treatment of pathophysiology disorders and briefly discuss where the blockers may be developed in the future.

Expression and Role of Voltage-Gated Sodium Channels in Human Dorsal Root Ganglion Neurons with Special Focus on Nav1.7,Species Differences, and Regulation by Paclitaxel

Voltage-gated sodium channels （Navs） play an important role in human pain sensation. However, the expression and role of Nav subtypes in native human sensory neurons are unclear. To address this issue, we obtained human dorsal root ganglion （hDRG） tissues from healthy donors. PCR analysis of seven DRG-expressed Nav subtypes revealed that the hDRG has higher expression of Navl.7 （,-~ 50% of total Nav expression） and lower expres- sion of Navl.8 （~ 12%）, whereas the mouse DRG has higher expression of Nav 1.8 （- 45%） and lower expression of Navl.7 （- 18%）. To mimic Nav regulation in chronic pain, we treated hDRG neurons in primary cultures with paclitaxel （0.1-1 μmol/L） for 24 h. Paclitaxel increased the Navl.7 but not Navl.8 expression and also increased the transient Na＋ currents and action potential firing frequency in small-diameter （〈50 ~tm） hDRG neurons. Thus, the hDRG provides a translational model in which to study ＂human pain in a dish＂ and test new pain therapeutics.

Pertussis toxin modulation of sodium channels in the central neurons of cyhalothrin-resistant and cyhalothrinsusceptible cotton bollworm, Helicoverpa armigera

Pertussis toxin （FIX） inhibits the activation of the α-subunit of the inhibitory heterotrimeric G-proteins （Cαi/o） and modulates voltage-gated sodium channels, which may be one of the primary targets of pyrethroids. To investigate the potential mechanisms of agricultural pests resistance to pyrethroid insecticides, we examined the modulations by PTX on sodium channels in the central neurons of the 3rd-4th instar larvae of cyhalothrin-resistant （Cy-R） and cyhaiothrin-susceptible （Cy-S） Helicoverpa armigera by the whole-cell patch-clamp technique. The isolated neurons were cultured for 12-16 h in an improved L15 insect culture medium with or without PTX （400 ng/mL）. The results showed that both the Cy-R and Cy-S sodium channels exhibited fast kinetics and tetrodotoxin （TTX） sensitivity. The Cy-R sodium channels exhibited not only altered gating properties, including a 8.88-mV right shift in voltage-dependent activation （V0.5act） and a 6.54-mV right shift in voltage-dependent inactivation （V0.5inact）, but also a reduced peak in sodium channel density （Ⅰdensity） （55.2% of that in Cy-S neurons）. Cy-R sodium channels also showed low excitability, as evidenced by right shift of activation potential （Ⅴacti） by 5-10 mV and peak potential （Ⅴpcak） by 20 mV. FIX exerted significant effects on Cy-S sodium channels, reducing sodium channel density by 70.04%, right shifting V0.5act by 14.41 mV and V0.5inact by 9. 38 mV. It did not cause any significant changes of the parameters mentioned above in the Cy-R sodium channels. The activation time （Tpeak） from latency to peak at peak voltage and the fast inactivation time constant （τinact） in both Cy-S and Cy-R neurons were not affected. The results suggest that cotton bollworm resistant to pyrethroid insecticides involves not only mutations and allosteric alterations of voltage-gated sodium channels, but also might implicate perturbation of PTX-sensitive Gαi/o-COupled signaling Wansduction pathways.

Exploring the obscure profiles of pharmacological binding sites on voltage-gated sodium channels by BmK neurotoxins

Diverse subtypes of voltage-gated sodium channels(VGSCs)have been found throughout tissues of the brain,muscles and the heart.Neurotoxins extracted from the venom of the Asian scorpion Buthus martensi Karsch(BmK)act as sodium channel-specific modulators and have therefore been widely used to study VGSCs.α-type neurotoxins,named BmK I,BmKαIV and BmK abT,bind to receptor site-3 on VGSCs and can strongly prolong the inactivation phase of VGSCs.In contrast,β-type neurotoxins,named BmK AS,BmK AS-1,BmK IT and BmK IT2,occupy receptor site-4 on VGSCs and can suppress peak currents and hyperpolarize the activation kinetics of sodium channels.Accumulating evidence from binding assays of scorpion neurotoxins on VGSCs,however,indicate that pharmacological sensitivity of VGSC subtypes to different modulators is much more complex than that suggested by the simpleα-type and β-type neurotoxin distinction.Exploring the mechanisms of possible dynamic interactions between site 3-/4-specific modulators and region-and/or speciesspecific subtypes of VGSCs would therefore greatly expand our understanding of the physiological and pharmacological properties of diverse VGSCs.In this review,we discuss the pharmacological and structural diversity of VGSCs as revealed by studies exploring the binding properties and cross-competitive binding of site 3-or site 4-specific modulators in VGSC subtypes in synaptosomes from distinct tissues of diverse species.

Phenolic acids isolated from the fungus Schizophyllum commune exert analgesic activity by inhibiting voltage-gated sodium channels

The present study was designed to search for compounds with analgesic activity from the Schizophyllum commune(SC), which is widely consumed as edible and medicinal mushroom world. Thin layer chromatography(TLC), tosilica gel column chromatography, sephadex LH 20, and reverse-phase high performance liquid chromatography(RP-HPLC) were used to isolate and purify compounds from SC. Structural analysis of the isolated compounds was based on nuclear magnetic resonance(NMR). The effects of these compounds on voltage-gated sodium(NaV) channels were evaluated using patch clamp. The analgesic activity of these compounds was tested in two types of mouse pain models induced by noxious chemicals. Five phenolic acids identified from SC extracts in the present study included vanillic acid, m-hydroxybenzoic acid, o-hydroxybenzeneacetic acid, 3-hydroxy-5-methybenzoic acid, and p-hydroxybenzoic acid. They inhibited the activity of both tetrodotoxin-resistant(TTX-r) and tetrodotoxin-sensitive(TTX-s) NaV channels. All the compounds showed low selectivity on NaV channel subtypes. After intraperitoneal injection, three compounds of these compounds exerted analgesic activity in mice. In conclusion, phenolic acids identified in SC demonstrated analgesic activity, facilitating the mechanistic studies of SC in the treatment of neurasthenia.

Distribution and Functional Characteristics of Voltage-Gated Sodium Channels in Immature Cochlear Hair Cells

Voltage-gated sodium channels(VGSCs)are transiently expressed in cochlear hair cells before hearing onset and play an indispensable role in shaping spontaneous activity.In this study,we showed that Na^+currents shaped the spontaneous action potentials in developing mouse inner hair cells(IHCs)by decreasing the time required for the membrane potential to reach the action-potential threshold.In immature IHCs,we identified 9 known VGSC subtypes(Navl.la-l.9ot),among which Navl.7a was the most highly expressed subtype and the main contributor to Na+currents in developing hair cells.Electrophysiological recordings of two cochlea-specific Navi.7 variants(CbmNavl.7a and CbmNavl.7b)revealed a novel loss-of-function mutation(C934R)at the extracellular linker between segments 5 and 6 of domain II.In addition,post-transcriptional modification events,such as alternative splicing and RNA editing,amended the gating properties and kinetic features of CbmNavl.7a(C934).These results provide molecular and functional characteristics of VGSCs in mammalian IHCs and their contributions to spontaneous physiological activity during cochlear maturation.

Research Progress on the Influence of Structural Changes inμ-Conotoxins on Sodium Channel Receptors

The voltage-gated sodium channel(Na v)is widely present in mammals and can generate cell action potentials,which are related to many diseases.Theμ-Conotoxins(μ-CTx)isolated from the venom of cone snails can specifically block the voltage-gated sodium channel;it can be widely used as a necessary probe to distinguish the Na v channel subtypes.In this study,the effects of eightμ-CTx on different Na v channel isoforms were reviewed,and sequence alignment and protein homologous modeling were used to predict their biological activities,and the structure-activity relationship betweenμ-CTx and mutagenesis strategies.

Diabetes-induced changes in cardiac voltage-gated ion channels

Diabetes mellitus affects the heart through various mechanisms such as microvascular defects,metabolic abnormalities,autonomic dysfunction and incompatible immune response.Furthermore,it can also cause functional and structural changes in the myocardium by a disease known as diabetic cardiomyopathy(DCM)in the absence of coronary artery disease.As DCM progresses it causes electrical remodeling of the heart,left ventricular dysfunction and heart failure.Electrophysiological changes in the diabetic heart contribute significantly to the incidence of arrhythmias and sudden cardiac death in diabetes mellitus patients.In recent studies,significant changes in repolarizing K+currents,Na+currents and L-type Ca^(2+)currents along with impaired Ca^(2+ )homeostasis and defective contractile function have been identified in the diabetic heart.In addition,insulin levels and other trophic factors change significantly to maintain the ionic channel expression in diabetic patients.There are many diagnostic tools and management options for DCM,but it is difficult to detect its development and to effectively prevent its progress.In this review,diabetes-associated alterations in voltage-sensitive cardiac ion channels are comprehensively assessed to understand their potential role in the pathophysiology and pathogenesis of DCM.

Ligustrazine inhibits high voltage-gated Ca^(2+) and TTX-resistant Na^+ channels of primary sensory neuron and thermal nociception in the rat:a study on peripheral mechanism

Objective Ligustrazine, also named as tetramethylpyrazine, is a compound purified from Ligusticum chuanxiong hort and has ever been testified to be a calcium antagonist. The present investigation was to determine the antinociceptive effect of ligustrazine and, if any, the peripheral ionic mechanism involved. Methods Paw withdrawal Latency （PWL） to noxious heating was measured in vivo and whole-cell patch recording was performed on small dorsal root ganglion （DRG） neurons. Results Intraplantar injection of ligustrazine （0.5 mg in 25 μl） significantly prolonged the withdrawal latency of ipsilateral hindpaw to noxious heating in the rat. Ligustrazine not only reversibly inhibited high-voltage gated calcium current of dorsal root ganglion （DRG） neuron in dose-dependent manner with IC50 of 1.89 mmol/L, but also decreased tetrodotoxin （TTX） -resistant sodium current in relatively selective and dose-dependent manner with IC50 of 2.49 mmol/L. Conclusion The results suggested that ligustrazine could elevate the threshold of thermal nociception through inhibiting the high-voltage gated calcium current and TTX-resistant sodium current of DRG neuron .in the rat.

Effects of Intrathecally Administerd NaV1.8 Antisense Oligonucleotide on the Expression of Sodium Channel mRNA in Dorsal Root Ganglion

Neuropathic pain has been hypothesized to be the result of aberrant expression and function of sodium channels at the site of injury. To investigate the effects of NaV1.8 antisense oligonucleotide on the expression of sodium channel mRNA in dorsal root ganglion （DRG） neurons in chronic neuropathic pain. 24 Sprague-Dawley rats weighing 200--260 g were anesthetized with the intraperitoneal injection of 300 mg· kg^-1 choral hydrate. The CCI model was made by loose ligation of sciatic nerve trunk by 4--0 chromic gut. The mechanical and thermal pain threshold were measured before operation and 1, 3, 5, 7, 9, 11, 13 days after operation. A PE-10 catheter was implanted in subarachnoid space at lumbar region. On the 7th postoperative day the animals were randomly divided into 4 groups. The drugs were injected intrathecally twice a day for 5 consecutive days in group 2--4. The animals were decapitated 14 days after the surgery. The L4--L6 DRG of the operated side was removed and crushed, and total RNA was extracted with Trizol reagent. The contralateral side was used as control. The change of NaV1.8 sodium channel transcripts was determined by RT-PCR. Pain threshold was significantly lowered after CCI as compared with that in control group and was elevated 3 days after antisense oligonucleotide injection. Sensory neuron specific TTX-R sodium channel NaV1.8 transcript was down-regulated after antisense oligonucleotide injection at the dosage of 45 μg as compared with that in CCI group （P〈0.01）, and it was even greater at the dosage of 90 μg. The intrathecally injected NaV1.8 antisense oligonucleotide can reduce the mechanical allodynia and thermal hyperalgesia partially by downregulating the SNS transcript expression.

Voltage- and Use-dependent Effect of 7-chlor-benzylte-trahydropalmatine on Sodium Currents in Guinea Pig Ventricular Myocytes

The whole-cell patch-clamp technique was employed to obtain information about the voltage-dependence and kinetics of interaction of 7-chlor-benzylte-trahydropalmatine (7-Cl-BTHP) with cardiac sodium channels. 7-Cl-BTHP (30 mol/L) significantly decreased the peak sodium current (from 7. 8±1. 8 nA to 5. 3±1. 4 nA, P<0. 01, n=5), without producing a shift of the current-voltage curve. It shifted the inactivation curves of sodium current to hyperpolarized potentials, and the V(0.5) was shifted from - (82. 5±2. 5) mV to - (95±2.4) mV (P <0. 05, n=4). 7-Cl-BTHP produced a significant use-dependent effect that was proportional to the duration of the voltage step. In addition, 7-Cl-BTHP slowed the recovery of sodium channel from inactivation, which could explain its use-dependent effects on sodium current. The characteristics of 7-Cl-BTHP blockage suggest that this agent binds preferentially to inactivated sodium channels.

Effects of Phorbol-12,13-dibuterate on Sodium Currents and Potassium Currents in Rat Trigeminal Ganglion Neurons

The effects of phorbol-12,13-dibuterate （PDBu） on total sodium current （INa-total）, tetrodotoxin-resistant sodium current （INa-TFXr）, 4-AP-sensitive potassium current （IA） and TEA-sensitive potassium current （IK） in trigeminal ganglion （TG） neurons were investigated. Whole-cell patch clamp techniques were used to record ion currents in cultured TG neurons of rats. Results revealed that 0.5μmol/L PDBu reduced the amplitude of INa-total by （38.3±4.5）% （n=6, P〈0.05）, but neither the G-V curve （control： V0.5 =-17.1±4.3 mV, k=7.4±1.3; PDBu： V0.5=-15.9±5.9 mV, k=5.9±1.4; n=6, P〉0.05） nor the inactivation rate constant （control： 3.6±0.9 ms; PDBu： 3.6±0.8 ms; n=6, P〉0.05） was altered. 0.5 μmol/L PDBu could significantly increase the amplitude of INa-TFXr by （37.2± 3.2）% （n=9, P〈0.05） without affecting the G-V curve （control： V0.5=-14.7±6.0 mV, k=6.9± 1.4; PDBu： V0.5=- 11.1±5.3 mV, k=8.1± 1.5; n=5, P〉0.05 ） or the inactivation rate constant （control： 4.6±0.6 ms; PDBu： 4.2±0.5 ms; n=5, P〉0.05）. 0.5 μmol/L PDBu inhibited IK by （15.6±5.0） % （n=16, P〈0.05）, and V0.5 was significantly altered from - 4.7±1.4 mV to -7.9 ±1.8 mV （n=16, P〈0.05）. IA was not significantly affected by PDBu, 0.5μmol/L PDBu decreased IA by only （0.3±3.2）% （n=5, P〉0.05）. It was concluded that PDBu inhibited INa-total ：.but enhanced INa-TFXr, and inhibited IK without affecting IA. These data suggested that the activation of PKC pathway could exert the actions.

A novel mutation in the sodium channel α1 subunit gene in a child with Dravet syndrome in Turkey

Dravet syndrome is a rare epileptic encephalopathy characterized by frequent seizures beginning in the first year of life and behavioral disorders. Mutations in the sodium channel α1 subunit gene are the main cause of this disease. We report two patients with refractory seizures and psychomotor retardation in whom the final diagnosis was Dravet syndrome with confirmed mutations in the sodium channel α1 subunit gene. The mutation identified in the second patient was a novel frame shift mutation, which resulted from the deletion of five nucleotides in exon 24.

Effect of orphanin FQ and morphine on sodium channel current in somatosensory area of rat cerebral cortex

BACKGROUND： Some experiments have demonstrated that injecting orphanin FQ （OFQ） into lateral ventricle, which can obviously decrease the pain threshold. It is indicated that OFQ is an anti-opiate substance. However, whether OFQ has effects on sensory neuron ion channel in cerebral cortex needs to be further studied. OBJECTIVE： To investigate the effects of OFQ, morphine or their combination on sodium channel current of somatosensory neurons in rat cerebral cortex. DESIGN： Repeated measurement trial. SETTING： Department of Physiology, Harbin Medical University. MATERIALS： Fifty healthy Wistar rats, aged 12 - 16 days, of either gender, were provided by the Experimental Animal Center, Second Hospital Affiliated to Harbin Medical University. OFQ was purchased from Sigma-Aldrich Company, and morphine was provided by the Shenyang First Pharmaceutical Factory. PC2C patch clamp amplifier and LabmasterTLlwere purchased from Yibo Life Science Instrument Co.,Ltd. of Huazhong University of Science and Techgnology. METHODS： This experiment was carried out in the Department of Physiology （provincial laboratory）, Harbin Medical University between January 2005 and May 2006. Cortical neurons were acutely isolated from rats, and prepared into cell suspension following culture. ①Sodium channel current of somatosensory neurons in rat cerebral cortex was recorded before and after administration by whole-cell Patch clamp technique after 50 nmol/L OFQ being added to extracellular fluid. ②The amplitude of sodium channel current of somatosensory neurons in rat cerebral cortex was recorded before and after administration by the same method after 20 μmol/L morphine being added to extracellular fluid, and then the change of sodium channel current was recorded after 50 nmol/L OFQ being added. MAIN OUTCOME MEASURES： The amplitude of sodium channel current of somatosensory neurons in rat cerebral cortex following the administration of OFQ, morphine separately or their combination.. RESULTS： ①The amplitude of sodium channel current of somatosensory neurons in rat cerebral cortex was significantly lower after administration of 50 nmol/L OFQ than before at the clampe of the voltage of -30 mV （P 〈 0.05）.②The amplitude of sodium channel current of somatosensory neurons in rat cerebral cortex was significantly lower after administration of 20 μmol/L morphine than before at the clampe of the voltage of-30 mV （P 〈 0.05）. The sodium channel current recovered to - （2 345.24±174.18） pA after 50 nmol/L OFQ was administrated. There were significant differences in the amplitude of Na^＋ channel current between two interventions （P 〈 0.05）. CONCLUSION： Morphine and OFQ can respectively reduce the amplitude of sodium channel current of somatosensory neurons in rat cerebral cortex, and OFQ can reverse the effect of morphine partly. It is indicated that OFQ can produce antiopioid activity in the central nervous system by influencing sodium channel current.

Cloning of Partial Sodium Channel Gene From Strains of Fenvalerate-Resistant and Susceptible Cotton Aphid(Aphis gossypii Glover)

The strain of fenvalerate-resistant cotton aphids was selected using fenvalerate insecticide in the laboratory, the resistance factor of the strain was 199.54. Three degenerate primers were designed and used to perform PCR amplification. A cDNA encoding partial sodium channel gene was cloned from the fenvalerate-resistant and -susceptible strains. There were two nucleotide acid differences between fenvalerate-resistant strain and -susceptible strain, resulting in an amino acid mutation, Met→Leu. It is predicted that the mutation is related to the cotton aphid resistance to fenvalerate.

Electrophysiology of Sodium Receptors in Taste Cells

Sodium intake is important to maintain proper osmolarity and volume of extracellular fluid in vertebrates. The ability to find sources of sodium ions for managing electrolyte homeostasis relies on the activity of the taste system to sense salt. Several studies have been performed to understand the mechanisms underlying Na+ reception in taste cells, the peripheral detectors for food chemicals. It is now generally accepted that Na+ interacts with specific ion channels in taste cell membrane, called sodium receptors. As ion channels, these proteins mediate transmembrane ion fluxes (that is, electrical currents) during their operation. Thus, a lot of information on the functional properties of sodium receptors has been obtained by using electrophysiological techniques. Here, I review our current knowledge on the biophysical and physiological features of these receptors obtained by applying the patch-clamp recording techniques to single taste cells.

Therapeutic efficacy of voltage‑gated sodium channel inhibitors in epilepsy

Epilepsy is a neurological disease characterized by excessive and abnormal hyper-synchrony of electrical discharges of the brain and a predisposition to generate epileptic seizures resulting in a broad spectrum of neurobiological insults,imposing psychological,cognitive,social and also economic burdens to the sufferer.Voltage-gated sodium channels(VGSCs)are essential for the generation and propagation of action potentials throughout the central nervous system.Dysfunction of these channels has been implicated in the pathogenesis of epilepsy.VGSC inhibitors have been demonstrated to act as anticonvulsants to suppress the abnormal neuronal firing underlying epileptic seizures,and are used for the management and treatment of both genetic-idiopathic and acquired epilepsies.We discuss the forms of idiopathic and acquired epilepsies caused by VGSC mutations and the therapeutic efficacy of VGSC blockers in idiopathic,acquired and pharmacoresistant forms of epilepsy in this review.We conclude that there is a need for better alternative therapies that can be used alone or in combination with VGSC inhibitors in the management of epilepsies.The current anti-seizure medications(ASMs)especially for pharmacoresistant epilepsies and some other types of epilepsy have not yielded expected therapeutic efficacy partly because they do not show subtype-selectivity in blocking sodium channels while also bringing side effects.Therefore,there is a need to develop novel drug cocktails with enhanced selectivity for specific VGSC isoforms,to achieve better treatment of pharmacoresistant epilepsies and other types of epileptic seizures.

Epithelial Sodium and Chloride Channels and Asthma

Objective：To focus on the asthmatic pathogenesis and clinical manifestations related to epithelial sodium channel （ENaC）/chlorine ion channel.Data Sources：The data analyzed in this review were the English articles from 1980 to 2015 from journal databases,primarily PubMed and Google Scholar.The terms used in the literature search were：（1） ENaCs;cystic fibrosis （CF） transmembrane conductance regulator （CFTR）;asthma/asthmatic,（2） ENaC/sodium salt;CF;asthma/asthmatic,（3） CFTR/chlorine ion channels;asthma/asthmatic,（4） ENaC/sodium channel/scnn1a/scnn1b/scnn1g/scnn1d/amiloride-sensitive/amiloride-inhibtable sodium channels/sodium salt;asthma/asthmatic,lung/pulmonary/respiratory/tracheal/alveolar,and （5） CFTR;CF;asthma/asthmatic （ti）.Study Selection：These studies included randomized controlled trials or studies covering asthma pathogenesis and clinical manifestations related to ENaC/chlorine ion channels within the last 25 years （from 1990 to 2015）.The data involving chronic obstructive pulmonary disease and CF obtained from individual studies were also reviewed by the authors.Results：Airway surface liquid dehydration can cause airway inflammation and obstruction.ENaC and CFTR are closely related to the airway mucociliary clearance.Ion transporters may play a critical role in pathogenesis of asthmatic exacerbations.Conclusions：Ion channels have been the center of many studies aiming to understand asthmatic pathophysiological mechanisms or to identify therapeutic targets for better control of the disease.

Na_v1.7 protein and mRNA expression in the dorsal root ganglia of rats with chronic neuropathic pain

Neuropathic pain was produced by chronic constriction injury of the sciatic nerve in rats. Behaviora tests showed that the thresholds for thermal and mechanical hyperalgesia were significantly reduced in neuropathic pain rats 3 28 days following model induction. The results of immunohistochemistry, western blot assays and reverse transcription-PCR showed that Nay1.7 protein and mRNA expression was significantly increased in the injured dorsal root ganglia. These findings indicated that Nay1.7 might play an important role in the model of chronic neuropathic pain