Termination of Epileptic Afterdischarge in the Hippocampus

QUICK SEARCH:

[advanced]

	Author:		Keyword(s):
Year:		Vol:		Page:

HOME | SEARCH | ARCHIVE | SUBSCRIBE | CONTACT | HELP

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (45)

Citing Articles via Google Scholar

Google Scholar

Articles by Bragin, A.

Articles by Buzsáki, G.

Search for Related Content

PubMed

PubMed Citation

Articles by Bragin, A.

Articles by Buzsáki, G.

Previous Article  |  Next Article

Volume 17, Number 7, Issue of April 1, 1997 pp. 2567-2579
Copyright ©1997 Society for Neuroscience

Termination of Epileptic Afterdischarge in the Hippocampus

Anatol Bragin, Markku Penttonen, and György Buzsáki
Center for Molecular and Behavioral Neuroscience, Rutgers, The State University of New Jersey, Newark, New Jersey 07102

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

The mechanism of afterdischarge termination in the various hippocampal regions was examined in the rat. Stimulation of theperforant path or the commissural system was used to elicit afterdischarges.Combination of multiple site recordings with silicon probes, currentsource density analysis, and unit recordings in the awake animalallowed for a high spatial resolution of the field events. Interpretationof the field observations was aided by intracellular recordingsfrom anesthetized rats. Irrespective of the evoking conditions,afterdischarges always terminated first in the CA1 region. Terminationof the afterdischarge was heralded by a large DC shift initiatedin dendritic layers associated with a low amplitude "afterdischargetermination oscillation" (ATO) at 40 to 80 Hz in the cell bodylayer. ATOs were also observed in the CA3 region and the dentategyrus. The DC shift spread at the same velocity (0.1-0.2 mm/sec)in all directions and could cross the hippocampal fissure. Allbut 1 of the 25 putative interneurons in the CA1 and dentate regionsceased to fire before the onset of ATO. Intracellularly, ATO andthe emerging DC potential were associated with fast depolarizingpotentials and firing of pyramidal cells and depolarization blockof spike initiation, respectively. Both field ATO and the intracellulardepolarization shift were replicated by focal microinjection ofpotassium. We hypothesize that [K⁺]_o lost by the intensely discharging neurons during the afterdischargetriggers propagating waves of depolarization in the astrocyticnetwork. In turn, astrocytes release potassium, which inducesa depolarization block of spike generation in neurons, resultingin "postictal depression" of the EEG.
Key words: epilepsy; spreading depression; oscillation; potassium; interneurons; ephaptic effects; glia

INTRODUCTION

The most common form of seizures, complex partial epilepsy, arises in the hippocampal region (cf. Engel, 1989; McNamara, 1994).The seizures are often followed by depressed electrical activity,termed "postictal silence" (Engel, 1989). Numerous in vivo andin vitro models of epilepsy have investigated the emergence, maintenance,and spread of seizures. In contrast, relatively few studies havespecifically addressed the issue of seizure termination (Libersonand Cadilhac, 1953; Penfield and Jasper, 1954; Gloor et al., 1961;Sypert and Ward, 1971; Leao, 1972; Heinemann et al., 1977; Haglundand Schwartzkroin, 1984; Somjen et al., 1985; Leung, 1987). Theissue is important because understanding factors critically involvedin ending an ongoing seizure may lead to a more effective treatmentof epileptic patients.

The goal of the present investigation was to reveal the contribution of the various factors responsible for the terminationof stimulation-induced afterdischarges in the intact brain. Thelaminar neuronal organization of the hippocampus (Amaral and Witter,1989) makes this structure particularly relevant to investigatepopulation synchrony and flow of extracellular currents. Nevertheless,in contrast to relatively stationary signals, such as evoked potentialsand behavior-dependent oscillatory patterns, studying the laminardistribution of epileptic activity is difficult given the nonstationarynature of seizures and the time required to obtain samples repeatedlyfrom different sites during successive afterdischarges (Wadmanet al., 1992). This is especially true for slow currents generatedby the glial network (cf. Heinemann et al., 1995). Multiple siterecordings with equally spaced electrodes (Bragin et al., 1995;Ylinen et al., 1995) may alleviate this difficulty. In the studiesreported below, we used high-resolution multiple site siliconprobes for the continuous analysis of current source density andsingle unit activity during afterdischarges in the awake rat.Interpretation of the extracellular field and unit observationswere further aided by intracellular recordings in the anesthetizedanimal. Seizures were elicited by stimulation of either the perforantpath or the associational/commissural system because these protocolshave most often been used in intact animals (Sloviter 1983; Leung1987; Lothman and Williamson, 1993; Mody 1993), and because wewanted to investigate whether termination of afterdischarges dependson the initiation site.

MATERIALS AND METHODS
Surgery. Twenty-seven male and female Sprague Dawley rats (300-450 gm) were used in this study. The rats were anesthetizedwith a 4 ml/kg mixture of 25 mg/ml ketamine, 1.3 mg/ml xylazine,and 0.25 mg/ml acepromazine. Pairs of stainless steel wires (100µm in diameter) with 0.5 mm vertical tip separation were placedin the angular bundle unilaterally (right side) or bilaterallyto stimulate the medial perforant path afferents to the hippocampus[anterior = $-$ 7.0 mm from bregma, lateral = 3.5 mm from midline,and ventral = $-$ 3.0 mm]. Another electrode pair was placed intothe ventral hippocampal commissure (anterior = $-$ 0.8, lateral =0.5, ventral = $-$ 4.2) to stimulate the commissural afferents tothe CA1-3 regions and the dentate gyrus.

Two different recording electrodes were used: stationary or movable wire electrodes and multisite recording silicon probes.Wire electrodes (two to four 60 µm tungsten wires) were implantedin the strata pyramidale and radiatum of CA1, the molecular layer,and hilus of the dentate gyrus (anterior = $-$ 3.0, lateral = 2.6,ventral = $-$ 2.1 to $-$ 3.1) and the CA3 pyramidal layer (anterior= $-$ 3.0, lateral = 3.2, ventral = $-$ 3.5). For simultaneous recordingof field potentials and unit activity in different hippocampalregions and layers, silicon probes micromachined with thin-filmtechnology were used (Bragin et al., 1995). In the 24-site probe,each of the 6 shanks had 4 recording sites (9 × 9 µm² platinum-plated pads) that were spaced 25 µm apart. The shankswere 300 µm apart. The thickness of the silicon shank was 15 µmthroughout. In the 16-site single shank probe, the recording siteswere 100 µm from each other in the vertical plane (80 µm wideat the base, narrowing to 15 µm at the tip). The recording siteswere platinum-plated. A 3 × 1 mm slot was drilled into the skullabove the dorsal hippocampus, parallel to the long axis of thestructure, through which the recording electrodes were insertedafter cutting the dura mater. The silicon probes were insertedinto the neocortex or corpus callosum during surgery. After recovery,the tips were lowered gradually into the hippocampus with theaid of a microdrive (Bragin et al., 1995). During the experiment,evoked field potentials helped guide the positioning of the microelectrodes.Two stainless steel watch screws driven into the bone above thecerebellum served as indifferent and ground electrodes.

Recording and stimulation. Six 4-channel MOSFET input operational amplifiers, mounted in the female connector, served to eliminatecable movement artifacts (Buzsáki et al., 1989a). Physiologicaldata were recorded either wide-band (1 Hz to 5 kHz for units andfield) or with an ultra slow time constant (0.03 or 0.1 Hz) andsampled at 10 kHz or 100 Hz/channel, respectively, with 12-bitprecision. The data were stored on optical disks. All analyseswere carried out off-line on a 486/66 MHz PC and/or IBM RS 6000computer. Afterdischarges were induced by a single 1 sec, 200Hz (0.1 msec) pulse train delivered to the perforant path (PP)or the commissural path (COM). The stimuli were supramaximal forevoking population spikes in the dentate gyrus (PP) or CA1 pyramidallayer (COM). If the train failed to induce an afterdischarge (<5%of cases), the stimulus intensity or pulse duration was increasedand tetanic stimulation was repeated after a rest period of atleast 30 min. The duration of the primary afterdischarge in eachregion was measured from the onset of large amplitude rhythmicwaves with or without population spikes to the "isoelectric" silentperiod. The propagation velocity of the slow waves was determinedfrom the latency of the negative peaks of the slow events andthe distance of the recording sites. Nineteen of the animals alsoserved as subjects in a previous experiment to study the emergenceand maintenance of afterdischarges in the hippocampal-entorhinalsystem (Bragin et al., 1996).

Current source density (CSD) analysis. Complete accounts of the theoretical basis of CSD analysis have been presented earlier(Freeman and Nicholson, 1975; Mitzdorf 1985). CSDs were calculatedin one direction (depth), assuming that currents in the septotemporaland subiculofimbrial directions were negligible (Leung, 1979).Although some resistivity differences are present in the differenthippocampal layers, in practice these are not large enough tosignificantly modify the spatial distribution of sinks and sources(Holsheimer, 1987). The CSD results are presented as the unscaledsecond derivative of potential as a function of depth, proportionalto the actual current densities (Bragin et al., 1995; Ylinen etal., 1995). The exact anatomical layers corresponding to the verticalscale of the CSD maps were reconstructed with the aid of the histologicallyidentified recording tracks and evoked potentials. Current sinksand sources associated with the activation of the PP and COM afferentsprovided precise landmarks for the identification of the recordingsites. Unitary activity in the CA1 pyramidal layer provided anadditional marker for the depth of the electrodes.

Histological procedures. After completion of the experiments, the rats were deeply anesthetized and perfused through the heartfirst with cacodylate-buffered saline (pH 7.5), followed by acacodylate-buffered fixative containing 4% paraformaldehyde and5.9% calcium chloride (pH 7.5). Brains were left in situ for 24hr, removed, and then postfixed in the same solution for 1 week.The brains were sectioned with the probes left in the brain ona vibratome at 100 µm in the coronal plane. The sections werestained with the Nissl method.

Intracellular methods. Seventeen Sprague Dawley (250-350 gm) rats were anesthetized with urethane (1.3-1.5 gm/kg) and placedin a stereotaxic apparatus. The body temperature of the rat waskept constant by a small animal thermoregulation device. The scalpwas removed, and a small bone window (2.0 mm) was drilled abovethe hippocampus (anterior = $-$ 3.3 and lateral = 2.2 mm from bregma)for extra- and intracellular recordings. Pairs of stimulatingelectrodes (100 µm each, with 0.5 mm tip separation) were insertedinto the left and right fimbria-fornix (anterior = $-$ 1.3, lateral= 1.0, ventral = 4.1) to stimulate the COM input to the CA1 region.The cisterna magna was opened, and the cerebrospinal fluid wasdrained to decrease pulsation of the brain. Extracellular recordingelectrodes (three 20 µm insulated tungsten wires) were insertedinto the hippocampus to record field and unit activity from theCA1 pyramidal layer, stratum radiatum, and the dentate hilus.After the intracellular recording electrode was inserted intothe brain, the bone window was covered by a mixture of paraffin(50%) and paraffin oil (50%) to prevent drying of the brain anddecrease pulsation. The distance of the intracellular and extracellularelectrodes was 0.5-1.0 mm in the anteroposterior and 0.2-0.5 mmin the lateral directions.

Micropipettes for intracellular recordings were pulled from 2.0 mm capillary glass. They were filled with 1 M potassium acetatein 50 mM Tris buffer, containing also 3% biocytin for intracellularlabeling. In vivo electrode impedances varied from 60 to 100 M $Omega$ .Once stable intracellular recordings were obtained, evoked andpassive physiological properties of the cell were determined.Field activity was recorded through the extracellular electrodeand filtered between 1 Hz and 5 kHz. After the physiological datahad been collected, biocytin was injected through a bridge circuit(Axoclamp-2B) using 500 msec depolarizing pulses at 0.5-2.0 nAat 1 Hz for 10-60 min (Li et al., 1994; Sik et al., 1995). After2-12 hr postinjection survival times, the animals were given aurethane overdose and then perfused intracardially with 100 mlphysiological saline, followed by 400 ml of 4% paraformaldehydeand 0.2% glutaraldehyde dissolved in PBS, pH 7.3. The brains werethen removed and stored in the fixative solution overnight. Sixty-micrometer-thickcoronal sections were cut and processed for biocytin labelingas described previously (Sik et al., 1995). In four experiments,the micropipette was broken (<1 M $Omega$ ) and DC changes were measuredin the CA1 pyramidal layer during epilepsy or KCl-induced spreadingdepression.

Pressure ejection of KCl. Extracellular DC shifts and spreading depression were induced by pressure ejection (Picospritzer,General Valve Co.) of 1 M KCl solution from a glass micropipette(2-5 µm tip diameter; Herreras et al., 1994). The pipette wasplaced 0.3-1.0 mm posterior to the intracellular microelectrodeand also served for monitoring the local EEG.

RESULTS
In agreement with previous studies on stimulus-induced afterdischarges in the rat, several distinctive epochs could be recognized(Leung, 1987; Buzsáki et al., 1989b) which included: (1) a 20-60sec primary afterdischarge of slow (2-12 Hz), fast (30-120 Hz),and ultrafast (200-400 Hz) oscillations; (2) a silent postictaldepression period; and (3) a secondary afterdischarge. The animalsat or stood still throughout these events with occasional "wetdog" shakes occurring during the secondary afterdischarge and,rarely, during the later part of primary afterdischarge. EEG activitygradually recovered after these three distinctive epochs. However,substantial alterations could be recognized in the EEG for severalhours (Leung, 1987).

The large amplitude events associated with afterdischarges can be recorded from various regions and layers of the hippocampus.A large part of these voltage traces is often a result of volumeconduction from distant current generators. Thus, voltage tracesare not always reliable for tracing the structural sources ofthe field events. CSD analysis provides a more precise localizationfor the origin of extracellular currents. The current that flowsinto the cells across an increased membrane conductance (an activeinward current or sink) will exit at adjacent, inactive partsof the membrane (passive outward current or source) to returnto the site of current entry by way of diverse paths through theextracellular medium. Conversely, active outward currents, generatedby decreased membrane conductance, will create inward currentsat the inactive parts of the membrane (passive sinks) by way ofthe extracellular return current. When extracellular potentialsare simultaneously measured at various depths, the CSD derivativesof the voltage traces allow for the continuous monitoring of theexact anatomical locations of sinks and sources. Figure 1 illustratesCSD traces during the course of an afterdischarge and the mainevents distinguished in the present work.
Fig. 1. Main patterns of the afterdischarge in the hippocampus evoked by COM stimulation (200 Hz). The continuous voltage traces from16 recording sites (1-2000 Hz bandpass) were used to calculatethe CSD derivatives. Only three selected CSD traces from the CA1pyramidal layer (p), stratum radiatum (r), and the supragranularlayer (m/g) are shown here. Sinks are up. Arrows, Onset of thesustained potential (SP) shifts recorded by the AC-coupled amplifiers;pID, postictal depression. ATO, Afterdischarge termination oscillation.The primary afterdischarge (pad) shown here is omitted from theillustrations in Figures 2, 3, 4.
[View Larger Version of this Image (21K GIF file)]

Termination of the primary afterdischarge: ATO and sustained potentials
The initiation and maintenance of the primary afterdischarge (pAD) have been described previously in an overlapping set ofanimals (Bragin et al., 1996). The evoked pAD was stereotypicalboth within and across animals, lasting for 30-40 sec (Buzsákiet al., 1989; Stringer et al., 1991; McNamara, 1994; Bragin etal., 1996). The pAD invariably terminated first in the CA1 regionin all animals, regardless of whether the afterdischarge was inducedby PP or COM stimulation (Fig. 1). The termination of afterdischargewas heralded by two physiological events: (1) large amplitude,slow potential drifts in the extracellular space and (2) the emergenceof a low amplitude, fast (40-90 Hz) field oscillation (Figs. 1,2, 3). Because the large extracellular DC shifts, recorded withglass electrodes (see below), were an order of magnitude largerthan the amplitude of the fast oscillations, simultaneous recordingof the two events with reliable amplitude resolution of the fieldoscillation and without exceeding the 12-bit resolution of theanalog-digital converter was not always possible. Therefore, inthe freely moving rat we studied the slow potential changes withslow time constant (0.03 and 0.1 sec) filter settings and lessamplification. The two events could be recorded simultaneouslyby using faster time constants (0.3 or 1 Hz) and thereby compromisingthe accuracy of the amplitude measurement of the slow potential(Fig. 1). Although in these records the magnitude of the DC shift-associatedchange could not be interpreted, the onset of the DC potentialsin the various layers still could be recognized precisely.
Fig. 2. Sustained potentials associated with afterdischarge termination. A, Sixteen-site recording of an afterdischarge in the CA1-dentategyrus axis in the awake rat. The early part of the pAD is omitted(see example in Fig. 1) to provide a better time resolution. Arrowsabove traces indicate the onset of large DC shifts recorded byAC-coupled amplifiers (0.1-200 Hz). ATO is not visible at thismagnification and low sampling rate (200 Hz). The propagationspeed of the DC front was 0.28 mm/sec in the CA1 region (openarrows) and 0.12 mm/sec in the dentate gyrus (filled arrows).Asterisk, A second wave of DC shift in the absence of neuronalactivity. B, Evoked potentials in response to perforant path stimulationat the same recording position as A. C, Silicon probe in situat its final recording position as seen during vibratome sectioning(different depth from A and B). D, The same section as shown inC after Nissl staining. Recording sites during the afterdischargeshown in A are marked by 1 to 16. The exact recording positionof each site is determined from the laminar profile of the evokedpotentials (B). o, CA1 stratum oriens; p, CA1 pyramidal layer;r, stratum radiatum; hf, hippocampal fissure; m, molecular layer;g, granule cell layer; h, hilus.
[View Larger Version of this Image (67K GIF file)]

Fig. 3. ATO and associated sustained potentials in the CA1 region. Only the end of the primary afterdischarge, induced by COM stimulation,is shown. Traces 1 to 6 are CSD derivatives of band-passed filteredEEG traces (0.3 Hz to 2 kHz). Note the onset of the sustainedpotential in stratum lacunosum-moleculare and its slow (0.15 mm/sec)spread toward the pyramidal layer (open arrows). Strata pyramidaleand oriens were invaded after a 3 sec delay (filled arrows). Fastsinks of ATO waves are largest in the pyramidal layer, surroundedby sources in the strata radiatum and oriens. o, CA1 stratum oriens;p, CA1 pyramidal layer; r, stratum radiatum; lm, stratum lacunosum-moleculare.
[View Larger Version of this Image (17K GIF file)]

Sustained potentials Sustained (DC) potential shifts, typically associated with increases of [K⁺]_o, often have been observed during electrically or chemicallyinduced afterdischarges (Fertziger and Ranck, 1970; Heinemannet al., 1977; Somjen et al., 1985; Somjen and Giacchino 1985;Korn et al., 1987; Stringer et al., 1991; Wadman et al., 1992),as well as in human epileptic seizures (Ikeda et al., 1996). Inagreement with previous studies in anesthetized animals (Somjenet al., 1985; Stringer et al., 1991; Wadman et al., 1992), DCshifts were present during pAD, as indicated by the large negativepolarity slow waves (<0.5 Hz) in the AC-coupled records. In contrastto these relatively low amplitude slow potentials (<5 mV), terminationof pAD was associated with a large amplitude (5-15 mV) negativeshift of the baseline when using 0.03 or 0.1 Hz time contant.Figure 2 illustrates the terminal part of the pAD recorded at16 sites in the CA1 dentate gyrus axis. The DC change, associatedwith the end of the afterdischarge in the CA1 region, occurredfirst in the apical dendritic layers, typically at the level ofthe distal dendrites, i.e., around the hippocampal fissure (Fig.2A, electrode 8). The front of the DC shift (i.e., the negativepeak of the AC-coupled slow wave) moved toward the CA1 pyramidalcell layer at a velocity of 0.1-0.2 mm/sec, as calculated fromthe time difference between the negative peaks of the slow wavesand the distance between the recording sites in this and otheranimals (n = 37 afterdischarges in 9 rats). The wave sometimesfailed to propagate across the cell body layers or was delayedby 3-5 sec before invading the pyramidal layer and stratum oriens(Fig. 3, black arrows). In several cases, the DC potential crossedthe hippocampal fissure and moved toward the granule cell layerat the same propagation velocity as in the CA1 stratum radiatum.In the dentate gyrus/CA3c area, termination of local afterdischargewas similarly associated with a large DC shift, after which theEEG activity became isoelectric (Fig. 2A). Occasionally, the afterdischargetermination DC wave was followed by another sustained potentialshift of smaller amplitude 20-40 sec later.

In a few cases, tetanic stimulation of either the COM or PP path elicited only a short-lived (<5 sec) afterdischarge. In thesecases, the fast oscillation and the associated slow potentialshift were not observed. Instead, the abbreviated afterdischargeterminated simultaneously at all recording sites, and baselineactivity returned quickly without a noticeable postictal depressionperiod. The termination of these "aborted" afterdischarges isnot considered further because they do not represent "full-blown"epileptic activity (McNamara, 1994) and they are not able to induceeither "kindling" or status epilepticus (Goddard et al., 1969;Racine et al., 1972; Lothman and Williamson, 1993). Full-blownafterdischarges were "all-or-none" in nature because their patternand duration after the first few elicitations were quite similar(Leung, 1987; Buzsáki et al., 1989b).
Afterdischarge termination oscillation (ATO) The onset of the DC potential shift in the dendritic layers coincided with the development of a short-lived (1-3 sec) lowamplitude, fast (40-80 Hz) field oscillation (Figs. 3, 4). Becauseof its relatively small amplitude (0.5-4 mV in the cell body layers),the field oscillation became apparent only at higher amplificationof the EEG signal. We termed this low-amplitude fast rhythm afterdischargetermination oscillation (ATO). The ATO was first observable inthe CA1 region. Initially, the fast waves of the ATO were interspersedbetween the large population spikes of the late part of pAD. Theoscillatory waves were of opposite polarity across the pyramidalcell layer. The amplitude of the fast oscillatory waves and associatedpopulation spikes varied in a waxing/waning pattern, giving a"spindle" appearance at a slower recording speed (Fig. 4).
Fig. 4. ATO in different hippocampal regions. A, CSD traces of ATO (1-2000 Hz) in the CA1 region. o, Stratum oriens; p, pyramidallayer; r, stratum radiatum. Open and filled arrowheads indicateslow upward movement of the sources and sinks, respectively. Sinksare up. B, CSD trace in the granule cell layer. C, CSD trace inthe CA3c pyramidal layer. The ATOs shown in CA1 (A), granule celllayer (B), and CA3 pyramidal layer (C) occurred 19, 25, and 41sec after afterdischarge onset in the same rat, respectively.The expanded sweeps reveal the fast field oscillations with andwithout population spikes. Histograms, autocorrelograms of ATO.
[View Larger Version of this Image (35K GIF file)]

CSD analysis revealed that the ATO emerged in the stratum radiatum and moved slowly (0.1-0.2 mm/sec) toward the cell bodylayer (Fig. 4A). In the pyramidal layer, the negative peaks ofthe fast waves were associated with population spikes of 0.5-3mV in amplitude. In the CSD records, the large rhythmic sinksin the pyramidal layer were coupled to corresponding sources inthe stratum radiatum (Figs. 3, 4). Occasionally, rhythmic sourcesin the stratum radiatum were disproportionally larger than thesurrounding sinks in the vertical plane. We assume that in suchcases the sources reflected passive return currents for activesinks generated rostrally or caudally from the recording site.

ATOs were also observed in the granule cell layer and in the CA3 pyramidal layer (Fig. 4B,C). ATO emerged significantly laterin these regions, in accordance with their longer duration ofpAD (Bragin et al., 1996). The shape, duration, and frequencyof ATO in these regions were similar to that described in theCA1 pyramidal cell layer. Whereas ATO was always present in theCA1 region, it was observed in only 50 and 30% of afterdischargesin the CA3 and dentate regions, respectively.

The propagation speed of ATO in the septohippocampal direction was examined in animals equipped with 6-shank probes (300 µmintershank intervals) implanted parallel to the long axis of thehippocampus. Three to four of the six shanks could often be insertedinto the cell body layer at the same depth. Figure 5, A and B,illustrates slowly migrating ATOs in the CA1 region and dentatehilar area of the same rat, respectively. From the distances ofthe recording tips and the time differences of the peaks of theATOs envelopes, the propagation of ATO in the longitudinal directionvaried from 0.1 to 0.18 mm/sec (n = 3 rats).
Fig. 5. Longitudinal spread of the ATO in the CA1 region (A) and dentate hilar region (B). A, Simultaneous recordings from four shanksin the pyramidal layer (voltage traces). Population spikes areclipped. B, Simultaneous recordings from four hilar sites. C,Approximate recording sites in the CA1 region (white arrows) andhilar region (black arrows) indicated on a section cut parallelto the septotemporal axis of the hippocampus. D, Evoked potentialsin the hilar region in response to perforant path stimulation.Note slow spread of ATO (0.1 mm/sec in CA1; 0.2 mm/sec in hilus)in the temporoseptal direction (A, B) but synchronously occurringevoked population spikes (D). p, Pyramidal layer; g, granule celllayer.
[View Larger Version of this Image (72K GIF file)]

Unit activity in awake animals
Isolated neurons with >5 Hz spontaneous discharge frequency, and with repetitive spikes in response to either PP or COM stimulation,were classified as putative interneurons, whereas slow firingcells with occasional complex spike bursts were identified aspyramidal cells (Fox and Ranck, 1981; Buzsáki et al., 1983).Discharge of all isolated pyramidal cells (n = 7) was phase lockedto the negative component of ATO, typically in an intermittentfashion. When population spike components, riding on ATO, grewsubstantially, separation of single cells became impossible. Multipleunit discharges of pyramidal cells, however, continued to dischargeon the negative peaks of the local fast waves. Four putative interneuronswere encountered in the CA1 pyramidal cell layer and 21 interneuronsin the hilar region. Eighteen of the hilar cells underwent a substantialamplitude decrease and stopped discharging altogether before thepopulation spike burst phase of the pAD (Bragin et al., 1996).The firing frequency of the remaining CA1 and hilar interneuronsalso decreased substantially during the population spike phaseof the pAD, and only a single CA1 interneuron continued to dischargeduring ATO (Fig. 6). On the waxing part of the ATO, this cellfired on the negative peaks of the local oscillatory waves. However,even this neuron ceased to fire after population spikes beganto dominate the ATO. These observations suggest that interneuronsdo not play a significant role in the generation of ATO.
Fig. 6. Interneuronal activity during the ATO. Top trace, Voltage trace recorded from the CA1 pyramidal layer (wide band; 1 Hz to5 kHz). Negative peaks were clipped. Arrow, Slow wave reflectingthe onset of the extracellular DC shift. Shorter epochs of thewide band trace (middle) and their high-pass-filtered (0.5-5 kHz;bottom) derivatives are shown at faster speed below. Note relativelyrhythmic firing of the interneuron at the beginning of ATO (left)and its complete silence on the waning phase (right).
[View Larger Version of this Image (53K GIF file)]

Intracellular observations
The pattern of pAD was somewhat different under deep anesthesia, and significantly larger current intensities and longer trainswere required to induce afterdischarges than in the drug-freerat (Bowyer and Winters, 1981; Somjen et al., 1985; Stringer etal., 1991; Wadman et al., 1992). Long duration pADs with repetitivepopulation bursts, comparable to those in the awake animal, wererarely observed. The more frequently elicited brief afterdischargesterminated abruptly and the EEG returned to its baseline patternin 5-10 sec. ATO was observed only when long lasting afterdischarges(>15 sec) were induced.

Intracellular recordings from CA1 pyramidal cells (n = 6) revealed a large depolarization of the soma membrane ( $-$ 40 to $-$ 20mV) during COM stimulation. Neuronal discharge resumed only afterthe cell membrane became sufficiently repolarized. Spike burstsand single spikes occurred in conjunction with the populationbursts recorded by the extracellular metal electrode (Fig. 7A).Intracellularly, ATO was associated with a subthreshold oscillationof the membrane potential (Fig. 7B). Small amplitude depolarizingwaves at the ATO frequency were observed at various voltage levelsof the membrane. As the soma became more depolarized, action potentialsemanated from the depolarizing peaks of the fast oscillatory waves.After a series of fast action potentials, the membrane potentialsuddenly depolarized to between $-$ 30 and $-$ 10 mV, signaling theend of the extracellular ATO. When the extracellular electrodewas placed close (<0.5 mm) to the intracellular pipette, the intracellularoscillation and extracellular ATO occurred virtually simultaneously,and the large depolarization shift intracellularly coincided withthe waning phase of the extracellular ATO and a slow potentialchange in the extracellular AC-coupled trace (Fig. 7A). With largerinterelectrode distances, the intracellular fast action potentialburst and the associated large membrane depolarization could eitherfollow (Fig. 8) or precede the extracellular ATO. In some cases,the first depolarization shift was followed by another depolarizationwave, and the membrane potential returned to the baseline onlyafter several minutes (Fig. 8). In summary, the intracellularexperiments revealed fast membrane oscillation and spiking inassociation with the extracellular ATO. The onset of the sustainedpotential changes in the extracellular milieu corresponded toa large intracellular depolarization of pyramidal cells and aconsequent block of their firing. Recordings with extracellularglass pipettes in the pyramidal layer confirmed that the AC-recordedslow potential and the intracellularly recorded large depolarizationat the end of the afterdischarge corresponded to a large (10-20mV) negative DC shift (see also Somjen et al., 1985).
Fig. 7. Intracellular correlates of the ATO and sustained potential shift in a CA1 pyramidal neuron. A, COM-induced afterdischargein the urethane anesthetized rat recorded intracellularly (toptrace) and field activity (bottom trace) recorded <0.5 mm posteriorto the micropipette. Thirty seconds are omitted between traces(30 s). Note fast spike burst and depolarization block of thecell and associated with extracellular ATO and the onset of theextracellular DC potential shift (arrow above field trace). Extracellulartrace was wide-band-filtered (1 Hz to 5 kHz). Resting membranepotential was restored after 102 sec (last trace segment). B,Details of records in A (arrows) at faster speed. Note fast depolarizingpotentials and action potentials during ATO. C, Depolarizationblock could be mimicked by extracellular injection of KCl. Recoveryoccurred after 192 sec. In other experiments, KCl induced fastfield oscillations (ATO) and a 5-30 mV negative DC shift in thepyramidal cell layer (not shown).
[View Larger Version of this Image (32K GIF file)]

Fig. 8. Intracellular correlates of the ATO in a pyramidal neuron at the CA1-subicular border. COM-induced afterdischarge recordedintracellularly (upper trace) and field activity (bottom trace)recorded ~1 mm posterior to the micropipette in the CA1 pyramidallayer. Ten seconds (10 s) were omitted between the traces. Notefast membrane oscillation (open triangle), spike burst, and largedepolarization ~10 sec after the onset of the extracellular ATO(black triangle). Note also a secondary depolarization wave (doublearrow). Whereas actions potentials reoccurred on the descendingpart of the first depolarization wave, only a single action potentialwas observed on the falling phase of the second wave. The extracellulartrace was wide-band-filtered (1 Hz to 5 kHz). Arrow above fieldtrace, Slow wave indicating the beginning of extracellular DCpotential shift.
[View Larger Version of this Image (32K GIF file)]

The afterdischarge-induced ATO and intracellular depolarization could be mimicked by extracellular injection of KCl into theCA1 stratum radiatum (n = 5 cells; Fig. 7C). The frequency andshape of the extracellularly recorded fast oscillation were identicalto those studied by Herreras et al. (1994) in detail (not shown).The speed and magnitude of the intracellular depolarization weresimilar to the afterdischarge-induced changes. The propagationvelocity of the KCl-induced DC shift, calculated from the timedifference between the onset of the sustained potential at theKCl-containing pipette and the onset of the large intracellulardepolarization and the distance between the extracellular andintracellular electrodes, was 0.1-0.2 mm/sec. Furthermore, extracellularrecordings with glass micropipettes had shown that the magnitudeof the KCl-induced DC shift in the extacellular space (5-20 mV)was similar to that observed during electrical stimulation-inducedafterdischarges associated with ATO.

DISCUSSION
The principal findings of the present experiments are that termination of primary afterdischarge in vivo is associated withthe occurrence of a large DC shift in the dendritic layers andfast field oscillation in the cell body layers. These pathophysiologicalevents spread at a very low speed in the three-dimensional spaceof the hippocampus. In intracellular recordings, these changescorrelated with a large depolarization and fast discharge of CA1pyramidal neurons. The findings suggest that stimulation-inducedafterdischarges are terminated by a depolarization blockade ofprincipal cells.

ATO
Fast field oscillations in the gamma frequency range (40-100 Hz) have been described in association with hippocampal thetaactivity after entorhinal cortex lesion and in the recovery phaseof induced afterdischarges (Stumpf, 1965; Leung, 1982; Buzsákiet al., 1983; Bragin et al., 1995b; Charpak et al., 1995). Thetheta-associated gamma oscillation is believed to reflect rhythmichyperpolarization of the pyramidal cell membrane as a result ofa network oscillation of basket interneurons (Buzsáki et al.,1983; Soltész and Dechenes, 1993; Bragin et al., 1995; Whittingtonet al., 1995; Traub et al., 1996; Wang and Buzsáki, 1996). Theafterdischarge-induced late oscillation (Leung, 1987) and thegamma pattern induced by entorhinal cortex lesion (Bragin et al.,1995b) emerge in the CA3 region and are transferred to the CA1region by the Schaffer collaterals (G. Buzsáki and A. Bragin,unpublished observations). Although the frequency of ATO is similarto these gamma patterns, several observations suggest that itsmechanism may be distinct.

A major difference between ATO and the naturally present, theta-associated gamma rhythm is the absence of interneuron-mediatedinhibition in ATO. In our sample, all but one interneuron ceaseddischarging before the occurrence of ATO, and none of them firedduring the waning part of the ATO spindle. Although it is possiblethat we failed to record from a critical group of interneuronsresponsible for the maintenance of ATO, several findings argueagainst such a possibility. First, pyramidal cells and the recordedinterneurons fired on the same negative peaks of the ATO waves.Second, the field rhythm was associated with depolarizing potentialsrather than IPSPs. Third, in accord with the intrasomatic events,CSD analysis of ATO revealed large sinks (inward currents), ratherthan sources, in the pyramidal cell layer. The somatic sinks duringATO could be regarded as "active" because they were associatedwith discharges of neurons both in the extracellular experimentsin awake rats and in the intracellular experiments in anesthetizedanimal. In contrast, the physiological gamma pattern is characterizedby rhythmic sources in the cell body layer (Bragin et al., 1995b).

ATO is also different from lesion-induced gamma oscillations (Bragin et al., 1995b) or from the fast EEG pattern that occursduring the late recovery part of an afterdischarge (Leung, 1987).These rhythms are generated in the CA3 region and transferredto the CA1 region by the Schaffer collaterals, as reflected bya sink source dipole in the strata radiatum and pyramidale, respectively.This dipole pattern is quite different from the sink source distributionassociated with ATO. Most important, ATO occurred in the CA1 regionin the absence of a concurrent gamma frequency rhythm in the CA3area.

Intracellularly, the oscillatory waves corresponded to depolarizations from which action potentials emanated. In principle,the depolarizing potentials may correspond to EPSPs brought aboutby the very sparse recurrent excitatory collaterals among CA1pyramidal cells themselves (Christian and Dudek, 1988; Radpourand Thomson, 1991; Klishin et al., 1995). Because the sparse recurrentcollaterals terminate in the basal dendrites (Deuchars and Thomson,1996), an active sink would be expected in this layer rather thanin the pyramidal layer. Generation of ATO by the local recurrentcollaterals is not supported by previous findings either. Fieldoscillation and intracellular membrane potential changes, virtuallyidentical to ATO, could be provoked by extracellular potassiuminjection, confirming previous observations (Herreras et al.,1994). It is important to note that, in the experiments of Herreraset al. (1994), the fast field oscillation and the accompanyingspreading depression were not prevented by blocking all synapticactivity with divalent cations. Ephaptic (transmembrane) effectsmay be a candidate mechanism for neuronal synchronization (Jefferysand Haas, 1982; Taylor and Dudek, 1982). Indeed, during the peakof the ATO spindle the voltage gradient across the cell body layersexceeded 15-25 mV/mm, a value sufficient to affect the excitabilityof pyramidal cells in vitro (Jefferys, 1981). Yet another possibilityis that the field ATO does not reflect true synchrony of pyramidalcells. Instead, the transiently increased number of dischargingpyramidal cells at similar frequencies may result in a spuriousfield rhythm even when they fire randomly (Wang and Buzsáki,1996).

Termination of primary afterdischarge by spreading depolarization
Several features of the sustained potentials, associated with the termination of pAD, were identical with those of spreadingdepression (Leao, 1944). The sustained potential after the pADwas invariably initiated in the dendritic layers, around the hippocampalfissure. The front of the wave traveled very slowly (0.1-0.2 mm/sec)in all directions, regardless of the anatomical connections ofneurons. The wave spread toward the CA1 pyramidal layer and granulecell layer, as well as in the longitudinal axis, with a similarspeed. Pyramidal cells discharged at a high frequency and timelocked to the local extracellular ATO. It has been suggested thatKCl-induced fast oscillation and spreading depression is broughtabout by opening of gap junctions among principal cells (Czéhet al., 1993; Herreras and Somjen, 1993; Herreras et al., 1994).However, gap junctions have not yet been identified among pyramidalcells in the adult hippocampus (Katsumaru et al., 1988; Penttonenet al., 1995; T. F. Freund and P. Somogyi, personal communication).It is possible that epileptic afterdischarges and the resultingchanges in the extracellular/intracellular milieu (Green, 1964;Pedley et al., 1976; Korn et al., 1987; Haglund and Schwartzkroin,1990) create favorable conditions for a rapid de novo formationof gap junctions among pyramidal neurons (Perez-Velazquez et al.,1994; Penttonen et al., 1995). Such possibility, however, hasyet to be demonstrated.

Depolarization-induced blockade of neuronal activity was not directly demonstrated in awake animals but was only inferredfrom the lack of neuronal activity after ATO. Excitability testsin response to single pulse stimulation of hippocampal afferents/efferentsprovide indirect support for the depolarization blockade hypothesis,however. Single pulses, capable of inducing large amplitude (>5mV) orthodromic or antidromic population spikes before the afterdischarge,failed to induce any responses after the ATO (A. Bragin and G.Buzsáki, unpublished observations). A parsimonious explanationof the response failure is the loss of input resistance as a resultof severe depolarization (Haglund and Schwartzkroin, 1984).

Comparisons with previous studies
The large DC shift and the associated ATO were consistent and integral parts of the stimulation-evoked afterdischarge in awakerats. This is in apparent contrast to the lack of previous observationsof these events in the numerous reports using in vivo and in vitroepilepsy models. Several differences between those experimentsand the present investigation might account for this discrepancy.First, electrical activity in awake animals has been recordedtypically with electrodes the diameter of which is larger thanthe width of the CA1 pyramidal layer (60 µm); therefore, the ATOsmay have been shunted even if the electrode was positioned inthe layer. The sustained potentials were eliminated by high-passfilters or regarded as movement artifacts. Second, the durationand intensity of population bursts during pAD may not be sufficientto induce these changes under anesthesia (Somjen et al., 1985;Stringer et al., 1991). Third, the short duration of the afterdischargesin in vitro models may offer a similar explanation for the lackof an ATO in these models. Finally, continuous perfusion of theslice may prevent excessive accumulation of [K⁺]_o and/or glutamate responsible for the depolarization of neurons.

These caveats notwithstanding, both DC shifts and ATO can be recognized in several published reports (Somjen and Giacchino,1985; Somjen et al., 1985; Leung, 1987; Stringer et al., 1991).After long afterdischarges (>10 sec), ATO coincided with "an episodeof Leao's depression" in urethane-anesthetized rats (Fig. 2 inSomjen et al., 1985), during which [K⁺]_o reached 40 mM (Fig. 1 in Somjen and Giacchino, 1985). Whenthe duration of the afterdischarge was prolonged by repeated stimulation,spreading depression often blocked electrical activity in anesthetized,paralyzed rats (Wadman et al., 1992). Finally, depolarizationblockade of spike discharge has been observed in vitro as well(Haglund and Schwartzkroin, 1984; Psarropoulou and Avoli, 1993;Gloveli et al., 1995; R. Dingledine and N. Lambert, personal communication).

Neuron-glia communication and afterdischarge termination: a hypothesis
The origin of ATO in the distal dendritic layers, the very slow spread of the associated sustained potential shift acrossthe principal cell layers, and its similar propagation speed inall regions of the hippocampus suggest the involvement of theglial network. This contention is strongly supported by the occurrenceof secondary slow potentials during the postictal depression periodin the absence of neuronal activity. The importance of the intimaterelationship between glia and neurons in the hyperexcitable tissuehas long been recognized (Traynelis and Dingledine, 1988; Haglundand Schwartzkroin, 1990). Astrocytes are known to form a quasisyncytiumvia multiple gap junctions, and their density is lower in thepyramidal and granule cell layers (Takato and Goldring, 1979;Ransom, 1995). Neuronal activity-associated release of K⁺ and/or glutamate can induce propagating Ca²⁺ waves in astrocyte cultures (MacVicar, 1984; Cornell-Bell etal., 1990; Dani et al., 1992) at a speed identical to spreadingdepression and the propagation velocity of ATO. Intercellularcoupling through gap junctions is required for both propagatingCa²⁺ waves and spreading depression (Martins-Ferreira and Ribeiro,1995; Nedergaard et al., 1995). The traveling Ca²⁺ waves, in turn, can trigger calcium influx into neurons (Nedergaard,1994; Parpura et al., 1994; Nedergaard et al., 1995). We hypothesizethat a similar glia-neuron dialogue in vivo may be responsiblefor the induction of ATO and depolarization blockade of principalcells (Fertziger and Ranck, 1970; Sypert and Ward, 1971; Leao,1972; Heinemann et al., 1977; Haglund and Schwartzkroin, 1984).The increased [K⁺]_o, resulting from intensive neuronal activity during the pAD,may trigger propagating waves in the astrocytic network reflectedby the slowly spreading sustained potentials. In turn, astrocytesat the front of the propagating depolarization wave release morepotassium (Kuffler and Nicholls, 1966; Quandt and MacVicar, 1986),resulting in a large depolarization of neurons. The ensuing depolarizationblock of spike generation contributes to the termination of theafterdischarge and is regarded as the cause of the consequentpostictal depression of the EEG (Sypert and Ward, 1971). The invitro observation that the CA1 area has the least effective Na⁺-K⁺ pump and the highest susceptibility to spreading depression (Haglundand Schwartzkroin, 1990; Schweitzer et al., 1992) may explainwhy afterdischarges always terminate in this hippocampal region.

From the above perspective, the DC potential shift and the ATO reflect depolarization of the glial network and neuronal population,respectively. The depolarization wave of the glial syncytium isthus both a prerequisite and cause of ATO. In summary, interactionbetween the glial syncytium and neuronal population seems criticalfor the termination of stimulation-induced afterdischarges inthe intact brain. It remains to be established whether the pAD $right-arrow$ DCwave $right-arrow$ ATO $right-arrow$ afterdischarge sequence reflects causal relationshipsand whether ATO and the associated depolarization block of neuronsare present in other in vivo seizure models as well.

FOOTNOTES

Received Nov. 4, 1996; revised Dec. 20, 1996; accepted Jan. 10, 1997.

This work was supported by National Institute of Neurological Diseases and Stroke Grants NS34994 and 1P41RR09754, Human FrontierScience Foundation, the Whitehall Foundation, and the FinnishAcademy of Sciences (M.P.). We thank K. Wise and J. Hetke formanufacturing silicon probes; J. J. Chrobak, J. Csicsvari, S.L.-W. Leung, M. Page, G. G. Somjen, and R. D. Traub for theircomments on an earlier version of this manuscript; and D. J. Dingledine,N. A. Lambert, P. A. Schwartzkoin, and W. Wilson for advice.

Correspondence should be addressed to Dr. György Buzsáki, Center for Molecular and Behavioral Neuroscience, Rutgers University,197 University Avenue, Newark, NJ 07102.

Dr. Bragin's permanent address: Institute of Theoretical and Experimental Biophysics, Puschino, Russia.

Dr. Penttonen's present address: A. I. Virtanen Institute, University of Kuopio, FIN-70211 Kuopio, Finland.

REFERENCES

Amaral D, Witter M (1989) The three-dimensional organization of the hippocampal formation: a review of anatomical data. Neuroscience 31:571-591 . [Web of Science][Medline]
Bowyer JF, Winters WD (1981) The effects of various anesthetics on amygdaloid kindled seizures. Neuropharmacology 20:199-209 . [Web of Science][Medline]
Bragin A, Jandó G, Nádasdy Z, Hetke J, Wise K, Buzsáki G (1995) Gamma (40-100 Hz) oscillation in the hippocampus of the behaving rat. J Neurosci 15:47-60 . [Abstract]
Bragin A, Csicsvary J, Penttonen M, Buzsáki G (1997) Epileptic afterdischarge in the hippocampal-entorhinal system: current source density and unit studies. Neuroscience 76:1187-1203 . [Web of Science][Medline]
Buzsáki G, Leung L, Vanderwolf CH (1983) Cellular bases of hippocampal EEG in the behaving rat. Brain Res Rev 6:139-171.
Buzsáki G, Bickford RG, Ryan LJ, Young S, Prohaska O, Mandel RJ, Gage FH (1989a) Multisite recording of brain field potentials and unit activity in freely moving rats. J Neurosci Methods 28:209-217 . [Web of Science][Medline]
Buzsáki G, Ponomareff LG, Bayardo F, Ruiz R, Gage FH (1989b) Neuronal activity in the subcortically denervated hippocampus: a chronic model for epilepsy. Neuroscience 28:527-538 . [Web of Science][Medline]
Charpak S, Pare D, Llinás RR (1995) The entorhinal cortex entrains fast CA1 hippocampal oscillations in the anesthetized guinea pig: role of the monosynaptic component of the perforant path. Eur J Neurosci 7:1548-1557 . [Web of Science][Medline]
Christian EP, Dudek FE (1988) Electrophysiological evidence from glutamate microapplications for local excitatory circuits in the CA1 area of rat hippocampal slices. J Neurophysiol 59:110-123 . [Abstract/Free Full Text]
Cornell-Bell AH, Finkbeiner SM, Cooper MS, Smith SJ (1990) Glutamate induces calcium waves in culture astrocytes: long-range glial signaling. Science 247:470-473 . [Abstract/Free Full Text]
Czéh G, Aitken PG, Somjen GG (1993) Membrane currents in CA1 pyramidal cells during spreading depression (SD) and SD-like hypoxic depolarization. Brain Res 632:195-208 . [Web of Science][Medline]
Dani JW, Chernjavsky A, Smith SJ (1992) Neuronal activity triggers calcium waves in hippocampal astrocyte networks. Neuron 8:429-440 . [Web of Science][Medline]
Deuchars J, Thomson AM (1996) CA1 pyramid-pyramid connections in rat hippocampus in vivo: dual recordings with biocytin filling. Neuroscience 74:1009-1018 . [Web of Science][Medline]
Engel Jr J (1989) In: Seizures and epilepsy. Philadelphia: Davis.
Fertziger AP, Ranck Jr JB (1970) Potassium accumulation in interstitial space during epileptiform seizures. Exp Neurol 26:209-218.
Fox SE, Ranck Jr JB (1981) Electrophysiological characteristics of hippocampal complex-spike cells and theta cells. Exp Brain Res 41:299-313.
Freeman JA, Nicholson C (1975) Experimental optimization of current source-density technique for anuran cerebellum. J Neurophysiol 38:369-382 . [Abstract/Free Full Text]
Gloor P, Vera CL, Sperti L, Ray SN (1961) Investigation of the mechanism of epileptic discharge in the hippocampus. Epilepsia 2:42-62. [Web of Science][Medline]
Gloveli T, Albrecht D, Heinemann U (1995) Properties of low Mg²⁺ induced epileptiform activity in rat hippocampal and entorhinal cortex slices during adolescence. Dev Brain Res 87:145-52 . [Medline]
Goddard GV, McIntyre DC, Leech CK (1969) A permanent change in brain functioning resulting from daily electrical stimulation. Exp Neurol 25:293-330.
Green JD (1964) The hippocampus. Physiol Rev 44:501-531.
Haglund MM, Schwartzkroin PA (1984) Seizure-like spreading depression in immature rabbit hippocampus in vitro. Dev Brain Res 14:51-59.
Haglund MM, Schwartzkroin PA (1990) Role of Na-K pump potassium regulation and IPSPs in seizures and spreading depression in immature rabbit hippocampal slices. J Neurophysiol 63:225-239 . [Abstract/Free Full Text]
Heinemann U, Lux HD, Gutnick MJ (1977) Extracellular free calcium and potassium during paroxysmal activity in cerebral cortex of the cat. Exp Brain Res 27:237-243 . [Web of Science][Medline]
Heinemann Um Eder C, Lass A (1995) Epilepsy. In: Neuroglia (Ketterman H, Ransom BR, eds), pp 936-949. New York: Oxford UP.
Herreras O, Somjen GG (1993) Propagation of spreading depression among dendrites and somata of the same cell population. Brain Res 610:276-282 . [Web of Science][Medline]
Herreras O, Largo C, Ibarz JM, Somjen GG, Martin del Rio R (1994) Role of neuronal synchronizing mechanisms in the propagation of spreading depression in the in vivo hippocampus. J Neurosci 14:7087-7098 . [Abstract]
Holsheimer J (1987) Electrical conductivity of the hippocampal CA1 layers and application to current source density analysis. Exp Brain Res 67:402-410 . [Web of Science][Medline]
Ikeda A, Terada K, Mikuni N, Burgess RC, Comair Y, Taki W, Hamano T, Kimura J, Lüders HO, Shibasaki H (1996) Subdural recording of ictal DC shifts in neocortical seizures in humans. Epilepsia 37:662-674 . [Web of Science][Medline]
Jefferys JGR (1981) Influence of electric fields on the excitability of granule cells in guinea pig hippocampal slices. J Physiol (Lond) 319:143-152. [Abstract/Free Full Text]
Jefferys JGR, Haas HL (1982) Synchronized bursting of CA1 hippocampal pyramidal cells in the absence of synaptic transmission. Nature 300:448-450. [Medline]
Katsumaru H, Kosaka T, Heizman CW, Hama K (1988) Gap junctions on GABAergic neurons containing the calcium-binding protein parvalbumin in the rat hippocampus (CA1 regions). Exp Brain Res 72:363-370 . [Web of Science][Medline]
Korn SJ, Giacchino JL, Chamberlin NL, Dingledine R (1987) Epileptiform burst activity induced by potassium in the hippocampus and its regulation by GABA-mediated inhibition. J Neurophysiol 57:325-340 . [Abstract/Free Full Text]
Klishin A, Tsintsadze T, Lozovaya N, Krishtal O (1995) Latent N-methyl-D-aspartate receptors in the recurrent excitatory pathway between hippocampal CA1 pyramidal neurons: Ca²⁺-dependent activation by blocking A1 adenosine receptors. Proc Natl Acad Sci USA 92:12431-12435 . [Abstract/Free Full Text]
Kuffler SW, Nicholls JG (1966) Neuroglial cells: physiological properties and potassium mediated effect of neuronal activity on the glial membrane potential. Proc R Soc Lond [Biol] 168:1-21.
Leao AAP (1944) Spreading depression of activity in the cerebral cortex. J Neurophysiol 7:359-390. [Free Full Text]
Leao AAP (1972) Spreading depression. In: Experimental models of epilepsy: a manual for the laboratory worker (Purpura DP, Penry JK, Tower DB, Woodbury DM, Walter RD, eds), pp 174-196. New York: Raven.
Leung LS (1979) Potentials evoked by the alvear tract in hippocampal CA1 of rats. II. Spatial field analysis. J Neurophysiol 42:1571-1589. [Free Full Text]
Leung LS (1987) Hippocampal electrical activity following local tetanization. I. Afterdischarges. Brain Res 419:173-187. [Web of Science][Medline]
Leung LS (1982) Nonlinear feedback model of neuronal populations in hippocampal CA1 region. J Neurophysiol 47:845-868 . [Abstract/Free Full Text]
Li X-G, Somogyi P, Ylinen A, Buzsáki G (1994) The hippocampal CA3 network: an in vivo intracellular labeling study. J Comp Neurol 339:181-208 . [Web of Science][Medline]
Liberson WT, Cadilhac J (1953) Further observations on DC potentials during electrically induced seizure discharge activity in guinea pig. Electroencephalogr Clin Neurophysiol 5:320-324.
Lothman EW, Williamson JM (1993) Rapid kindling with recurrent hippocampal seizures. Epilepsy Res 14:209-220 . [Web of Science][Medline]
MacVicar BA (1984) Voltage-dependent calcium channels in glial cells. Science 226:1345-1347 . [Abstract/Free Full Text]
Martins-Ferreira H, Ribeiro LJ (1995) Biphasic effects of gap junctional uncoupling agents on the propagation of retinal spreading depression. Brazil J Med Biol Res 28:991-994 . [Web of Science][Medline]
McNamara JO (1994) Cellular and molecular basis of epilepsy. J Neurosci 14:3413-3425 . [Web of Science][Medline]
Mitzdorf U (1985) Current source-density method and application in cat cerebral cortex: investigation of evoked potentials and EEG phenomena. Physiol Rev 65:37-100 . [Free Full Text]
Mody I (1993) The molecular basis of kindling. Brain Pathol 3:395-403 . [Web of Science][Medline]
Nedergaard M (1994) Direct signaling from astrocytes to neurons in cultures of mammalian brain cells. Science 263:1768-1771 . [Abstract/Free Full Text]
Nedergaard M, Cooper AJ, Goldman SA (1995) Gap junctions are required for the propagation of spreading depression. J Neurobiol 28:433-44 . [Web of Science][Medline]
Parpura V, Basarsky TA, Liu F, Jeftinija K, Jeftinija S, Haydon PG (1994) Glutamate-mediated astrocyte-neuron signalling. Nature 369:744-747 . [Medline]
Pedley TA, Fisher RX, Futamachi KJ, Prince DA (1976) Regulation of extracellular potassium concentration in epileptogenesis. Fed Proc 35:1254-1259 . [Web of Science][Medline]
Penfield W, Jasper H (1954) In: Epilepsy and the functional anatomy of the human brain. Boston: Little & Brown.
Penttonen M, Bragin A, Sik A, Buzsáki G (1995) Dye coupling of neurons in the hippocampus implies a role for gap junctions in epilepsy. Soc Neurosci Abstr 21:1971.
Perez-Velazquez JL, Valiante TA, Carlen PL (1994) Modulation of gap junctional mechanisms during calcium-free induced field burst activity: a possible role for electrotonic coupling in epileptogenesis. J Neurosci 14:4308-4317 . [Abstract]
Psarropoulou C, Avoli M (1993) 4-Aminopyridine-induced spreading depression episodes in immature hippocampus: developmental and pharmacological studies. Neuroscience 55:57-68 . [Web of Science][Medline]
Racine RJ (1972) Modification of seizure activity by electrical stimulation. I. Afterdischarge threshold. Electroencephal Clin Neurophysiol 32:281-294 . [Web of Science][Medline]
Stringer JL, Williamson JM, Lothman EW (1991) Maximal dentate activation is produced by amygdala stimulation in unanesthetized rats. Brain Res 542:336-342 . [Web of Science][Medline]
Quandt FN, MacVicar BA (1986) Calcium activated potassium channels in cultured astrocytes. Neuroscience 19:29-41 . [Web of Science][Medline]
Radpour S, Thomson AM (1991) Coactivation of local circuit NMDA receptor mediated epsps induces lasting enhancement of minimal schaffer collateral EPSPs in slices of rat hipocampus. Eur J Neurosci 3:602-613. [Web of Science][Medline]
Ransom BR (1995) Gap junctions. In: Neuroglia (Ketterman H, Ransom BR, eds). New York: Oxford UP.
Schweitzer JS, Patrylo PR, Dudek FE (1992) Prolonged field bursts in the dentate gyrus: dependence on low calcium, high potassium, and nonsynaptic mechanisms. J Neurophysiol 68:2016-2025 . [Abstract/Free Full Text]
Sik A, Penttonen M, Ylinen A, Buzsáki G (1995) Hippocampal CA1 interneurons: an in vivo intacellular labeling study. J Neurosci 15:6651-6665 . [Abstract/Free Full Text]
Sloviter RS (1983) "Epileptic" brain damage in rats induced by sustained electrical stimulation of the perforant path. I. Acute electrophysiological and light microscopic studies. Brain Res Bull 10:675-697 . [Web of Science][Medline]
Soltész I, Dechenes M (1993) Low and high frequency membrane potential oscillation during $theta$ activity in CA1 and CA3 pyramidal neurons of the rat hippocampus under ketamine-xylazine anesthesia. J Neurophysiol 70:97-116 . [Abstract/Free Full Text]
Somjen GG, Giacchino JL (1985) Potassium and calcium concentrations in interstitial fluid of hippocampal formation during paroxismal discharges. J Neurophysiol 53:1098-1108 . [Abstract/Free Full Text]
Somjen GG, Aitken PG, Giacchino JL, McNamara JO (1985) Sustained potential shifts and paroxysmal discharges in hippocampal formation. J Neurophysiol 53:1079-1097 . [Abstract/Free Full Text]
Stumpf C (1965) Drug action on the electrical activity of the hippocampus. Int Rev Neurobiol 8:77-138 . [Medline]
Sypert GW, Ward AA (1971) Unidentified neuroglia potentials during propagated seizures in the neocortex. Exp Neurol 33:239-255 . [Web of Science][Medline]
Takato M, Goldring S (1979) Intracellular marking with lucifer yellow CH and horseradish peroxidase of cells electrophysiologically characterized as glial in the cerebral cortex of the cat. J Comp Neurol 186:173-188 . [Web of Science][Medline]
Taylor CP, Dudek FE (1982) Synchronous neural afterdischarges in rat hippocampal slices without active chemical synapses. Science 218:810-812 . [Abstract/Free Full Text]
Traynelis SF, Dingledine R (1988) Potassium-induced spontaneous electrographic seizures in the rat hippocampal slice. J Neurophysiol 59:259-276 . [Abstract/Free Full Text]
Wadman WJ, Juta AJA, Kamphuis W, Somjen GG (1992) Current source density analysis of sustained potential shifts associated with electrographic seizures and with spreading depression in rat hippocampus. Brain Res 570:85-91 . [Web of Science][Medline]
Wang X-J, Buzsáki G (1996) Gamma oscillation by synaptic inhibition in an interneuronal network model. J Neurosci 16:6402-6413 . [Abstract/Free Full Text]
Whittington MA, Traub RD, Jefferys JGR (1995) Metabotropic receptor activation drive synchronized 40 Hz oscillations in networks of inhibitory interneurons. Nature 373:612-615 . [Medline]
Ylinen A, Bragin A, Nádasdy Z, Jandó G, Szabó I, Sik A, Buzsáki G (1995) Sharp wave associated high frequency oscillation (200 Hz) in the intact hippocampus: network and intracellular mechanisms. J Neurosci 14:30-46.

Copyright ©1997 Society for Neuroscience   0270-6474/1997/172567-13$05.00/0

This article has been cited by other articles:

Z. Xiao, P.-Y. Deng, C. Yang, and S. Lei
Modulation of GABAergic Transmission by Muscarinic Receptors in the Entorhinal Cortex of Juvenile Rats
J Neurophysiol, August 1, 2009; 102(2): 659 - 669.
[Abstract] [Full Text] [PDF]

A. Bragin, A. Azizyan, J. Almajano, and J. Engel Jr
The Cause of the Imbalance in the Neuronal Network Leading to Seizure Activity Can Be Predicted by the Electrographic Pattern of the Seizure Onset
J. Neurosci., March 18, 2009; 29(11): 3660 - 3671.
[Abstract] [Full Text] [PDF]

M. A. Castro-Alamancos, P. Rigas, and Y. Tawara-Hirata
Resonance (~10 Hz) of excitatory networks in motor cortex: effects of voltage-dependent ion channel blockers
J. Physiol., January 1, 2007; 578(1): 173 - 191.
[Abstract] [Full Text] [PDF]

B. Lasztoczi and J. Kardos
Cyclothiazide Prolongs Low [Mg2+]-Induced Seizure-Like Events
J Neurophysiol, December 1, 2006; 96(6): 3538 - 3544.
[Abstract] [Full Text] [PDF]

J. Ziburkus, J. R. Cressman, E. Barreto, and S. J. Schiff
Interneuron and Pyramidal Cell Interplay During In Vitro Seizure-Like Events
J Neurophysiol, June 1, 2006; 95(6): 3948 - 3954.
[Abstract] [Full Text] [PDF]

D. J. Pinto, S. L. Patrick, W. C. Huang, and B. W. Connors
Initiation, Propagation, and Termination of Epileptiform Activity in Rodent Neocortex In Vitro Involve Distinct Mechanisms
J. Neurosci., September 7, 2005; 25(36): 8131 - 8140.
[Abstract] [Full Text] [PDF]

R. D. Traub, I. Pais, A. Bibbig, F. E.N. LeBeau, E. H. Buhl, H. Garner, H. Monyer, and M. A. Whittington
Transient Depression of Excitatory Synapses on Interneurons Contributes to Epileptiform Bursts During Gamma Oscillations in the Mouse Hippocampal Slice
J Neurophysiol, August 1, 2005; 94(2): 1225 - 1235.
[Abstract] [Full Text] [PDF]

Y. Fujiwara-Tsukamoto, Y. Isomura, K. Kaneda, and M. Takada
Synaptic interactions between pyramidal cells and interneurone subtypes during seizure-like activity in the rat hippocampus
J. Physiol., June 15, 2004; 557(3): 961 - 979.
[Abstract] [Full Text] [PDF]

Z. Feng and D. M. Durand
Low-Calcium Epileptiform Activity in the Hippocampus In Vivo
J Neurophysiol, October 1, 2003; 90(4): 2253 - 2260.
[Abstract] [Full Text] [PDF]

Y. Isomura, Y. Fujiwara-Tsukamoto, and M. Takada
Glutamatergic Propagation of GABAergic Seizure-Like Afterdischarge in the Hippocampus In Vitro
J Neurophysiol, October 1, 2003; 90(4): 2746 - 2751.
[Abstract] [Full Text] [PDF]

M. Bikson, P. J. Hahn, J. E. Fox, and J. G.R. Jefferys
Depolarization Block of Neurons During Maintenance of Electrographic Seizures
J Neurophysiol, October 1, 2003; 90(4): 2402 - 2408.
[Abstract] [Full Text] [PDF]

M. A Castro-Alamancos and P. Rigas
Synchronized oscillations caused by disinhibition in rodent neocortex are generated by recurrent synaptic activity mediated by AMPA receptors
J. Physiol., July 15, 2002; 542(2): 567 - 581.
[Abstract] [Full Text] [PDF]

C. Wu, H. Shen, W. P. Luk, and L. Zhang
A fundamental oscillatory state of isolated rodent hippocampus
J. Physiol., April 15, 2002; 540(2): 509 - 527.
[Abstract] [Full Text] [PDF]

S. K. Towers, F. E. N. LeBeau, T. Gloveli, R. D. Traub, M. A. Whittington, and E. H. Buhl
Fast Network Oscillations in the Rat Dentate Gyrus In Vitro
J Neurophysiol, February 1, 2002; 87(2): 1165 - 1168.
[Abstract] [Full Text] [PDF]

V. Dzhala, I. Khalilov, Y. Ben-Ari, and R. Khazipov
Neuronal mechanisms of the anoxia-induced network oscillations in the rat hippocampus in vitro
J. Physiol., October 15, 2001; 536(2): 521 - 531.
[Abstract] [Full Text] [PDF]

R. K Ellerkmann, V. Riazanski, C. E Elger, B. W Urban, and H. Beck
Slow recovery from inactivation regulates the availability of voltage-dependent Na+ channels in hippocampal granule cells, hilar neurons and basket cells
J. Physiol., April 15, 2001; 532(2): 385 - 397.
[Abstract] [Full Text] [PDF]

M. A. Castro-Alamancos
Origin of Synchronized Oscillations Induced by Neocortical Disinhibition In Vivo
J. Neurosci., December 15, 2000; 20(24): 9195 - 9206.
[Abstract] [Full Text] [PDF]

Z.-Q. Xiong, P. Saggau, and J. L. Stringer
Activity-Dependent Intracellular Acidification Correlates with the Duration of Seizure Activity
J. Neurosci., February 15, 2000; 20(4): 1290 - 1296.
[Abstract] [Full Text] [PDF]

This Article

Abstract

Full Text (PDF)

Submit an eLetter

Alert me when this article is cited

Alert me when eLetters are posted

Alert me if a correction is posted

Citation Map

Services

Email this article to a friend

Similar articles in this journal

Similar articles in Web of Science

Similar articles in PubMed

Alert me to new issues of the journal

Download to citation manager

Citing Articles

Citing Articles via HighWire

Citing Articles via Web of Science (45)

Citing Articles via Google Scholar

Google Scholar

Articles by Bragin, A.

Articles by Buzsáki, G.

Search for Related Content

PubMed

PubMed Citation

Articles by Bragin, A.

Articles by Buzsáki, G.