A new rapid kindling variant for induction of cortical epileptogenesis in freely moving rats

Kindling, one of the most used models of experimental epilepsy is based on daily electrical stimulation in several brain structures. Unlike the classic or slow kindling protocols (SK), the rapid kindling types (RK) described until now require continuous stimulation at suprathreshold intensities applied directly to the same brain structure used for subsequent electrophysiological and immunohistochemical studies, usually the hippocampus. However, the cellular changes observed in these rapid protocols, such as astrogliosis and neuronal loss, could be due to experimental manipulation more than to epileptogenesis-related alterations. Here, we developed a new RK protocol in order to generate an improved model of temporal lobe epilepsy (TLE) which allows gradual progression of the epilepsy as well as obtaining an epileptic hippocampus, thus avoiding direct surgical manipulation and electric stimulation over this structure. This new protocol consists of basolateral amygdala (BLA) stimulation with 10 trains of biphasic pulses (10 s; 50 Hz) per day with 20 min-intervals, during 3 consecutive days, using a subconvulsive and subthreshold intensity, which guarantees tissue integrity. The progression of epileptic activity was evaluated in freely moving rats through electroencephalographic (EEG) recordings from cortex and amygdala, accompanied with synchronized video recordings. Moreover, we assessed the effectiveness of RK protocol and the establishment of epilepsy by evaluating cellular alterations of hippocampal slices from kindled rats. RK protocol induced convulsive states similar to SK protocols but in 3 days, with persistently lowered threshold to seizure induction and epileptogenic-dependent cellular changes in amygdala projection areas. We concluded that this novel RK protocol introduces a new variant of the chronic epileptogenesis models in freely moving rats, which is faster, highly reproducible and causes minimum cell damage with respect to that observed in other experimental models of epilepsy.

[1]  R. Köhling,et al.  Network excitability in a model of chronic temporal lobe epilepsy critically depends on SK channel-mediated AHP currents , 2012, Neurobiology of Disease.

[2]  A. Dhir Pentylenetetrazol (PTZ) Kindling Model of Epilepsy , 2012, Current protocols in neuroscience.

[3]  S. Kogure,et al.  Fast Fourier transformation analysis of kindling-induced afterdischarge in the rabbit hippocampus , 2011, Epilepsy Research.

[4]  M. E. Corcoran,et al.  Regional Changes in Gene Expression after Limbic Kindling , 2011, Cellular and Molecular Neurobiology.

[5]  R. Uranga,et al.  MCT Expression and Lactate Influx/Efflux in Tanycytes Involved in Glia-Neuron Metabolic Interaction , 2011, PloS one.

[6]  D. Spencer,et al.  Histopathology of human epilepsy , 2010 .

[7]  W. Löscher,et al.  Functional, metabolic, and synaptic changes after seizures as potential targets for antiepileptic therapy , 2010, Epilepsy & Behavior.

[8]  F. Biagioni,et al.  Altered distribution and function of A2A adenosine receptors in the brain of WAG/Rij rats with genetic absence epilepsy, before and after appearance of the disease , 2009, The European journal of neuroscience.

[9]  A. Musto,et al.  Different phases of afterdischarge during rapid kindling procedure in mice , 2009, Epilepsy Research.

[10]  F. Jensen,et al.  Epileptogenesis in the immature brain: emerging mechanisms , 2009, Nature Reviews Neurology.

[11]  J. Botterill,et al.  The effect of amygdala kindling on hippocampal neurogenesis coincides with decreased reelin and DISC1 expression in the adult dentate gyrus , 2009, Hippocampus.

[12]  R. Dingledine,et al.  Astrocytes in the Epileptic Brain , 2008, Neuron.

[13]  Justin Toupin,et al.  Electrical stimulation protocols for hippocampal synaptic plasticity and neuronal hyper-excitability: Are they effective or relevant? , 2007, Experimental Neurology.

[14]  F. Luo,et al.  Temporal sequence of ictal discharges propagation in the corticolimbic basal ganglia system during amygdala kindled seizures in freely moving rats , 2007, Epilepsy Research.

[15]  E. Galván,et al.  Calcium-activated afterhyperpolarizations regulate synchronization and timing of epileptiform bursts in hippocampal CA3 pyramidal neurons. , 2006, Journal of neurophysiology.

[16]  James O McNamara,et al.  Molecular Signaling Mechanisms Underlying Epileptogenesis , 2006, Science's STKE.

[17]  D. Binder,et al.  Functional changes in astroglial cells in epilepsy , 2006, Glia.

[18]  H. Pape,et al.  Kindling-induced changes in plasticity of the rat amygdala and hippocampus. , 2005, Learning & memory.

[19]  F. Helmchen,et al.  Sulforhodamine 101 as a specific marker of astroglia in the neocortex in vivo , 2004, Nature Methods.

[20]  Jos J Eggermont,et al.  Kindling changes burst firing, neural synchrony and tonotopic organization of cat primary auditory cortex. , 2004, Cerebral cortex.

[21]  Margaret Fahnestock,et al.  Kindling and status epilepticus models of epilepsy: rewiring the brain , 2004, Progress in Neurobiology.

[22]  D. Mcintyre,et al.  Kindling: some old and some new , 2002, Epilepsy Research.

[23]  K. Abe Modulation of hippocampal long-term potentiation by the amygdala: a synaptic mechanism linking emotion and memory. , 2001, Japanese journal of pharmacology.

[24]  F. D. da Silva,et al.  Upregulation of metabotropic glutamate receptor subtype mGluR3 and mGluR5 in reactive astrocytes in a rat model of mesial temporal lobe epilepsy , 2000, The European journal of neuroscience.

[25]  T. Gloveli,et al.  Kindling induces a transient suppression of afterhyperpolarization in rat subicular neurons , 2000, Brain Research.

[26]  Jillian H. Fecteau,et al.  Development of spontaneous seizures over extended electrical kindling I. Electrographic, behavioral, and transfer kindling correlates , 1998, Brain Research.

[27]  O. Lindvall,et al.  Epileptogenesis induced by rapidly recurring seizures in genetically fast- but not slow-kindling rats , 1998, Brain Research.

[28]  E. Bertram,et al.  Interneurons in area CA1 stratum radiatum and stratum oriens remain functionally connected to excitatory synaptic input in chronically epileptic animals. , 1997, Journal of neurophysiology.

[29]  L. Fochtmann,et al.  Genetic variation in immediate and delayed postictal refractory period in rats , 1996, Brain Research.

[30]  Y. Ikegaya,et al.  Dentate gyrus field potentials evoked by stimulation of the basolateral amygdaloid nucleus in anesthetized rats , 1996, Brain Research.

[31]  T. Pencek,et al.  Evidence for decreased calcium dependent potassium conductance in hippocampal CA3 neurons of genetically epilepsy-prone rats , 1995, Epilepsy Research.

[32]  R. Racine,et al.  Activation of astrocytes during epileptogenesis in the absence of neuronal degeneration , 1995, Neurobiology of Disease.

[33]  H. Matsui,et al.  Morphological changes in the hippocampus in amygdaloid kindled mouse , 1995, Epilepsy Research.

[34]  B. George,et al.  Kindling model of epilepsy. , 1994, Methods and findings in experimental and clinical pharmacology.

[35]  E. Lothman,et al.  Morphometric effects of intermittent kindled seizures and limbic status epilepticus in the dentate gyrus of the rat , 1993, Brain Research.

[36]  J. N. Hayward,et al.  Amygdala kindling elevates plasma vasopressin , 1991, Brain Research.

[37]  Thomas P. Sutula,et al.  Progressive neuronal loss induced by kindling: a possible mechanism for mossy fiber synaptic reorganization and hippocampal sclerosis , 1990, Brain Research.

[38]  Edward H Bertram,et al.  Self-sustaining limbic status epilepticus induced by ‘continuous’ hippocampal stimulation: electrographic and behavioral characteristics , 1989, Epilepsy Research.

[39]  D. Mcintyre,et al.  Suppression of amygdala kindling with short interstimulus intervals: Effect of norepinephrine depletion , 1987, Experimental Neurology.

[40]  J. Perlin,et al.  Kindling with rapidly recurring hippocampal seizures , 1985, Brain Research.

[41]  G. V. Goddard,et al.  Is Adenosine an Endogenous Anticonvulsant? , 1985, Epilepsia.

[42]  L. Swanson The Rat Brain in Stereotaxic Coordinates, George Paxinos, Charles Watson (Eds.). Academic Press, San Diego, CA (1982), vii + 153, $35.00, ISBN: 0 125 47620 5 , 1984 .

[43]  F. Dudek,et al.  Synchronous neural afterdischarges in rat hippocampal slices without active chemical synapses. , 1982, Science.

[44]  D. Cain,et al.  A developmental study of kindling in the rat. , 1981, Brain research.

[45]  T. Albertson,et al.  Intertrial intervals and kindled seizures , 1981, Experimental Neurology.

[46]  J. Pinel,et al.  Postseizure inhibition of kindled seizures , 1977, Experimental Neurology.

[47]  R. Racine,et al.  Rates of motor seizure development in rats subjected to electrical brain stimulation: strain and inter-stimulation interval effects. , 1973, Electroencephalography and clinical neurophysiology.

[48]  O. Hansson ‘Defining Medical Terms’ , 1973 .

[49]  R. Racine,et al.  Modification of seizure activity by electrical stimulation. 3. Mechanisms. , 1972, Electroencephalography and clinical neurophysiology.

[50]  R. Racine,et al.  Modification of seizure activity by electrical stimulation. II. Motor seizure. , 1972, Electroencephalography and clinical neurophysiology.

[51]  R. Racine Modification of seizure activity by electrical stimulation. I. After-discharge threshold. , 1972, Electroencephalography and clinical neurophysiology.

[52]  W. Gersch,et al.  Epileptic Focus Location: Spectral Analysis Method , 1970, Science.

[53]  G. V. Goddard,et al.  A permanent change in brain function resulting from daily electrical stimulation. , 1969, Experimental neurology.

[54]  G. V. Goddard,et al.  Development of Epileptic Seizures through Brain Stimulation at Low Intensity , 1967, Nature.

[55]  L. Wilkins The Epileptic Seizure , 1958, Neurology.

[56]  张静,et al.  Banana Ovate family protein MaOFP1 and MADS-box protein MuMADS1 antagonistically regulated banana fruit ripening , 2015 .

[57]  M. Avoli,et al.  Histopathology of Human Epilepsy -- Jasper's Basic Mechanisms of the Epilepsies , 2012 .

[58]  O. von Bohlen und Halbach,et al.  Amygdala‐kindling induces alterations in neuronal density and in density of degenerated fibers , 2004, Hippocampus.

[59]  W. Buño,et al.  Cellular mechanisms underlying the rhythmic bursts induced by NMDA microiontophoresis at the apical dendrites of CA1 pyramidal neurons , 2003, Hippocampus.

[60]  S. Smith,et al.  Measurement of interhemispheric time differences in generalised spike-and-wave. , 1992, Electroencephalography and clinical neurophysiology.

[61]  H. Gastaut Letter: 'Epileptic seizures'. , 1973, Developmental Medicine & Child Neurology.