Sustained Plateau Activity Precedes and Can Generate Ictal-Like Discharges in Low-Cl- Medium in Slices from Rat Piriform Cortex

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The Journal of Neuroscience, December 15, 1999, 19(24):10738-10746

Sustained Plateau Activity Precedes and Can Generate Ictal-Like Discharges in Low-Cl Medium in Slices from Rat Piriform Cortex
Rezan Demir, Lewis B. Haberly, and Meyer B. Jackson
Departments of Physiology and Anatomy and Center for Neuroscience, University of Wisconsin Medical School, Madison, Wisconsin 53706

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Interictal and ictal discharges represent two different forms of abnormal brain activity associated with epilepsy. Ictal dischargesclosely parallel seizure activity, but depending on the form ofepilepsy, interictal discharges may or may not be correlated withthe frequency, severity, and location of seizures. Recent voltage-imagingstudies in slices of piriform cortex indicated that interictal-likedischarges are generated in a two-stage process. The first stageconsists of a sustained, low-amplitude depolarization (plateauactivity) lasting the entire latent period prior to dischargeonset. Plateau activity takes place at a site distinct from thesite of discharge onset and serves to sustain and amplify activityinitiated by an electrical stimulus. In the second stage a rapidlyaccelerating depolarization begins at the onset site and thenspreads over a wide region. Here, we asked whether ictal-likedischarges can be generated in a similar two-stage process. Aswith interictal-like activity, the first sign of an impendingictal-like discharge is a sustained depolarization with a plateau-liketime course. The rapidly accelerating depolarization that signalsthe start of the actual discharge develops later at a separateonset site. As found previously with interictal-like discharges,local application of kynurenic acid to the plateau site blockedictal-like discharges throughout the entire slice. However, inmarked contrast to interictal-like activity, blockade of synaptictransmission at the onset site failed to block the ictal-likedischarge. This indicates that interictal- and ictal-like dischargesshare a common pathway in the earliest stage of their generationand that their mechanisms subsequentlydiverge.

Key words: epilepsy; epileptiform activity; ictal activity; voltage imaging; piriform cortex; glutamate receptors

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The question of how interictal and ictal activities are related is of fundamental importance to our understanding of the genesisof seizures (Prince and Connors, 1986; Dichter and Ayala, 1987;Fisher, 1989). Interictal activity consists of isolated synchronouselectrical discharges, each lasting a few hundred milliseconds.Ictal activity accompanies seizures and consists of prolongedparoxysmal discharges with distinct temporal phases. In some formsof simple focal epilepsy, interictal discharges help indicatethe site of seizure origin, and in these cases the onset of seizuresmay actually be a transition from interictal to ictal activity(Prince et al., 1983; Dichter and Ayala, 1987). However, in someanimal models (Sherwin, 1978; Engel and Ackermann, 1980; Gotman,1984) and human epilepsies (Engel et al., 1981) ictal and interictaldischarges can arise from different locations, with little correlationbetween interictal activity and the frequency and severity ofseizures (Dichter and Ayala, 1987; Fisher, 1989). In hippocampalslices interictal-like discharges can be dissociated experimentallyfrom ictal-like discharges. These studies suggested that in contrastto interictal-like activity, some forms of ictal-like activitycan occur in the absence of synaptic transmission (Konnerth etal., 1986; Jensen and Yaari, 1988; Schweitzer et al., 1992). Thisraises important questions about the extent to which parallelversus divergent mechanisms underlie these two forms of paroxysmalactivity.

Recent voltage-imaging studies in slices of piriform cortex (PC) revealed that interictal-like discharges can be precededby a low-amplitude, sustained depolarization (plateau activity)(Demir et al., 1999). Plateau activity was observed during thelatent period that precedes discharges evoked by near-thresholdelectrical stimulation. It begins a few milliseconds after stimulationand is confined to the boundary region between the endopiriformnucleus (En) and layer III of the overlying PC. This site is distinctfrom the site of discharge onset, situated at a deeper locationwithin the En and layer VI of adjacent neocortex [agranular insula(AI) in anterior slices and anterior perirhinal cortex (PRh_a)in posterior slices] (Demir et al., 1998). This work suggestedthat in slices of PC the generation of interictal-like dischargesoccurs in two stages, with plateau activity representing the firststage and actual onset representing the secondstage.

Ictal-like activity can also be elicited in slices of PC (Hoffman and Haberly, 1989). The above questions about the relationshipbetween ictal and interictal activity prompted us to determinewhether ictal-like discharges develop in the same two-stage progressionas interictal-like discharges. We found that ictal-like dischargeswere preceded by plateau activity similar to that which precedesthe onset of interictal-like discharges. As with interictal-likedischarges, local application of kynurenic acid at the site ofplateau activity blocked ictal-like discharges. However, in contrastto interictal-like discharges, ictal-like discharges could notbe blocked by inhibiting synapses at the site of onset. This suggeststhat plateau activity is capable of serving as a precursor toboth of these types of epileptiform activity. However, by thetime of onset, ictal-like discharges diverge from interictal-likedischarges in being insensitive to focal blockade of synaptictransmission.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Piriform cortex slices. Adult male Sprague Dawley rats weighing 175-240 gm were used to prepare PC slices. A vibratome wasused to cut slices at a thickness of 350 µm along a near-coronalplane perpendicular to the brain surface (Hoffman and Haberly,1991, 1993; Demir et al., 1998). The physiological saline [artificialCSF (ACSF)] for slicing and recording contained 124 mM NaCl, 5mM KCl, 26 mM NaHCO₃, 1.2 mM KH₂PO₄, 2.4 mM CaCl₂, 1.3 mM MgSO₄,and 10 mM glucose bubbled with 95% O₂ and 5% CO₂ (carbogen). Experimentswith bath application of CoCl₂ were performed with ACSF bufferedby HEPES (10 mM) and lacking phosphate, to avoid precipitation(see Fig. 7). Slices were defined as anterior, intermediate, orposterior depending on the stereotaxic levels stated previously(Demir et al., 1998).

Epileptiform activity. Ictal-like discharges were generated by perfusing slices with a low-Cl ACSF in which 93% of the Cl in the ACSF described above was replaced by isethionate. Sliceswere incubated in this low-Cl ACSF at 34°C, starting 1.5-2 hr before recording and continuingthroughout an experiment. Although previous incubation of slicesin low-Cl ACSF was not necessary to elicit ictal-like activity, the appearanceof ictal-like discharges took time, and it was advantageous tobegin experiments soon after staining because the voltage-sensitivedye was gradually washed out during hours of perfusion with saline.The low-Cl method of eliciting ictal-like activity is based on a positiveshift in the Nernst potential for Cl resulting in increased excitability. This increase is thoughtto result primarily from the reversal of Cl-dependent GABA_A receptor-mediated inhibitory synaptic potentials.However, additional effects of low Cl may include a decrease in the free cation concentration in theextracellular space (Chamberlin and Dingledine, 1988), with excitatoryeffects resulting from partial removal of charge screening. Furthermore,low Cl is thought to have effects on synaptic transmission (Traynelisand Dingledine, 1989), and the reversal of voltage- and Ca²⁺-dependent Cl conductances could also contribute to the increase in excitability(Madison et al., 1986; Owen et al., 1986).

Interictal-like activity was generated using the induction and disinhibition protocols described previously (Demir et al.,1998). Disinhibition was achieved by simple addition of 5-10 µMbicuculline during experiments to block GABA_A receptors. Inductionused the same low-Cl ACSF used during recordings of ictal-like activity as describedabove, but with a major difference that slices were returned tocontrol saline for recordings. Thus, in this model, a period ofspontaneous bursting activity in low-Cl ACSF transformed, or induced, a persistent change in excitabilitythat was manifest after return to control ACSF (Hoffman and Haberly,1989; Stasheff et al., 1989).

Epileptiform discharges were evoked by electrical stimulation of slices with a saline-filled glass pipette (20-50 µm tip diameter).Current pulses 200 µsec in duration were delivered with a stimulusisolator. Ictal-like discharges are generally defined as lasting>2 sec (Rasmussen et al., 1996; Traub et al., 1996; Rutecki andYang, 1998). However, we found that the duration varied with stimuluscurrent (see Fig. 2), and with currents near the threshold fordischarge generation, events were sometimes as short as 1 sec.Because these discharges were obtained under the same conditionsas those lasting much longer and showed clear qualitative differenceswith interictal-like discharges, we treated them as ictal-like.

The threshold stimulus for discharge generation was determined by careful variation of stimulus intensity. For experimentsin which drugs were tested for their ability to block epileptiformdischarges, stimulus intensities ~10% above threshold were usedto avoid subthreshold responses. During these experiments, thethreshold intensity was regularly determined because it showeda tendency to change over the course of a long experiment (3-6hr). After evoking an ictal-like discharge, at least 2 min wasalways allowed for recovery before attempting to evoke another.This interval was necessary because there was a refractory periodfor ictal-like discharges in PC slices reminiscent of the postictaldepression seen during seizures in animals (Ayala et al., 1970).

Voltage imaging. The voltage-sensitive fluorescent dye RH414 (Molecular Probes, Eugene, OR) was used to image voltage. Sliceswere incubated for 30-45 min in 200 µM RH414 in ACSF bubbled withcarbogen. Fluorescence images were recorded with a 464-element,hexagonally arranged, photodiode-fiber optic camera (Chien andPine, 1991). The tissue was illuminated in an upright epifluorescentmicroscope equipped with a 100 W tungsten-halogen light sourcethrough a Zeiss Fluar 5× objective (numerical aperture, 0.25).This objective produced images in which the distance between neighboringphotodetector fields was 144 µm. The optical and electronic instrumentationfollows that of Wu and Cohen (1993); a detailed description alongwith a schematic of the setup can be found in a previous reportfrom this laboratory (Demir et al., 1998). The output of eachphotodetector was individually amplified to a final level of 0.2V/pA of photocurrent, digitized, and read into a Pentium computer.Fluorescent signals were high-pass filtered with a 500 msec timeconstant and low-pass filtered with a corner frequency of 500Hz. A CCD camera served to take transilluminated video imagesof slices, which were read into the computer with a frame grabber(Data Translation, Marlboro,MA).

Data acquisition and analysis. Optical signals were acquired and analyzed with the computer program Neuroplex (RedShirt Imaging,Fairfield, CT). Fluorescence traces were overlaid on video imageswith programs written in IDL (Research Systems, Boulder, CO) (Jacksonand Scharfman, 1996; Demir et al., 1998). The contours for thesite of discharge onset were prepared from real-time-imaging databy determining the photodetector fields where the fluorescencechange had risen to within 50 or 70% of its maximum amplitude.This cutoff excludes regions with plateau activity because withnear-threshold stimulus currents, plateau activity has an amplitude $<=$ 25% of the maximum amplitude of interictal-like discharges (Demiret al., 1999), as well as ictal-like discharges (present results).Before the preparation of contours, the fluorescence intensityof each detector was normalized to the intensity range seen bythat detector. Another program written in IDL superimposed thecontours onto video images. Contours for plateau activity wereprepared manually by marking detectors in which a sustained depolarizationduring the latent period could clearly be seen above the backgroundnoise (Demir et al., 1999).

Local drug application. Kynurenic acid (5 and 10 mM), bicuculline methiodide (50 µM), and CoCl₂ (10 mM) were dissolved ina 0.9% NaCl solution and topically applied from a micropipette(tip diameter, 3-5 µm) inserted into a slice with a micromanipulatorat selected sites. A Picospritzer (General Valve, Fairfield, NJ)connected to the drug-application micropipette provided pressurepulses (0.5 sec; 20-25 psi) for ejection of solution. The effectivenessof this approach in delivering a drug to specific sites was discussedpreviously (Demir et al., 1999). Localization was tested in everyexperiment by visualization of fluorescein (0.1 mg/ml) includedin the drug solution. Because the optical filter set used forRH414 excluded fluorescein fluorescence, this did not interferewith optical recordings of voltage. As in previous studies fromthis laboratory (Demir et al., 1999), before drug applicationepileptiform events were evaluated two or three times for stabilityof discharge latency. Drug application experiments at each sitewere repeated at least threetimes.

Histology. After optical recordings, slices were preserved by fixation in 4% paraformaldehyde, resectioned with a freezingmicrotome at 60 µm, and counterstained with cresyl violet. Photographsof these Nissl-stained sections helped to identify anatomicalstructures during analysis of imagingdata.

Drugs. Bicuculline methiodide was obtained from Sigma (St. Louis, MO), and kynurenic acid was from Aldrich (Milwaukee,WI).

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Ictal-like discharges

Either interictal- or ictal-like discharges were elicited using the appropriate protocols described in Materials and Methods.Interictal-like discharges in the induced (Fig. 1A) and disinhibited(Fig. 1B) models generally lasted 100-300 msec [see Demir et al.(1998) for comparisons between these two models]. Ictal-like dischargeswere elicited from slices pretreated and perfused with low-Cl ACSF (Fig. 1C-E). These electrical events were similar in amplitudebut considerably longer in duration than were interictal-likedischarges. Although the duration of ictal-like discharges wasvariable (Fig. 1C-E), the initial phase generally consisted ofa sustained depolarization. This initial depolarization was sometimesfollowed by relatively brief voltage oscillations (Fig. 1C,E).Ictal-like discharges first appeared at discrete and well definedsites of onset (discussed below) and then spread throughout theentire slice.

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Figure 1. Optical recordings of interictal- and ictal-like discharges. A, B, Interictal-like discharge in an induced slice (A; previous bursting in low-Cl ACSF) and a disinhibited slice (B; with 10 µM bicuculline). C-E, Ictal-like discharges in anterior (C), intermediate (D), and posterior (E) PC slices. All fluorescence (F) traces represent averages of six neighboring detectors. Note that the instrumentation uses a high-pass filter with a 500 msec time constant (see Materials and Methods), and this produces some attenuation of the longer events of C-E. Stimulus was applied to layer Ib of the PC in all traces; stimulus currents were 175 µA (A), 65 µA (B), 250 µA (C), 275 µA (D), and 60 µA (E).

An intriguing feature of evoked ictal-like discharges in PC slices was that their duration increased as the stimulus currentwas increased above threshold (Fig. 2). Discharges in responseto threshold stimuli were generally briefer (Fig. 3). Superimposedsub- and suprathreshold responses in Figure 3 show that ictal-likedischarges have an all-or-none character and appear with substantiallatency after a threshold stimulus. As with interictal-like activity(Hoffman and Haberly, 1989, 1991; Demir et al., 1998), increasingthe stimulus current decreased the latency to ictal-like dischargeonset (data not shown). To address the question of how the initiationof ictal-like discharges compares with the initiation of interictal-likedischarges, we used near-threshold or slightly suprathresholdstimulus currents to produce latent periods of sufficient durationto observe latent period activity. This enabled us to focus onthe events leading up to the onset of an ictal-like discharge.

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Figure 2. Fluorescence traces show responses from En in an intermediate PC slice elicited by increasing stimulus currents (indicated above the traces on the right) applied in layer Ib. The duration of ictal-like discharges increased with increasing stimulus current. Traces represent averages of six neighboring detectors.

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Figure 3. Plateau activity preceding ictal-like discharges. Sub- and suprathreshold responses are superimposed to illustrate the all-or-none character of ictal-like discharges. The time scales are expanded relative to those in Figures 1 and 2 to show the early events before discharge onset. A, A trace from the site of onset shows onset activity (asterisk-curved bracket), characterized by a ramp-like depolarization leading up to a discharge. B, A trace from the site of plateau activity shows plateau activity (asterisk-curved bracket), characterized by a low-amplitude, maintained depolarization. C, A trace from superficial layer III of the PC is close enough to the site of stimulation to show a rapidly decaying local response. D, E, Responses from deep (D) and superficial (E) layers of the neighboring transitional neocortex between AI and PRh_a show the ictal-like discharge emerging suddenly from a flat baseline. The discharges in B-E appear after a delay relative to the discharge in the site of onset (A). The vertical dashed line helps to view latency differences. These traces were taken from sites labeled A-E in a subsequent figure (see Fig. 5B2). Electrical stimulation (135 µA) was applied in layer Ib at the time indicated by the arrow in A (see Fig. 5B2 for site). All traces represent averages of four neighboring detectors.

Plateau activity precedes ictal-like discharges

Electrical activity during the latent period preceding interictal-like discharges has been described previously for the twodifferent experimental models used in Figure 1, A and B (Demiret al., 1999). In both the disinhibition model (bicuculline treatment)and the induction model (previous spontaneous bursting in low-Cl ACSF), a similar spatiotemporal pattern was seen during the latentperiod between electrical stimulation and discharge onset. Plateauactivity, as mentioned in the introductory remarks, is characterizedby an approximately constant, low-amplitude depolarization, beginninga few milliseconds after stimulation and continuing until dischargeonset. Onset activity is a rapidly accelerating depolarizationthat appears at the site of discharge onset (Hoffman and Haberly,1993), beginning ~20-50 msec before onset and leading directlyto the discharge (Demir et al., 1999). These two forms of latentperiod activity appeared in sequence at two distinct locations.Plateau activity was generally located at the boundary of En anddeep layer III of the PC. Onset activity generally had a deeperlocation in En and adjoining layer VI of the neocortex. Plateauactivity serves to sustain and amplify electrical activity initiatedby a stimulus. Onset activity is driven by projections from thesite of plateau activity, providing feedback to that site to contributeto the amplification process. Onset activity builds up directlyinto the epileptiform discharge. Blockade of activity at eithersite, with either kynurenic acid or CoCl₂, blocks the generationof interictal discharges (Demir et al., 1999).

In the present study the electrical activity observed before the onset of an ictal-like discharge was similar to that observedin the two interictal models described above. A ramp-like depolarizationresembling the onset activity of interictal-like discharges appearedat the site of onset of ictal-like discharges (Fig. 3A, asterisk-curvedbracket). A sustained depolarization resembling the plateau activityof interictal-like discharges was seen at a site different fromthe site of discharge onset (Fig. 3B, asterisk-curved bracket).Thus, onset and plateau activities were each seen at distinctlocations that were very similar to the locations where theseforms of activity were seen in the interictal models (detailedmapping of locations presentedbelow).

No significant latent-period activity was seen outside of the onset and plateau sites. A rapidly activating and decaying localresponse could be seen near the stimulus electrode (positionedin superficial layer III of the PC; Fig. 3C), and this was followedby an ictal-like discharge that spread from the site of onset.At other sites far from the site of stimulation, where no localresponse could be detected, discharges arose abruptly from baselinewithout any preceding activity (Fig. 3D,E). The onset of theseevents thus resembled that of the rapid-onset interictal-likeevents described by Hoffman and Haberly (1993). The amplitudeof the fluorescence change associated with ictal-like dischargeswas smaller in amplitude and briefer in duration in superficiallayers (Fig. 3C,E) than in deep layers of the PC (Fig. 3A,B) orin neighboring AI or PRh_a (Fig. 3D). Thus, the spatial patternsfor ictal- and interictal-like discharges were similar in showinga decreasing amplitude toward the cortical surface (Demir et al.,1998).

We showed previously that stimulus currents below the threshold for interictal-like discharges evoked depolarizations at thesame site where plateau activity was observed. These subthresholddepolarizations were smaller in amplitude than plateau activity.After peaking, subthreshold responses always decayed smoothlyto baseline, and never showed a plateau-like time course (Demiret al., 1999). Under ictal-like conditions, subthreshold responsesat the site of plateau activity showed a similar low-amplitude,and a similar smooth decay to baseline (Figs. 3B, 4A). The factthat these subthreshold responses failed to show the sustainedtime course of plateau activity indicates that, as was found previouslywith interictal-like discharges, plateau activity could not bedissociated from the ictal-like discharge.

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Figure 4. Subthreshold responses at the site of plateau activity. A, Superimposed fluorescence traces are shown from the site of plateau activity in response to increasing stimulus intensities. Responses were evoked by stimulation in layer Ib with the indicated current. Traces represent averages of seven neighboring detectors. Note that the subthreshold responses were not flat like plateau activity but decayed immediately after peaking. Note further that the amplitude does not increase linearly with increasing stimulus intensities. B, A stimulus-response plot illustrates this nonlinearity more clearly. The peak response amplitudes from A were plotted versus stimulus current. The nonlinearity is emphasized by a sigmoidal fit.

Under the conditions used to generate ictal-like discharges, the amplitudes of subthreshold responses at the site of plateauactivity showed a strongly nonlinear, graded increase with stimuluscurrent (n = 5; Fig. 4). This trend could be seen in superimposedtraces from the site of plateau activity (Fig. 4A), as well asin the stimulus-response plot in Figure 4B. This sigmoidal behaviorwas not seen in control slices, in which stimulus-response plotswere linear. The stimulus-response behavior under conditions usedto generate interictal-like activity depended on the choice ofmodel. Plots were linear in the induction model (Demir et al.,1999) and nonlinear in the disinhibited model (R. Demir et al.,unpublishedobservations).

Location of onset and plateau activity during ictal-like discharges

Sites of latent-period activity were determined by making contours using a 50-70% of maximum cutoff for the onset site anda manual trace-by-trace examination for the plateau site (seeMaterials and Methods). In anterior slices, the site of onsetof ictal-like discharges was confined to the En and to layer VIof adjacent AI (n = 4; Fig. 5A2 pink-shaded region). In contrastto interictal-like discharges in anterior slices (induced model),in which the site of onset was confined to the dorsalmost partof En and neighboring layer VI of AI (Demir et al., 1998), thesite of onset of ictal-like events occupied a larger portion ofthe En. The site of plateau activity in anterior slices encompassedpart of the En and deep layer III of the PC (n = 4; Fig. 5A2,blue-shaded region); a tiny portion of AI layers V and VI alsoconsistently showed plateau activity. This site was similar tothe site of plateau activity for interictal-like discharges inthe induced model (. However, with ictal-like discharges therewas a smaller contribution from the deep layers of neighboringAI and a larger contribution from deep layer III of the PC. Overall,the region showing plateau activity was larger for ictal-likeactivity than for interictal-like activity. Thus, for both onsetactivity and plateau activity, larger regions were seen for ictal-likedischarges than for interictal-like discharges.

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Figure 5. Site of plateau activity associated with ictal-like discharges. Nissl-stained photographs (A1-C1) were taken from the same slices shown in A2-C2. Sites of discharge onset (pink shading) and plateau activity (blue shading) are indicated on video images from anterior (A1, A2), intermediate (B1, B2), and posterior (C1, C2) PC slices. Stimulus sites are indicated by parallel jagged lines in A2-C2. Stimulus currents were 100 µA (A1, A2), 135 µA (B1, B2), and 63 µA (C1, C2). AI, Agranular insula; Cl, claustrum; CPu, caudate-putamen; ec, external capsule; En, endopiriform nucleus; LOT, lateral olfactory tract; PC, piriform cortex; PRh_a, anterior perirhinal cortex; RF, rhinal fissure. Open arrowheads mark the PC/neocortex boundary.

In posterior slices, the site of onset for ictal-like discharges was confined to the En (n = 4; Fig. 5C2, pink-shaded region),and this resembled the site of onset of interictal-like dischargesin the disinhibited model in posterior slices. In contrast, thesite of onset of interictal-like discharges in the induced modelalso included layer VI of the neighboring PRh_a (Demir et al.,Demir et al., 1998). Under ictal-like conditions, the site ofplateau activity in posterior PC slices consisted of parts ofthe En and deep layer III of the PC (n = 4; Fig. 5C1,C2, blue-shadedregion), which was similar to the site of plateau activity forinterictal-like discharges in the disinhibited model (. In theinduced model the site of plateau activity did not extend intodeep layers of the neighboring PRh_a.

In intermediate slices, the site of onset was in the dorsal edge of the En, and the site of plateau activity was in the boundaryregion between En and deep layer III of the PC (Fig. 5B1,B2).Adjoining neocortex was not involved in either form of latent-periodactivity. Similar sites of onset and plateau activity were observedfor both models of interictal-like activity (Demir et al., Demiret al., 1998, 1999). These sites are summarized for ictal-likedischarges in Table 1 for anterior, intermediate, and posteriorslices of the PC.


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Table 1. Plateau and onset sites for ictal-like discharges

Blockade of plateau activity

Previous work established a requirement for excitatory synaptic transmission at the sites of plateau and onset activity inthe genesis of interictal-like discharges (Demir et al., 1999).Because we found the same forms of latent-period activity in thelow-Cl model, we investigated the role of synaptic transmission at thesesites in the generation of ictal-like discharges. Kynurenic acid(a broad-spectrum excitatory amino acid receptor antagonist) wasapplied locally to inhibit synaptic transmission in specific regions.The method of local drug application used in this study was thesame as that used previously, in which localization of drug waschecked by observing fluorescein. Drug localization was furtherverified by showing no effect on graded responses at short distancesand no blockade of epileptiform activity when the drug applicationpipette was moved 500 µm from a critical site (Demir et al., 1999).

The sites of discharge onset and plateau activity were first mapped by analysis of imaging data while the experiment was ongoing.Kynurenic acid was then applied to the site of plateau activity,and an electrical stimulus found previously to be suprathresholdfor the generation of an ictal-like discharge was reapplied. Blockadewas seen in every experiment (n = 8; Fig. 6A1b), with the ictal-likeresponse recovering within a few minutes (Fig. 6A1c).

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Figure 6. Blockade of ictal-like activity. A, Kynurenic acid (5 mM) was locally applied at several sites to determine the role of excitatory synaptic transmission in the generation of ictal-like discharges. Traces in A1 show responses from the site of plateau activity in an intermediate PC slice before (A1a), immediately after (A1b), and a few minutes after (A1c) kynurenic acid application. The ictal-like discharge was blocked by kynurenic acid application at this site (A1b) and recovered completely after washout (A1c). When kynurenic acid was applied at the site of onset, ictal-like activity (A2a) was not blocked, although the response was usually attenuated locally (A2b) and recovered to full size after a few minutes (A2c). Application of kynurenic acid at a site in deep AI/PRh_a (A3) did not block the ictal-like discharge. B, Bicuculline methiodide (50 µM) was applied to several sites to test whether reversed inhibitory potentials play a role in the generation of ictal-like discharges. Local application of bicuculline at the site of plateau activity (B1a,b), the site of onset (B2a,b), and another site in En (B3a,b) did not block ictal-like activity. Traces in A and B were taken from two different slices and show responses from the sites of drug application (indicated above each set of traces). Traces are averages of four neighboring detectors. Ictal-like discharges were evoked by stimulation in layer Ib at 140 µA (A1), 110 µA (A2), 95 µA (A3), 67 µA (B1), 55 µA (B2), and 52.5 µA (B3).

In contrast to the results seen for application at the plateau site, application of kynurenic acid at the site of onset didnot block ictal-like discharges. The signals emanating from thissite were attenuated, but the latency-to-discharge onset was unaffected(n = 6; Fig. 6A2b). Applying a higher concentration of kynurenicacid (10 mM) to the onset site also failed to block ictal-likedischarges (n = 4). In four of the experiments in which kynurenicacid was applied to the site of onset, the data were examinedto see whether the site of onset moved to a new location. In threeof these experiments the site of onset was essentially the same,and in the fourth it moved slightly. Ictal-like discharges couldstill be evoked when kynurenic acid was applied at other locationsin En outside the sites of onset and plateau activity (n = 6;data not shown) and at other nearby sites in PRh_a (n = 7; Fig.6A3).

The site of plateau activity was the only location in PC slices where the sensitivity of ictal-like discharges to local excitatoryamino acid receptor blockade could be demonstrated. Thus, plateauactivity appears to be necessary for both ictal- and interictal-likedischarges. In contrast, although activity at the onset site wassimilar in appearance at the start of both ictal- and interictal-likedischarges, application of kynurenic acid to this site blockedonly interictal-like discharges (Demir et al., 1999).

In the low-Cl ACSF used here to generate ictal-like discharges, Cl-mediated inhibitory synaptic potentials are reversed and thereforehave an excitatory instead of inhibitory effect on postsynapticcells. Thus, GABA_A receptor activation could contribute to epileptiformactivity under these conditions. To test this hypothesis we attemptedto block GABA_A receptors with the antagonist bicuculline usingthe same local application method used to block glutamate receptors.Application of bicuculline to the site of plateau activity (n= 4; Fig. 6B1), site of onset (n = 4; Fig. 6B2), elsewhere inthe En (n = 4; Fig. 6B3), and other nearby sites in neighboringneocortex (n = 4; data not shown) failed to block the ictal-likedischarges. To test the possibility that either excitatory aminoacid receptors or depolarizing GABA_A receptors can initiate anictal-like discharge, we applied 10 mM kynurenic acid togetherwith 50 µM bicuculline in the same pipette and again saw no blockadewhen these drugs were injected at the site of onset (n = 2; datanotshown).

To test the role of synaptic transmission more generally, we used the Ca²⁺ channel blocker CoCl₂. Like kynurenic acid, CoCl₂ blocked interictal-likedischarges when applied to the site of onset (Hoffman and Haberly,1993, 1996; Demir et al., 1999). We specifically tested the actionof CoCl₂ on evoked responses at the site of onset, to make surethat it was an effective reagent in the blockade of synaptic transmissionat that location. Bath application of 2 mM CoCl₂ blocked synapticpotentials at the site of onset, recorded either with fluorescenceor with an extracellular field electrode (Fig. 7A). Ictal-likedischarges could still be evoked when 10 mM CoCl₂ together with50 µM bicuculline was applied at the site of onset (n = 3; Fig.7B). In these experiments the same blocker solution was testedat two to four locations within the onset site, but the dischargeswere not blocked. These results indicate that local blockade ofchemical synapses at the site of onset does not prevent the generationof ictal-like activity.

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Figure 7. Effects of CoCl₂ on synaptic transmission and ictal-like discharges. A, Fluorescence (top) and extracellular field potentials (bottom) were recorded from En in a control slice. Responses evoked by 400 µA applied in deep layer III of the PC were almost completely abolished by bath application of 2 mM CoCl₂. (KH₂PO₄ was omitted from the ACSF for both control and CoCl₂). Each trace represents an average of signals from six neighboring detectors averaged over 10 trials. B, Fluorescence traces from the En show an ictal-like discharge evoked by a stimulus of 47 µA applied in layer Ib. Traces show discharges before (top) and immediately after (bottom) application of 10 mM CoCl₂ and 50 µM bicuculline to the site of discharge onset.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The experiments presented here showed that ictal-like discharges in PC slices are preceded by plateau activity with a timecourse and location similar to that of plateau activity precedinginterictal-like discharges (Demir et al., 1999). Plateau activityin the ictal model showed an approximately constant amplitudethroughout the entire latent period, never occurred in isolationfrom an ictal-like discharge, and was spatially restricted tosimilar locations in anterior, intermediate, and posterior slices.Furthermore, synaptic blockade at the site of plateau activityblocked ictal-like discharges throughout the slice, as demonstratedpreviously in interictal models. Thus, plateau activity is requiredfor the generation of both interictal- and ictal-like dischargesin PC slices. Because ictal-like activity in this slice preparationresembles electrical activity during seizures in the neocortex(Ayala et al., 1970), the sustained, plateau-like depolarizationsdescribed here may contribute to the onset of seizures. The requirementof plateau activity for the genesis of both interictal- and ictal-likeevents is important, because it implies that both types of epileptiformactivity share common mechanisms at an early stage of their genesis.Because plateau activity may serve as a precursor for ictal spikes,pharmacological interventions directed toward curtailing plateauactivity could be useful in controllingseizures.

The finding that ictal- and interictal-like activities have a common precursor, namely, plateau activity, provides an interestingperspective on the relationship between interictal spikes andseizures. The onset of seizures is often thought of as a transitionfrom interictal to ictal activity (Dichter and Ayala, 1987). Oneimportant issue in this regard is whether interictal spikes canserve as direct progenitors of seizure activity (Prince et al.,1983). However, the relationship between interictal and ictalactivity suggested by the present results is one of bifurcationrather than transitional sequence. Factors in effect during plateauactivity may determine whether the ensuing discharge will be interictalor ictal in character. By altering the ionic environment, thevolume of extracellular space, and the functional states of ionchannels and synapses, interictal spikes could modify conditionsso that subsequent plateau activity leads to ictal rather thaninterictaldischarges.

Locations of onset and plateau activity

The sites of onset and plateau activity were identified previously in two interictal models, in slices from anterior, intermediate,and posterior PC (Demir et al., 1998, 2000). Here we found thatthese forms of activity occurred at similar sites in ictal-likedischarges (Fig. 5, Table 1), but with some subtle and interestingdifferences. As with interictal-like activity, the onset siteof ictal-like activity included En, and the plateau site includedadjoining parts of En and deep layer III of the PC. However, inthe induced model, adjoining deep layers of neocortex contributedto both onset and plateau activity, in both anterior and posteriorPC slices. By contrast, neocortex did not contribute to theseearly stages of interictal discharges in the disinhibited model(Demir et al., 1998, 2000). Thus, ictal-like activity in anteriorPC slices has a site distribution resembling that of interictal-likeactivity in the induced model, but in posterior PC slices, ictal-likeactivity has a site distribution resembling that of interictal-likeactivity in the disinhibited model. Interestingly, neither onsetnor plateau activity was seen in neocortex in intermediate slices,for either ictal- or interictal-like activity. We have suggestedpreviously that the differences between the onset sites in theinduced and disinhibited models may be caused by a nonuniformdistribution of GABA_A receptors and/or synaptic circuitry alongthe rostrocaudal axis of the En and neighboring neocortex (Demiret al., 1998). Similar regional differences may be relevant tovariations in onset and plateau sites associated with ictal-likebehavior.

Threshold and subthreshold behavior

Epileptiform discharges are generally all-or-none, and that was the case here for ictal-like discharges. However, subthresholdresponses at the site of plateau activity had a nonlinear dependenceon stimulus current (Fig. 4). Similar subthreshold nonlinearitywas seen in the disinhibited interictal model (. but in controland induced slices, stimulus-response plots were linear (Demiret al., Demir et al., 1999). This suggests the presence of strongeramplification processes in the disinhibited interictal model andthe low-Cl ictal model. Di- and polysynaptic potentials described by Tsengand Haberly (1989) could amplify responses and contribute to thisnonlinearbehavior.

We were surprised to see that the duration of an ictal-like discharge increased with increasing stimulus current (Fig. 2).This result stands in contrast with interictal-like discharges,which have the same duration regardless of stimulus strength.Increasing the stimulus current also shortens the latency to dischargeonset, and this may be relevant to the character of the ensuingdischarge. A prolonged latent period, which will be accompaniedby prolonged plateau activity, could influence the state of aslice at the time of onset. Modeling studies suggested that bothdendritic depolarizations and ectopic axonal spikes can contributeto ictal discharge initiation (Traub et al., 1996). If the relativemagnitudes of these two processes change with time, then the durationof the subsequent discharge may depend on which of these two processespredominates at the time of onset. Because of the complex relationshipbetween cellular mechanisms and network phenomenon, computer-modelingstudies such as those conducted by Traub and coworkers will probablybe necessary to test thesehypotheses.

Synaptic blockade and discharge onset

Although the finding that plateau activity is a precursor for both interictal- and ictal-like discharges implies common mechanismsat the earliest stage of genesis, an important difference wasseen at the onset. Interictal-like discharges could be abolishedby synaptic blockade at the onset site (Demir et al., 1999), butictal-like discharges could not. Bicuculline methiodide also failedto block ictal-like discharges when applied to the site of onset,suggesting that inverted inhibitory synaptic potentials causedby the reversal of the Cl gradient do not provide the excitatory drive for discharge initiation.Thus, it is unlikely that inverted inhibitory synaptic potentialssimply substitute for excitatory glutamatergicsynapses.

One possible explanation for the failure of local synaptic blockade at the onset site to suppress ictal-like discharges isthe larger size of the onset site relative to that of interictal-likedischarges. This may reflect the involvement of a network of neuronsextending over a larger region. This suggests that if we wereable to perfuse the entire onset region with drug we might blockictal-like discharges. However, the plateau site was also larger,and local drug application there still blocked discharges. Onsetactivity was observed in a smaller region than plateau activityfor both interictal-like (Demir et al., 1999) and ictal-like (Fig.5) discharges. Furthermore, kynurenic acid was used at twice theconcentration used in all other experiments (10 vs 5 mM), butonset still occurred at essentially the samelocation.

Another possible explanation for why kynurenic acid, bicuculline, and mixtures of bicuculline with kynurenic acid or CoCl₂failed to block ictal-like discharges when applied to the siteof onset is that nonsynaptic mechanisms play a significant rolein the initiation process. Kynurenic acid slightly reduced theamplitude of the fluorescence change at the site of onset (Fig.6A2b), suggesting that excitatory synapses contribute to the observeddepolarization, but this depolarization still developed into aspreading epileptiform discharge. Nonsynaptic neuronal interactionsplay roles in many brain functions, as well as pathological conditionssuch as epilepsy (Jefferys, 1995). Computer simulations in thehippocampus have suggested that nonsynaptic mechanisms can makesignificant contributions to ictal activity (Traub et al., 1996).Hippocampal slices can generate synchronous neuronal dischargeswhen synaptic transmission is blocked (Taylor and Dudek, 1982).Furthermore, ictal-like discharges can be generated without functionalchemical synapses, but interictal-like activity is eliminatedunder these conditions (Konnerth et al., 1986; Jensen and Yaari,1988; Schweitzer et al., 1992). This implies that ictal- and interictal-likeparoxysmal activities differ in their dependence on synaptic transmission.The present results are consistent with this general trend. Thenonsynaptic mechanisms proposed to play roles in epileptiformactivity include electrotonic coupling through gap junctions (Dudeket al., 1986), field effects or ephaptic interactions (Traub etal., 1985; Dudek et al., 1986), voltage-dependent Cl conductances (Chamberlin and Dingledine, 1988), and elevated[K⁺]_o (Yaari et al., 1986). Further studies using local applicationmethods in PC slices should help evaluate the roles of these diverseprocesses in the generation of seizure-likeactivity.

Regardless of the relative contributions of these mechanisms, it is significant that ictal-like discharges diverge from interictal-likedischarges at the time of onset. Before onset, both types of epileptiformactivity depend on plateau activity, which in turn depends onexcitatory amino acid receptor-mediated synaptic transmission.Ictal- and interictal-like activities thus start off on a commonpathway, apparently using similar mechanisms. The juncture atwhich ictal-like activity becomes resistant to synaptic blockademay represent an important point of divergence between ictal-and interictal-likedischarges.

  FOOTNOTES

Received Aug. 3, 1999; revised Sept. 17, 1999; accepted Sept. 28, 1999.

Support for this research was provided by National Institutes of Health Grants NS37212 to M.B.J. and NS19865 to L.B.H.
Correspondence should be addressed to Dr. Meyer Jackson, Department of Physiology, SMI 127, University of Wisconsin MedicalSchool, 1300 University Avenue, Madison, WI 53706. E-mail: MJACKSON{at}PHYSIOLOGY.WISC.EDU.

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DISCUSSION
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