Temporal lobe epilepsy animal model established by stereotaxic microinjection of kainic acid

BACKGROUND： Kainic acid can be used to induce a model of epilepsy by systemic injection, such as intraperitoneal or subcutaneous injection. Individual rats have different responses to kainic acid, therefore high doses of drug are required and the success rate of model induction is low. It is necessary to develop an improved method to establish a temporal lobe epilepsy （TLE） animal model. OBJECTIVE： To explore an economic, stable and efficient method of establishing a TLE animal model. DESIGN, TIME AND SETTING： A completely randomized, controlled study. The experiments were performed in the Cellular Function Laboratory of the Physiology Department, Anhui Medical University from March to July 2007. MATERIALS： Twenty adult male Wistar rats, weighing 230-260 g, were provided by the Experimental Animal Centre of Nanjing Medical University. Kainic acid was purchased from Sigma in USA. Type SN-2 stereotaxic apparatus was made by Narishge in Japan. METHODS： Wistar rats were randomly divided into a kainic acid （KA） group （n = 12） and a normal saline （NS） group （n = 8）. For intrahippocampal microinjection, a burr hole was drilled in the skull at the following stereotaxic coordinates： anteroposterior （AP） 4.1 mm caudal to bregma; lateral （ML） 4.2 mm right lateral to the midline. Rats in the KA group were injected with 2.5 μL KA （0.4 g/L） into the center of the CA3 region, while in the NS group the same volume of NS was injected into the same site. MAIN OUTCOME MEASURES： Both groups were monitored under a video capture system for 12 weeks to record spontaneous seizures. Intracranial eletroencepholograph （IEEG） recordings in vivo were performed after the behavioral observations. After the IEEG recordings, hippocampi were processed into coronal sections. Nissl and Timm stainings were then performed to observe and confirm pathology. RESULTS： Twenty rats were involved in the final analysis. Behavioral observations： the eadiest spontaneous onset of epilepsy appeared 2 weeks after injection of KA. Eight rats had spontaneous onset of epilepsy 3-12 weeks after treatment. None of rats in the NS group had spontaneous onset of epilepsy. IEEG recordings： Epileptic-form waves, such as sharp waves and spike waves, were calculated by artificial analysis The number of epileptic-form waves in the KA group increased significantly compared to those of the NS group （P 〈 0.01）. Morphology results： In the KA group, Nissl staining and Timm staining revealed typical pathology in the hippocampal temporosphenoid lobe. In the NS group, no pathology was observed. CONCLUSION： Intrahippocampal microinjection of KA is a reliable method to establish a temporal lobe epilepsy animal model, requiring low doses of kainic acid and giving a high rate of success.

Gastrodin blocks neural stem cell differentiation into glial cells mediated by kainic acid

Kainic acid can simulate excitatory amino acids in vitro. Neural stem cells, isolated from newborn Wistar rats, were cultured in vitro and exposed to 100 4 000 #M kainic acid for 7 days to induce neuronal cell differentiation, causing the number of astrocytes to be significantly increased. Treatment with a combination of 0.5 mg/L gastrodin and kainic acid also caused the number of differentiated neurons to be significantly increased compared with treatment with kainic acid alone Experimental findings suggest that gastrodin reduces the excitability of kainic acid and induces neural stem cell differentiation into neurons.

Effects of rutin on oxidative stress in mice with kainic acid-induced seizure

Flavonoids are present in foods such as fruits and vegetables. Several studies have demonstrated a relationship between the consumption of flavonoid-rich foods and prevention of human disease, including neurodegenerative disorders. We assessed the effect of rutin （quercetin-3-O-rutinoside） on oxidative stress in kainic acid （KA）-induced seizure. METHODS： Thirty-six BALB/c mice were randomly divided into three groups. In the control group, saline （intra-peritoneal, i.p.） was administered for 7 d, and on the last day, KA （10 mg/kg, i.p.） was injected 30 min after administration of saline. In rutin groups, mice were pretreated with rutin （100 and 200 mg/kg, i.p.） for 7 d, and on the last day, KA （10 mg/kg, i.p.） was injected 30 min after administration of rutin. Subsequently, behavioural changes were observed in mice. Lipid peroxidation and oxidative stress were measured respectively in the early and late phases after KA-induced seizures. RESULTS： Seizure scores in the rutin groups were significantly lower than those in the control group （P 〈 0.01）. Furthermore, rutin dose-dependently inhibited the number of wet-dog shakes （WDS） （P 〈 0.05）. Malondialdehyde level in the hippocampus of the rutin groups was significantly lower than that in the hippocampus of the control group on days 1 and 21 after KA administration. In the rutin groups, the thiol levels observed on day 1 after KA administration were higher than that in the control group （P 〈 0.01）. CONCLUSION： These results indicate that rutin has potential anticonvulsant and antioxidative activities against oxidative stress in KA-induced seizure in mice.

Protective effects of gastrodine on dendritic spines in kainic acid-injured neurons

EphB2 affects neuronal cells by altering the dendritic spines. The present study analyzed the neu-roprotective effects of gastrodine by measuring EphB2 expression in rat neural cells cultured in vitro and injured by kainic acid. Gastrodine （12.5, 25, and 50 mg/L） improved morphology in kainic acid-injured neurons, reduced lactate dehydrogenase leakage, decreased neuronal apoptosis, and increased EphB2 expression in neuronal cells. A moderate dose of 25 mg/L gastrodine resulted in the most significant effects. These results suggested that gastrodine suppressed the neurotoxic effects of excitatory amino acids and provided neuroprotection by remodeling neuronal dendritic spines.

N-methyl-D-aspartate receptor subunit 1 protein expression in the hippocampus and temporal cortex of kainic acid-induced epilepsy rats

BACKGROUND： The N-methyl-D-aspartate receptor subunit 1 （NMDAR1） contributes to the incidence of epilepsy. However, the relationship between epilepsy-induced brain injury and NMDAR1 remains poorly understood. OBJECTIVE： To investigate changes in NMDAR1 protein expression in the hippocampus and temporal cortex of kainic acid-induced epilepsy rats. DESIGN, TIME AND SETFING： A randomized, controlled, animal experiment was performed at the Department of Physiology and Department of Pathology, Basic Medical College of Jilin University from March 2002 to March 2003. MATERIALS： Rabbit anti-NMDAR1 antibody was purchased from Wuhan Boster Biological Technology, China. METHODS： A total of 80 healthy, male, Wistar rats, aged 22 weeks, were randomly assigned to sham-surgery （n = 10） and model （n = 70） groups. Epilepsy models were established by injecting kainic acid （1μL） into the right amygdala, and rats were sacrificed at 2, 6, 24, 72 hours, and 7, 15, 30 days after surgery, with 10 animals at each time point. The rats in the sham-surgery group were injected with 1μL phosphate buffered saline into the right amygdala. MAIN OUTCOME MEASURES： NMDAR1 protein expression in the hippocampus and temporal cortex at 2, 6, 24, 72 hours and 7, 15, 30 days after epilepsy was detected using immunohistochemistry and flow cytometry analysis. RESULTS： In the sham-surgery group, a few NMDARl-positive cells were distributed in the hippocampus and temporal cortex. In the model group, NMDARl-positive cells were increased in the hippocampus and temporal cortex at 2 hours following kainic acid-induced epilepsy. They were significantly increased at 6 hours, and slightly decreased at 7 days （CA3 region and temporal cortex）, but remained greater than the sham-surgery group. This continued until day 30 （P 〈 0.01 ）. In addition, there were more NMDAR1 positive cells in the hippocampal CA3 and dentate gyrus than the temporal cortex （P 〈 0.01）. CONCLUSION： In epilepsy model rats, NMDAR1 protein expression was upregulated in the hippocampus and temporal cortex, and in particular in the hippocampal CA3 and dentate gyrus. NMDAR1 may participate in epilepsy and the excitation process of the epileptic brain.

Synthesis of both epimeric triacid ananlogs of kainic acid

A practical and cheap method for synthesis of C-4 carboxylic acid substituted kainic acid analogue 5 and its epimer 6 from trans-4-hydroxyproline is described. Using this method, more interesting intermediates and analogues could be obtained easily.

Mitochondrial and nuclear damages and caspase-3 expression in the hippicampal CA3 region of rats with kainic acid induced statuse pilepticus

BACKGROUND: Some scholars believed that the neuronal injury after status epilepticus is apoptosis, the main evidence is the changes of expressions of various apoptosis related genes, such as immediate-early gene, p53 gene and genes of bcl-2 family, etc. But there is still no ultrastructural evidence for apoptosis. OBJECTIVE: To observe the ultrastructural damages of mitochondrion and nucleus and the changes of caspase expression in neurons of hippocampal CA3 region in rats with status epilepticus induced by kainic acid. DESIGN: A randomized controlled study. SETTING: Department of Anesthesiology and Department of Neurology, Qilu Hospital of Shandong University. MATERIALS: Seventy-five adult male Wistar rats of 250-300 g, clean degree, were provided by the experimental animal center of Shandong University. Kainic acid was purchased from Sigma Company (USA); rabbit anti-rat polyclonal antibody caspase-3 from Santa Cruz Company (USA). METHODS: The experiments were carried out in the Department of Anesthesiology, Qilu Hospital of Shandong University from October 2005 to February 2006. ① The 75 rats were randomly divided into experimental group (n =45) and control group (n =30). ② Model establishment, convulsion grading and the judging standards for status epilepticus: Rats in the experimental group were given intraperitoneal injection of kainic acid (10 mg/kg), and those in the control group were injected with saline of the same volume. The time of seizure was recorded and their behavioral manifestations were observed, and the seizure was terminated by intraperitoneal injection of diazepam (10 mg/kg). ③ Observation under electron microscope: At 3, 12 and 24 hours after status epilepticus respectively, bilateral hippocampal tissues were taken out, semithin sections of about 75 nm were prepared after fixation, dehydration and embedding, and then observed under H-800 transmission electron microscope. ④ Immunohistochemical detection: Bilateral hippocampi were removed at 3, 12 and 24 hours after status epilepticus respectively, the fixation, dehydration, transparence, wax immersion and embedding were performed, then serial sections of CA3 region were immunohistochemically determined by the SABC method. Leica QWinV3 image analytical software was applied, then the average number and average gray value of positive cells were calculated. MAIN OUTCOME MEASURES: Results of observation under electron microscope, that of immunohistochemical staining of neurons in hippocampal CA3 region; Comparison of number of caspase-3 positive cells and gray value. RESULTS: All the 75 Wistar rats were involved in the analysis of results. ① Results of observation under electron microscope: At 3 hours after status epilepticus, swelling crista and membranous disintegration were observed under electron microscope. At 24 hours, obvious nuclear changes occurred, and manifested as the side-aggegation of chromatins. ② Results of immunohistochemical detection: In the experimental group, the number of caspase-3 positive cells at 3 hours after status epilepticus had no obvious difference as compared with that in the control group (P > 0.05); At 12 hours, the number and gray value of caspase-3 positive cells in the experimental group were higher than those in the control group (10.49±0.68 vs. 5.33±0.43; 45.57±2.27 vs. 19.79±0.33, P < 0.05), the same results were also observed at 24 hours (37.36±0.57 vs. 5.12±0.47; 115.24±1.22 vs. 18.73±0.42, P < 0.01). CONCLUSION: In the rat models of status epilepticus induced by kainic acid, mitochondrial damage was earlier than the increase of caspase-3 expression and nuclear changes, which suggested that mitochondrion was the key link for the neuronal death after status epilepticus.

Overexpression of γ-aminobutyric acid transporter subtype I leads to susceptibility to Kainic acid-induced seizure in transgenic mice

γ-aminobutyric acid (GABA) is the principal inhibitory neurotransmitter, and the GABAergic synaptic transmission is normally terminated by the rapid uptake through GABA transporters. With transgenic mice ubiquitously overexpressing GABA transporter subtype I (GAT1), the present study explored the pathophysiological role of GAT1 in epileptogenesis. Though displaying no spontaneous seizure activity, these mice exhibit altered electroencephalographic patterns and increased susceptibility to seizure induced by kainic acid. In addition, the GABAA receptor and glutamate transporters are up-regulated in transgenic mice, which perhaps reflects a compensatory or corrective change to the elevated level of GAT1. These preliminary findings support the hypothesis that excitatory and inhibitory neurotransmission, and seizure susceptibility can be altered by neurotransmitter transporters.

A Study of Epileptiform Hippocampal Unit Activity Induced by Intracerebroventricular Injection of Kainic Acid in Rats

Hippocampal EEG and unit activities were recorded after seizures were initiated withintracerebroventricular injection of kainic acid (KA) in rats. Three kinds of hippocampal unit re-sponses to KA were found:1. Positive units: These units were characterized by high frequency burst firing temporally coincidentwith each hippocampal EEG spike.2. Negative units: These units showed a cessation of firing during each EEG paroxysm.3. Indifferent units: These units showed no evident chanses coincident with EEG paroxysms.Most positive units were hippocampal complex spike cells which correspond histologically tohippocampal pyramidal cells, and most complex spike cells fired in positive bursts after KA treat-ment. In the early period after KA injection, the positive units were concentrated in CA3 area. It was suggested that the activities of positive units may be considered as the typical epileptiformhippocampal unit activity induced by KA, and the firing features of negative units ma be the resultof the influence of hippocampal inhibitory interneurons or the result of excessive cellulardepolarization, and that hippocampal pyramidal cells were more sensitive to the epileptogenic ef-fect of KA than hippocampal intemeurons, and some pyramidal cells in CA3, in particular,may serve as "epileptic pacemaker neurons " in KA-induced epileptogenesis.

Dynamic changes of mG1uR1 mRNA expression in rat hippocampus during seizures induced by kainic acid

Objective: To investigate temporospatial changes of mG1uR1 mRNA expression in rat hippocampus during seizures induced by kainic acid. Methods: Using in situ hybridization with Dig-labeled cDNA probes to examine mG1uR1 mRNA expression. The relative number of hybridization signal was quantified by image analysis systems. EEG and behavior changes of the rats were simultaneously observed. Results: All rats of the KA-injected group exhibited severe limbic convulsions. The EEG recordings also showed electrical seizure activities. The mG1uR1 mRNA expression began to increase at 1 h after KA injection and reached its maximal level at 4 - 8 h, and then it began to decrease gradually and came to the lowest by the end of 72 h. Conclusion: The enhanced early expression of mG1uR1 mRNA in hippocampus suggested that mG1uR1 may play an important role in epilepogenesis and may be related to the subsequent neuronal damage.

Time-dependent changes of astrocytes following microinjection of kainic acid and irradiation by gamma-knife in adult rat brain

objective: Two groups of rats were microinjected with kainic acid (KA) and irradiated with gam ma knife respectively on unilateral nucleus caudate-putamen to compare the response of astrocytes. Methods: The astrocytes were identified with anti-GFAP immunohistochemical ABC method and the progress of their reaction to the 2 insults was examined from 3 h to 30 d after the lesion. Results: Both lesions could induce hyperplasia and hypertrophy of astrocytes and 2 types of GFAP-ir cells were found, one with small cell body and thin process, and the other with hypertrophic cell body and thick and long process. The timecourse of GFAP expression in the 2 groups was different. In KA microinjection group, large necrotic area was ob served in the target within 24 h. Three days later, a few astrocytes appeared around the necrosis. With in crease of the survival time, hyperplasia and hypertrophy of astrocytes began to increase. Whereas in gamma knife group, hyperplasia and hypertrophy were evident from 3 h to 7 d and necrotic dots could be seen in the target on day 14. On day 30, necrosis was tnore obvious with gradual variations in GFAP expression around the necrotic area. Conclusion: The above results indicated that GFAP could be used as a marker for CNS in jury; the difference in their timing and distribution pattern suggested different mechanisms in KA microinjec tion group and gamma-knife irradiation group.

Kainic Acid, NMDA and Bicuculline Induce Elevation in Concentrations of Glutathione and Amino Acids <i>in Vivo</i>: Biomarkers for Seizure Predisposition?

The present study was carried out to investigate the effect of NMDA, bicuculline and kainic acid (KA) on the extracellular concentration of glutathione, phosphoethanolamine (PEA) and taurine in rat hippocampus in vivo. Rats were implanted with intrahippocampal microelectrodes perfused with free-glucose Krebs-Ringer solution and allowed to recover for about 2 h. After assaying baseline concentrations of amino acids, NMDA or bicuculline was administered intrahippocampally, whereas KA was given systemically. Either treatment resulted in significant high extracellular concentrations of glutathione, but only NMDA or KA resulted in high concentrations of PEA and taurine. Interestingly, the increase in glutathione concentration due to KA was followed by a delayed increase of glutamate and PEA. Our results demonstrated that increased efflux of glutathione, a common consequence of different neuroexcitotoxic agents, occurs in vivo. Given that the agents used in the present study were also convulsunts, the implication of the findings on seizure predisposition was also considered.

Coexistence of nitric oxide synthase with γ-aminobutyric acid during seizure induced by kainic acid in SD rats

Objective: Functional significance of NO and central inhibitory neurotransmitter γ-aminobutyric(GABA) during seizures were investigated morphorlogically. Methods: A kainate-induced complex partialseizure model was used in our experiment. Twenty SD rats were randomly divided into KA 30, 60, 90, 200min and control groups. The brain sections were stained by NADPh (nicotinamide adenine dinucleotide phosphate ) diaphorase (Nd ) histochemically, and were further stained by GABA immunohistochemically.Results: Histological and immunohistochemical study revealed that in KA groups the number of Nd and GABA-positive double labelled neurons in CA3 region, CA3 region and dentate gyms was significantly reduced,compared with the control group. Conclusion: Nd coexisted with GABA in the brain. Reduction of GABA release led to relief of GABA-ergic inhibition and in the same way, reduction of NO release weakened its negative feedback modulation. Therefore neuronal synchronous paroxysmal discharges increased. GABA and NO,both having antiepileptic action, acted through different ways or different link in the same way. NO may involve in the effect of GABA-ergic neurons and play cooperative antiepileptic action with GABA.

中缝背核内微量注射海人酸(KAINIC ACID)对唇针镇痛效应的影响

我们以往的实验表明,脑内5-羟色胺能神经原系统在唇针镇痛中起着重要的作用。电解损毁5-羟色胺能神经原胞体集中的中脑中缝核,唇针镇痛效应降低;电刺激中缝背核,则唇针镇痛效应增高山。 电解损毁核团目前还是经常采用的研究脑功能的一种方法,但此法不仅损毁了所要研究的核团内的细胞体。

Effect of ketogenic diet on hippocampus mossy fiber sprouting and GluR_5 expression in kainic acid induced rat model

Ketogenic diet （KD） is a high fat, low protein, low carbohydrate diet. Its antiepileptic effect is certain but the underlying mechanism is unknown. Mossy fiber sprouting in the inner molecular layer of the dentate gyrus causes the synaptic reorganization in the hippocampus, which is an important cause of temporal lobe epilepsy in animals and humans. It is also essential to the genesis and development of epilepsy. As the predominant excitatory neurotransmitter in the central nervous system, glutamate plays a role in synaptic reorganization and development of epilepsy.

两种海人酸癫痫小鼠模型的建立及比较研究

目的比较分析海人酸(kainic acid,KA)侧脑室(intracerebroventricular,ICV)注射和腹腔注射(intraperitoneal injections,IP)两种给药路径建立的颞叶癫痫小鼠模型早期的行为学和病理学差异。方法100只C57BL/6N野生型(wild type,WT)雄性小鼠(体质量为20~22 g),按随机数字表法分为4组:ICV+normal saline(NS)对照组(n=10),ICV+KA模型组(n=40),IP+NS对照组(n=10),IP+KA模型组(n=40)。ICV+KA模型组使用600 nL的KA(0.5 mg/mL)进行侧脑室注射,IP+KA模型组按25 mg/kg剂量进行腹腔注射,对照组使用等量的生理盐水进行侧脑室和腹腔注射。建立模型3 d后,进行行为学、分子生物学(Western blot)和神经病理损伤评估(FJB染色,TUNEL染色,免疫荧光染色)。结果两对照组无痫性发作,两模型组均出现痫性发作。IP+KA组与ICV+KA组死亡率分别为47.50%和65.00%,造模成功率分别为80.00%与60.00%。与IP+KA组比较,ICV+KA组小鼠模型成功率明显增高而死亡率明显减少。FJB染色和TUNEL染色结果显示,与IP+KA组比较,ICV+KA组海马的神经变性和凋亡改变程度变化更加明显(P<0.05)。与IP+KA组比较,ICV+KA组海马凋亡蛋白表达差异也有统计学意义(P<0.05)。免疫荧光结果显示,ICV+KA和IP+KA组海马和皮层的星形胶质细胞和小胶质细胞较对照组明显激活(P<0.05),但是ICV+KA组海马和皮层的胶质细胞激活程度均强于IP+KA组(P<0.05)。ICV+KA组海马和皮层的GFAP和Iba-1蛋白表达均高于IP+KA组(P<0.05)。结论两种KA制备方法均可制备出成功的癫痫模型。但ICV路径制备癫痫小鼠具有更高的成功率和更少的死亡率,并且神经病理损害程度和胶质细胞激活程度更加明显。

海人藻酸建立内侧颞叶癫痫小鼠模型的研究

目的 本研究采用立体定向手术在一侧海马注射海人藻酸(kainic acid, KA),建立内侧颞叶癫痫(medial temporal lobe epilepsy, MTLE)慢性模型,通过行为学、电生理学和病理学验证其有效性。方法 取健康的C57BL/6野生型雄鼠22只,随机分成对照组(n=6)和实验组即KA注射组(n=16)。对照组和实验组分别在海马CA3区进行微量注射生理盐水和KA,1周后再次进行立体定向手术,植入脑电记录电极。植入术后1周开始记录小鼠脑电活动,统计癫痫发作次数和持续时间。通过对小鼠的观察与记录,分别从行为学、电生理学和病理学方面验证慢性癫痫模型。结果 本实验对22只C57BL/6野生型雄鼠进行实验,对照组均无癫痫发作,而实验组存活的小鼠均出现癫痫发作。成模的小鼠在行为学上发生了凝视、咀嚼、头面部肌肉抽搐、肢体痉挛等慢性癫痫自发发作行为,有2只小鼠因手术死亡、4只小鼠在急性发作期死亡、10只小鼠模型成功建立;脑电图呈内侧颞叶癫痫样脑电图改变;在病理组织学方面,经免疫荧光染色发现:CA3区神经元丢失,星形胶质细胞大量增生,符合海马硬化特征性的病理改变。结论 通过使用KA单侧、单次颅内注射构建的模型具有耗时、易操作、易成型等多项优势,该模型展现出与人类MTLE相似的脑电图、行为与神经病理改变,有助于研究治疗颞叶癫痫的药物,是癫痫外科手术预后判断的理想动物模型。

TRPV4在海人藻酸介导的小鼠癫痫模型中的作用

目的探讨瞬时感受器电位辣椒素受体4型(TRPV4)在小鼠癫痫持续状态(SE)中的作用及其可能的机制。方法本实验利用腹腔注射海人藻酸(KA)建立小鼠SE模型,随机分为Control组、KA组、HC-0670475 mg·kg^(-1)组、HC-06704710 mg·kg^(-1)组、HC-06704720 mg·kg^(-1)组及Vehicle组;依据Racine行为分级法记录小鼠癫痫发作程度,同时记录小鼠达到SE的潜伏期、各组小鼠SE发生率及小鼠存活率;利用Western-blot和Real-Time PCR检测海马组织中TRPV4表达水平;应用ELISA试剂盒检测海马组织中MDA、SOD和GSH含量。结果观察到SE后6 h小鼠海马区TRPV4的表达水平升高(P<0.05),在24 h达到高峰;预先应用TRPV4拮抗剂HC-067047延长了诱发小鼠SE的潜伏期(P<0.05),减少SE的发病率(P<0.05),增加小鼠的存活率(P<0.05);此外,证实了SE可以引起海马区MDA含量增加,SOD、GSH活性降低(<0.05),而HC-067047预处理可以降低MDA含量,增加SOD、GSH活性(P<0.05)。结果TRPV4可能通过增加海马区氧化应激损伤参与小鼠癫痫持续状态。

定痫丸对海人藻酸诱导的小鼠癫痫行为干预作用研究

目的研究定痫丸颗粒剂对海人藻酸(KA)诱导的小鼠癫痫行为的干预作用,通过群体神经元多通道在体电生理记录技术,探讨定痫丸颗粒剂对小鼠癫痫发作时海马脑区神经元放电模式的影响。方法取雄性野生型小鼠28只,随机分为生理盐水对照组、KA诱导癫痫模型组、定痫丸干预组及丙戊酸钠干预组,每组7只。定痫丸干预组给予定痫丸颗粒剂灌胃;生理盐水对照组及KA诱导癫痫模型组给予与定痫丸干预组同等剂量的生理盐水灌胃;丙戊酸钠干预组给予丙戊酸钠腹腔注射。每天1次,持续10 d。最后1次给药干预后,除生理盐水对照组,其余每组均给予海人藻酸腹腔注射以诱发小鼠癫痫发作并观察各组的行为变化。同步采集海马脑区群体神经元的放电活动。结果定痫丸干预组与KA诱导癫痫模型组比较,小鼠癫痫发作的潜伏期明显延长,癫痫持续状态总时程缩短,癫痫发作行为频率降低,并且癫痫发作时海马脑区神经元放电峰值下降。结论给予动物定痫丸颗粒剂提前干预,能有效改善小鼠癫痫症状,具有明显的抗惊厥效果。

梨状皮层注射红藻氨酸建立癫痫小鼠模型

目的:建立和评价梨状皮层微量注射红藻氨酸(kainic acid,KA)激发的癫痫小鼠模型。方法:利用即刻早期基因(c-fos)免疫荧光染色技术、原位末端转移酶标记染色(TdT-mediated dUTP nick-end labeling,TUNEL)技术在急性癫痫小鼠模型中确定癫痫相关脑区梨状皮层。在梨状皮层脑立体定位注射KA后,观察小鼠癫痫发作程度(Racine评分)和癫痫发作潜伏期,行为学实验包括水迷宫检测小鼠学习记忆能力和新物体识别实验检测小鼠探索能力,癫痫发作结果和行为学实验结果均与海马立体定位注射KA的癫痫模型作对比。利用电生理技术检测新模型小鼠神经元电活动。结果:c-fos免疫荧光和TUNEL染色结果显示,在急性癫痫小鼠模型中除海马外,梨状皮层脑区神经元也被大量激活,且发生凋亡;在梨状皮层注射KA后成功激发癫痫,与海马注射KA的癫痫模型相比,癫痫发作评分没有显著性差异且发作潜伏期更短;行为学结果显示,梨状皮层注射KA的癫痫模型小鼠空间记忆能力降低,新物体探索能力降低,该结果与海马注射KA的癫痫模型相比无显著性差异;膜片钳实验显示梨状皮层注射KA的癫痫模型神经元放电频率增加、幅值降低、静息膜电位上升。结论:在梨状皮层微量注射KA后成功激发癫痫,这为癫痫发病机制的研究提供了一种新的动物模型。