ライフサイエンスコーパス: epileptogenesis

1 er than the underlying disease process (i.e. epileptogenesis).

2 otentially modifiable therapeutic targets in epileptogenesis.

3 id not directly correlate with inhibition of epileptogenesis.

4 ylation, leading to impaired function during epileptogenesis.

5 pocampus in response to kainate (KA)-induced epileptogenesis.

6 mitant with inhibition of CI activity during epileptogenesis.

7 cellular bioenergetics during the process of epileptogenesis.

8 europathological alterations associated with epileptogenesis.

9 chanisms, and may be an early contributor to epileptogenesis.

10 xpression in neuropathologies that accompany epileptogenesis.

11 nule cells might contribute to temporal lobe epileptogenesis.

12 ving intact neurons alleviated posttraumatic epileptogenesis.

13 ke on group I mGluR-mediated translation and epileptogenesis.

14 bling group I mGluR-mediated translation and epileptogenesis.

15 T2 changes nor interictal activity predicted epileptogenesis.

16 in the brain and blood of animals undergoing epileptogenesis.

17 S generation, contributed also to subsequent epileptogenesis.

18 ith a role for this inflammatory mediator in epileptogenesis.

19 s an important molecular mechanism of limbic epileptogenesis.

20 o neuronal hyperexcitability and possibly to epileptogenesis.

21 ciated with both ischemia-induced injury and epileptogenesis.

22 m with specific characteristics that promote epileptogenesis.

23 he inducing agonist and serves as a model of epileptogenesis.

24 be utilized to suppress seizures and perhaps epileptogenesis.

25 ity, heightened gamma band oscillations, and epileptogenesis.

26 ERAD by the mutant protein may contribute to epileptogenesis.

27 ting in artificially prolonged latencies for epileptogenesis.

28 anism associated with group I mGluR-mediated epileptogenesis.

29 rly-born DGCs that are mature at the time of epileptogenesis.

30 for seizure suppression and modification of epileptogenesis.

31 ate to normal brain development and possibly epileptogenesis.

32 ectively enhanced during critical periods of epileptogenesis.

33 ucted status epilepticus (SE) and subsequent epileptogenesis.

34 ated with formative mechanisms of poststroke epileptogenesis.

35 imit glutamate release, thus contributing to epileptogenesis.

36 e, is a potential predictor and modulator of epileptogenesis.

37 d forebrain ADK were resistant to subsequent epileptogenesis.

38 ure), or 3 weeks after (newborn) pilocarpine-epileptogenesis.

39 no effective therapy is available to prevent epileptogenesis.

40 s of rat neocortex, a model of posttraumatic epileptogenesis.

41 ts, including alpha4, and may play a role in epileptogenesis.

42 gnaling influences neuronal excitability and epileptogenesis.

43 ition may also play an important role during epileptogenesis.

44 reased synaptic excitation and contribute to epileptogenesis.

45 le AMPARs in excitotoxic cellular injury and epileptogenesis.

46 and other Src family kinases contributes to epileptogenesis.

47 pothesized as a major factor contributing to epileptogenesis.

48 re hypothesized to be critical components of epileptogenesis.

49 nt drugs, suggesting an age-specific form of epileptogenesis.

50 ay represent an early stage of posttraumatic epileptogenesis.

51 pathological cellular processes that promote epileptogenesis.

52 also highly susceptible to acutely provoked epileptogenesis.

53 s, suggesting its functional significance in epileptogenesis.

54 -mediated activation of TrkB is required for epileptogenesis.

55 nts, suggesting that FRs are associated with epileptogenesis.

56 e neocortical and hippocampal post-traumatic epileptogenesis.

57 atterns of regulation during development and epileptogenesis.

58 vous system development and certain forms of epileptogenesis.

59 ticus following specific insults may prevent epileptogenesis.

60 atum oriens of the hippocampus during limbic epileptogenesis.

61 h) in controlling dendritic excitability and epileptogenesis.

62 reflect pathophysiological processes beyond epileptogenesis.

63 al for interrupting the processes underlying epileptogenesis.

64 ect localized pathological events related to epileptogenesis.

65 nst hCA II and hCA VII, isoforms involved in epileptogenesis.

66 t no detectable regulatory effects on limbic epileptogenesis.

67 one mechanism by which BDNF promotes limbic epileptogenesis.

68 persist for up to 1 year after induction of epileptogenesis.

69 ent of the given pathology in the process of epileptogenesis.

70 ersisted up to 1 year after the induction of epileptogenesis.

71 43 in the brain and serum over the course of epileptogenesis.

72 the acute and latent phase of injury-induced epileptogenesis.

73 abolites may be able to serve as a marker of epileptogenesis.

74 ol for identifying brain inflammation during epileptogenesis.

75 es to hippocampal dendrites that may promote epileptogenesis.

76 e an epileptogenic brain insult can mitigate epileptogenesis.

77 hippocampal culture model of post-traumatic epileptogenesis.

78 nto the role of microglial activation during epileptogenesis.

79 tatory neurotransmission plays a key role in epileptogenesis.

80 e gyrus, potentially mediating temporal lobe epileptogenesis.

81 tion-dependent neuronal plasticity including epileptogenesis.

82 astrogliosis is a cause or a consequence of epileptogenesis.

83 p, may be proposed as putative biomarkers of epileptogenesis.

84 th, in older animals may augment TBI-induced epileptogenesis.

85 signaling cascade reduces the probability of epileptogenesis.

86 and triggers neuronal hyperexcitability and epileptogenesis.

87 ppocampal CA3 neurons, a classical focus for epileptogenesis.

88 eptors in provoking seizures and in kindling epileptogenesis.

89 igger of inflammatory cascades implicated in epileptogenesis.

90 tes by serum-derived albumin, is involved in epileptogenesis.

91 le of facilitated NMDA receptor signaling in epileptogenesis.

92 hat HIF-1alpha is an important factor during epileptogenesis.

93 us, and to explore their relationship during epileptogenesis.

94 her allergic inflammation contributes toward epileptogenesis.

95 nd has also been implicated in temporal lobe epileptogenesis.

96 mpus and exhibit neuroplastic changes during epileptogenesis.

97 ences of increased protein synthesis in FXS, epileptogenesis.

98 ority of restructuring in the dentate during epileptogenesis.

99 (TrkB) is thought to be critical for limbic epileptogenesis.

100 t these excitatory synapses that may promote epileptogenesis.

101 vals and a poor measure of the time frame of epileptogenesis, (2) epileptogenesis is a continuous pro

102 in mice, indicating that the drug slows down epileptogenesis, a finding deserving further investigati

103 lts suggest GAP-43 as a key factor promoting epileptogenesis, a possible therapeutic target for treat

104 riod may serve as a diagnostic biomarker for epileptogenesis, able to predict the future onset of spo

105 models, discovery of new basic mechanisms of epileptogenesis, acceleration of proof of principle stud

106 During epileptogenesis, adult-generated granule cells (DGCs) fo

107 These results indicate that hippocampal epileptogenesis after convulsive status epilepticus is a

108 bitory synapses, and the critical period for epileptogenesis after head injury has been better define

109 nflammation were shown to be associated with epileptogenesis after injury.

110 s utility to delineate mechanisms underlying epileptogenesis after pediatric brain injury, and provid

111 lp develop therapeutic strategies to prevent epileptogenesis after stroke and elucidate some of the m

112 izures develop is critical for understanding epileptogenesis, an understanding of how and why recurre

113 ion of the adenosine system is implicated in epileptogenesis and cell therapies have been developed t

114 abolism in rat plasma and hippocampus during epileptogenesis and chronic epilepsy in the kainic acid

115 nts and determine the latency to hippocampal epileptogenesis and clinical epilepsy, we developed an e

116 EGCs that develop after SE may contribute to epileptogenesis and cognitive impairments that follow SE

117 zure duration as an important determinant in epileptogenesis and defining the predictive roles of int

118 ovel insights into the mechanisms underlying epileptogenesis and discover potential preventive treatm

119 rstand the role of HMGB1 and its isoforms in epileptogenesis and drug resistance.

120 MGB1 isoforms are mechanistic biomarkers for epileptogenesis and drug-resistant epilepsy in humans, n

121 leptic brain and as a potential biomarker of epileptogenesis and epileptogenicity and for presurgical

122 chmarks is to develop reliable biomarkers of epileptogenesis and epileptogenicity that could revoluti

123 gest an important role of innate immunity in epileptogenesis and focus on glial inhibition, through p

124 l studies of basic mechanisms of spontaneous epileptogenesis and for preclinical screening of effecti

125 k clinically relevant noninvasive markers of epileptogenesis and found that reduced amygdala T2 relax

126 Specific mechanisms of TBI-related epileptogenesis and how these mechanisms are affected by

127 l teach us much about the pathophysiology of epileptogenesis and ictogenesis.

128 BDNF expression, only a modest impairment of epileptogenesis and increased hippocampal TrkB activatio

129 ulation of the endocannabinoid system during epileptogenesis and indicates that the CB(1) receptor re

130 d may be associated with both the process of epileptogenesis and maintenance of the epileptic state.

131 for understanding the mechanisms underlying epileptogenesis and may provide insights into why sponta

132 rks in MTLE may improve the understanding of epileptogenesis and neuropsychological impairments assoc

133 has in turn enriched our knowledge of human epileptogenesis and normal brain development and functio

134 l process commonly occurring in experimental epileptogenesis and observed in human epilepsy.

135 ibute to network alterations associated with epileptogenesis and offers a useful strategy for identif

136 ling pathways that control susceptibility to epileptogenesis and possibly persistence of an epileptic

137 in DNA methylation homeostasis may underlie epileptogenesis and reversal of these epigenetic changes

138 been implicated in playing a crucial role in epileptogenesis and seizure generation.

139 Astrocytes have been implicated in epileptogenesis and seizure-induced brain injury.

140 stic changes in excitability observed during epileptogenesis and SRS.

141 ts receptor, TrkB, in the hippocampus during epileptogenesis and that BDNF-mediated activation of Trk

142 he data that support the concepts underlying epileptogenesis and the model systems that are presumed

143 pathway has been implicated in mechanisms of epileptogenesis and the mTORC1 inhibitor, rapamycin, has

144 Ca(2+)](i) remained markedly elevated during epileptogenesis and was still elevated indefinitely in t

145 ver 600 were regulated during development or epileptogenesis, and 37 of these were either upregulated

146 urons also were altered in the brain-injury, epileptogenesis, and chronic-epilepsy phases of AE.

147 erexcitability conditions, such as seizures, epileptogenesis, and epilepsy.

148 xcitatory synaptic transmission, plasticity, epileptogenesis, and excitotoxicity.

149 s in synaptic function and formation play in epileptogenesis, and further illustrate just how closely

150 d our understanding of circuit mechanisms of epileptogenesis, and have potential implications for the

151 age (MRI) provided predictive biomarkers for epileptogenesis, and if the inflammatory mediator interl

152 ycin (mTOR) signaling pathway is involved in epileptogenesis, and mTOR inhibitors prevent epilepsy in

153 old for status epilepticus (SE), accelerated epileptogenesis, and once epilepsy was induced, depressi

154 target, neuronal damage is not necessary for epileptogenesis, and other mechanisms are at play.

155 leptic drugs are not effective in preventing epileptogenesis; antiepileptic drugs were, however, not

156 The mechanisms of ischemia-induced epileptogenesis are not completely understood, but gluta

157 y for group I mGluR-mediated translation and epileptogenesis are unknown.

158 hanisms of mTOR activation in post-traumatic epileptogenesis are unknown.

159 The development of epileptogenesis as measured by electrophysiological and

160 occurs in both neurons and astrocytes during epileptogenesis, as assessed by measuring biochemical an

161 ergic inhibition, which may be key factor in epileptogenesis, as the seizures in vivo are blocked by

162 Epileptogenesis assessed by development of kindling was

163 activation as well as neuronal cell loss in epileptogenesis-associated brain regions at all investig

164 uptake and binding potential were evident in epileptogenesis-associated brain regions, such as the hi

165 In contrast, the epileptogenesis-associated increase of p-trk immunoreact

166 Deficits in KCC2 activity are implicated in epileptogenesis, but how increased neuronal activity lea

167 The thalamus also contributes to epileptogenesis, but no studies have directly assessed c

168 ing that peri-insult generated cells mediate epileptogenesis, but that seizures per se are initiated

169 e BDNF receptor, TrkB, is critical to limbic epileptogenesis, but the responsible downstream signalin

170 B (trkB) receptor activation promotes limbic epileptogenesis, but whether or where trkB activation oc

171 ive stress was reduced in animals undergoing epileptogenesis by a transient treatment with N-acetylcy

172 more physiologically relevant and linked to epileptogenesis, by characterizing the effects of these

173 We hypothesized that epileptogenesis can induce molecular changes in the hipp

174 ctivation of the BDNF receptor TrkB promotes epileptogenesis caused by status epilepticus.

175 Genes selectively regulated by NRSF during epileptogenesis coded for ion channels, receptors, and o

176 ro preparations, during early post-traumatic epileptogenesis demonstrated rapid increases in the frac

177 s revealed that the severity of TBI-mediated epileptogenesis depends on the age of the animal.

178 yer recording determined whether hippocampal epileptogenesis develops immediately or long after injur

179 Whereas TrkB can be activated, and epileptogenesis develops in BDNF(-/-) mice, the plastici

180 these findings to the general mechanisms of epileptogenesis during development and points out gaps i

181 ypes including an enhanced susceptibility to epileptogenesis during development.

182 critical role for AMPA receptors (AMPARs) in epileptogenesis during this critical period in the devel

183 HFOs can be used as a reliable biomarker for epileptogenesis, epileptogenicity, and the delineation o

184 mmature granule cells exposed to pilocarpine-epileptogenesis exhibited aberrant hilar basal dendrites

185 utamate receptor (mGluR) stimulation include epileptogenesis, expressed in vitro as the conversion of

186 he specific subunit Kv3.4 is affected during epileptogenesis following pilocarpine-induced status epi

187 icographic or intrahippocampal recordings of epileptogenesis (from the insult to the first spontaneou

188 that some aspects of normal development and epileptogenesis have common molecular mechanisms.

189 addressed the role of TGF-beta signaling in epileptogenesis in 2 different rat models of vascular in

190 we studied the properties of the TBI-induced epileptogenesis in a biophysically realistic cortical ne

191 mpal injury and tissue reorganization during epileptogenesis in a mouse mTLE model.

192 he contribution of glial cells as drivers of epileptogenesis in acquired epilepsies.

193 se oscillations occur in the early stages of epileptogenesis in areas adjacent to the brain lesion an

194 Results indicate that epileptogenesis in C1q KO mice is related to a genetical

195 Understanding the mechanisms of limbic epileptogenesis in cellular and molecular terms may prov

196 expression and hippocampal apoptosis during epileptogenesis in comparison with the positive control.

197 t into the mechanism and future treatment of epileptogenesis in EIEE13.

198 treatment, changes that likely contribute to epileptogenesis in experimental mTLE.

199 a unique target for preventing or retarding epileptogenesis in females.

200 could be a viable prophylactic treatment for epileptogenesis in FXS.

201 may play a role in the expression of in-situ epileptogenesis in human CD.

202 tyric acid (GABA) function can contribute to epileptogenesis in humans and animal models.

203 These data suggest that epileptogenesis in Jerky-deficient mice most likely invo

204 t to show contrasting effects on spontaneous epileptogenesis in kindled animals as well.

205 Its requirement for epileptogenesis in kindling implicates TrkB and downstre

206 of metabolic genes in the hippocampus during epileptogenesis in male rats in the pilocarpine model of

207 that inhibition of DNA methylation inhibited epileptogenesis in multiple seizure models.

208 ion play an essential role in the process of epileptogenesis in patients with FCD.

209 The delayed epileptogenesis in PR knock-out mice was not substantial

210 sed several forms of seizure sensitivity and epileptogenesis in rats selectively bred for vulnerabili

211 ossy fiber pathway of the hippocampus during epileptogenesis in rats.

212 anges in neuronal integrity that may promote epileptogenesis in such individuals.

213 sitive-feedback circuits might contribute to epileptogenesis in temporal lobe epilepsy.

214 disease and trace the biological pathways to epileptogenesis in the developing brain.

215 s but may not be necessary prerequisites for epileptogenesis in the developing brain.

216 e potential contribution of these changes to epileptogenesis in the dysplastic human brain.

217 oforms, exhibited an increased resistance to epileptogenesis in the hippocampus and amygdala kindling

218 stimulation activates translation-dependent epileptogenesis in the hippocampus.

219 l plasticity pathway that may play a role in epileptogenesis in the immature brain.

220 e that mTOR signaling mediates mechanisms of epileptogenesis in the kainate rat model and that mTOR i

221 ant cells make differential contributions to epileptogenesis in the tuberous sclerosis complex.

222 by Nav beta1 contributes to the mechanism of epileptogenesis in these animals as well as in patients.

223 n intact model of epilepsy and indicate that epileptogenesis in this model produced long-lasting alte

224 uggests that astrocytes may be important for epileptogenesis in TSC.

225 nabling even short RE cell bursts to promote epileptogenesis in two ways: first, by activating GABA(B

226 Evidence of TrkB activation during epileptogenesis in vivo despite genetic deletion of its

227 During limbic epileptogenesis in vivo the dentate granule cells (DGCs)

228 epileptiform discharge in vitro and kindling epileptogenesis in vivo with partial gamma-aminobutyric

229 - one] resulted in a significant decrease in epileptogenesis in wild-type (PR(+/+)) mice.

230 Epileptogenesis in wild-type (WT) mice was associated wi

231 hanisms at play during epilepsy development (epileptogenesis) in animal models of TLE could enable th

232 In a mouse model of focal epileptogenesis, in which astrogliosis is restricted to

233 is study was to develop an in vitro model of epileptogenesis induced by glutamate injury in organotyp

234 transiently administered for 2 weeks during epileptogenesis inhibited oxidative stress more efficien

235 These AEDs target mechanisms of epileptogenesis involving amyloid beta and tau.

236 re of the time frame of epileptogenesis, (2) epileptogenesis is a continuous process that extends muc

237 ical conditions, and one prominent theory of epileptogenesis is based on the assumption that mossy ce

238 Understanding molecular mechanisms mediating epileptogenesis is critical for developing more effectiv

239 of recurring seizures to the progression of epileptogenesis is debated.

240 me course of fluid percussion injury-induced epileptogenesis is dramatically biased by the definition

241 evelops in BDNF(-/-) mice, the plasticity of epileptogenesis is eliminated in TrkB(-/-) mice.

242 Hippocampal epileptogenesis is hypothesized to involve secondary mec

243 e spatial organization of cortical trauma on epileptogenesis is poorly understood.

244 One cornerstone event during epileptogenesis is the occurrence of the first spontaneo

245 Epileptogenesis is the process whereby a normal brain be

246 overall influence of altered neurogenesis on epileptogenesis is therefore unclear.

247 ether or where trkB activation occurs during epileptogenesis is uncertain.

248 sial temporal lobe epilepsy, but its role in epileptogenesis is unclear and controversial.

249 Its role in epileptogenesis is unclear and controversial.

250 hanism underlying the group I mGluR-mediated epileptogenesis is unknown.

251 drial processes during epilepsy development (epileptogenesis) is unknown.

252 table to the complex alterations involved in epileptogenesis, it is likely that multitargeted approac

253 scence microscopy during the injury (acute), epileptogenesis (latency), and chronic-epilepsy phases o

254 twork formations during the course of limbic epileptogenesis (LE).

255 For I(mGluR(V)) to play a role in epileptogenesis, long-term activation of the current mus

256 Epileptogenesis may develop due to genetic or pharmacolo

257 s in vitro model of glutamate injury-induced epileptogenesis may help develop therapeutic strategies

258 The process of postinjury hippocampal epileptogenesis may involve gradually developing dentate

259 Epileptogenesis may involve the creation of these topogr

260 ase in h channels during a critical phase of epileptogenesis mechanistically underlies dendritic hype

261 ia and oxidative stress has been proposed in epileptogenesis of temporal lobe epilepsy (TLE).

262 The mechanisms of epileptogenesis operative in this subcortical lesion are

263 s recurrent seizures and could contribute to epileptogenesis or development of the epileptic state.

264 GluK1 kainate receptors are not required for epileptogenesis or seizure expression in this model.

265 it hyperactivity disorder, in suppression of epileptogenesis, or enhancement of cognition.

266 er pharmacological induction of an otherwise epileptogenesis-precipitating acute brain injury, transg

267 seizures in WT mice when implanted after the epileptogenesis-precipitating brain injury.

268 f animals with antiinflammatory drugs during epileptogenesis prevented both disease progression and b

269 NMDARs, we conclude that astrocytes modulate epileptogenesis, recurrent spontaneous seizures, and pat

270 s, the pathophysiological mechanisms of such epileptogenesis remain unknown and no adjunctive therapy

271 nking neuronal synchrony and burst firing to epileptogenesis remains equivocal.

272 ed spatially localized HSP to post-traumatic epileptogenesis remains poorly understood.

273 but whether these changes are important for epileptogenesis remains unknown.

274 mpal interneuron activity has been linked to epileptogenesis, seizures and the oscillatory synaptic a

275 ineates the onset and suggests mechanisms of epileptogenesis that follow experimental FSE.

276 erefore, our study identifies a mechanism of epileptogenesis that links MAP kinase to Eph/Ephrin and

277 ning synapses is a reversible, early step in epileptogenesis that offers a novel therapeutic target i

278 d from IL-6 -: treated mice show that during epileptogenesis, the cells respond to repetitive orthodr

279 ptic plasticity (HSP) mediates posttraumatic epileptogenesis through unbalanced synaptic scaling, par

280 onal model to relate changes observed during epileptogenesis to a decreased tendency to burst in the

281 (-/-) mice exhibited behavioral endpoints of epileptogenesis, tonic-clonic seizures.

282 The group I mGluR model of epileptogenesis took on special significance because epi

283 a cascade of events that eventually lead to epileptogenesis triggered by TBI.

284 ltered gene expression and thus may underlie epileptogenesis via induction of permanent changes in ne

285 Oxidative stress during epileptogenesis was associated with de novo brain and bl

286 Epileptogenesis was initiated using the pilocarpine stat

287 and other molecular markers correlating with epileptogenesis was measured by Western blotting.

288 Mossy cell loss, also implicated in epileptogenesis, was assessed as well.

289 addition, changes in theta band power during epileptogenesis were associated with altered locomotor a

290 gical measures and no behavioral evidence of epileptogenesis were detected in TrkB(-/-) mice.

291 s as crucial mediators in the development of epileptogenesis, which is the process whereby a normal b

292 gests that impaired autophagy contributes to epileptogenesis, which may be of interest as a potential

293 ys of understanding the molecular pathway of epileptogenesis, widening the spectrum of possible thera

294 ats following photothrombotic infarction and epileptogenesis with emphasis on the distribution of neu

295 he repeated flurothyl paradigm is a model of epileptogenesis with spontaneous seizures that remit.

296 tic animals at 1 year after the induction of epileptogenesis with two different fluorescent dyes (Fur

297 correlating with the development of chronic epileptogenesis within hippocampus.

298 ate the molecular and cellular mechanisms of epileptogenesis without any complication from drug-induc

299 ncreased capacity for AMPA receptor-mediated epileptogenesis without inducing cell death.

300 synchronous burst firing is associated with epileptogenesis, yet the evidence from human studies lin