Repeated Generalized Seizures Induce Time-Dependent Changes in the Behavioral Seizure Response Independent of Continued Seizure Induction

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Volume 17, Number 14, Issue of July 15, 1997 pp. 5581-5590
Copyright ©1997 Society for Neuroscience

Repeated Generalized Seizures Induce Time-Dependent Changes in the Behavioral Seizure Response Independent of Continued Seizure Induction

Gary M. Samoriski and Craig D. Applegate
Program in Neuroscience and The Comprehensive Epilepsy Program, University of Rochester School of Medicine and Dentistry, Rochester, New York 14642

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

This study examined both the acute and long-lasting changes in seizure susceptibility that occur in response to the repeatedinduction of generalized seizure activity. Daily flurothyl-inducedgeneralized clonic seizures resulted in a progressive decreasein both the generalized seizure threshold and the latency to thefirst myoclonic jerk. The threshold reduction was significantas early as the second trial and was maximal by trial 5. However,a minimum of eight seizures was necessary for the maximal reductionto be long-lasting. The present study also examined the effectsof the number of seizures and the duration of the stimulation-freeinterval on the type of generalized seizure expressed. Duringthe induction phase of the experiment, only generalized clonicseizures ("forebrain seizures") were expressed. If, however, theanimal was retested after a 1, 2, 3, or 4 week stimulation-freeinterval, a progressive increase in both the proportion of animalsexpressing "brainstem seizure" behaviors and the median seizurescore was observed. The progression of flurothyl-induced generalizedseizure behaviors was significantly altered if (1) a minimum ofeight generalized clonic seizures had been expressed, and (2)a minimum of a 2 week stimulation-free interval followed. Fewergeneralized clonic seizures failed to reliably produce changesin seizure phenotype, even after extended stimulus-free intervals.These data indicate that specific kindling processes are initiatedduring the interval of repeated seizure induction and evolve inthe absence of continued seizure induction. Furthermore, thesemechanisms of epileptogenesis were found to be manifest predominantlyas a change in the seizure phenotype expressed and to proceedindependent of changes in the generalized seizure threshold.
Key words: epileptogenesis; generalized clonic seizure; generalized tonic seizure; kindling; flurothyl; mouse

INTRODUCTION

Epileptogenesis, in experimental animals, is characterized by a decrease in the generalized seizure threshold (GST) and achange in the motor seizure behavior expressed in response torepeated exposure to a stimulus of constant magnitude. The neuralreorganization that underlies the enhanced seizure susceptibilityprogressively develops in response to the repeated induction ofeither focal or generalized seizure activity (Goddard et al.,1969; Ramer and Pinel, 1976). Once established, the modified seizurestate is maintained for at least 12 weeks and perhaps longer (Dennisonet al., 1995). Collectively, these phenomena are the hallmarksof kindling. Although the kindled state is established as a resultof alterations effected during the course of seizure induction,it is unknown whether these changes continue to evolve in theabsence of exogenous input. In this report, we present evidencedemonstrating that repeated generalized ictal activity initiateschanges in neural function that are time-dependent, evolve independentof continued seizure induction, and are manifest as a change inthe phenotype of the expressed motor seizure.

The goal of the present study was to characterize this phenomenon in mice using the inhalant chemoconvulsant flurothyl. Theadministration of flurothyl has been shown to reliably producegeneralized seizure behaviors in rats and mice (Truitt et al.,1960; Adler et al., 1967; Prichard et al., 1969). Clonic seizurebehaviors are exhibited if the exposure is terminated with thebeginning of a sustained generalized seizure. Although repeatedflurothyl testing has been shown to result in a progressive decreasein the seizure threshold (Adler et al., 1967; Prichard et al.,1969), the effect of multiple flurothyl-induced generalized seizureson the behavioral seizure response has not been well described.In addition, long-lasting changes that may result from repeatedflurothyl testing have not been documented. Consequently, thisstudy was designed to describe the long-term effects of repeatedseizure testing with flurothyl in terms of (1) the number of seizuresnecessary to initiate mechanisms responsible for changes in seizuresusceptibility, and (2) the minimum duration of the stimulation-freeinterval before the change in seizure phenotype is observed.

MATERIALS AND METHODS
Animals. Adult (6 weeks of age) male C57BL/6J mice were obtained from Jackson Laboratories (Bar Harbor, ME). An adaptationalperiod (minimum 1 week) was allowed before the beginning of seizuretesting. The animals were grouped in a temperature-controlledenvironment under a 12:12 hr light/dark cycle (lights on at 6:00A.M.). Food and water were provided ad libitum. All animal useprocedures were in accordance with the National Institutes ofHealth Guide for the Care and Use of Laboratory Animals (1985).
Experimental design Rationale. Flurothyl, administered by inhalation, was chosen to study the effects of repeated generalized seizures on CNSfunction. In contrast to other chemoconvulsants that are administeredsystemically (intraperitoneally or intravenously), once sustainedflurothyl-induced seizure activity begins, the investigator cancontrol the duration of action of the drug by opening the chamberto room air. Because flurothyl does not depend on metabolism forits action and is rapidly eliminated by the lungs, opening thechamber essentially terminates its action.

To evaluate the acute and long-term effects of repeated flurothyl-induced seizures on the GST in mice, a design was used suchthat each exposure to flurothyl produced a sustained generalizedseizure with predominantly clonic motor manifestations. Generalizedseizures were elicited by a 10% solution of flurothyl and repeatedonce every 24 hr. Previous studies have shown that this is aneffective paradigm for eliciting multiple seizures with low mortalityand results in progressively lower thresholds without significantlychanging the motor characteristics of the seizure (Adler et al.,1967; Prichard et al., 1969). In addition, the fact that the decreasein GST asymptotes with repeated testing indicates that a maximaland stable change in seizure threshold can be achieved under theseconditions (Adler et al., 1967; Prichard et al., 1969). Basedon these observations, two criteria were used to define the seizurethreshold asymptote: (1) when the GST had become significantlydifferent compared with the naive state (first trial), and (2)when the threshold was sustained and unchanging for at least fourconsecutive trials (i.e., no significant difference among anyof the four trials). Preliminary experiments revealed that eighttrials satisfied these criteria. These animals then went unstimulatedfor 4 weeks and were subsequently retested with flurothyl to assesswhether the change in threshold was long-lasting. The durationof the stimulus-free interval was chosen, because the retentionof the kindling effect at 1 month is generally accepted as a measureof permanence. However, on retesting at 28 d, we observed a significantchange in the behavioral seizure response of the animal. Therefore,the following experiments were designed to characterize the minimumrequirements necessary to elicit acute and long-term changes inthe seizure susceptibility, as measured by latency to the sustainedmotor event (GST) and phenotype (behavioral seizure response).

Treatment. Preliminary data indicated that when preceded by eight generalized clonic seizures, a 4 week stimulus-free intervalwas sufficient to effect a significant change in the behavioralseizure response of the animal when retested with flurothyl. Todetermine whether the altered behavioral response was apparentafter a stimulus-free interval of lesser duration, these experimentswere repeated and extended to include 1, 2, and 3 week intervals.Therefore, generalized seizures were elicited once every 24 hrfor 8 d. Separate groups of mice went unchallenged for intervalsof 1 (n = 13), 2 (n = 24), 3 (n = 11), or 4 (n = 18) weeks, atwhich time they were retested and the seizure response evaluated.In addition, a subset of animals from the 1, 2, and 3 week groupswere rechallenged 50 d after their retest trial to document whetherchanges in the behavioral seizure response and GST were maintainedat these longer intervals.

Because eight daily generalized clonic seizures (followed by a 4 week stimulus-free interval) were found to result in a nearmaximal change in the proportion of animals exhibiting a "brainstemseizure," it was of interest to determine whether the elicitationof fewer generalized clonic seizures produced a similar changein the behavioral seizure response. With 24 hr separating theseizures, 1, 2, 4, 6, or 8 generalized motor convulsions wereinduced in different groups of mice. The GST and motor seizurecharacteristics were then reevaluated 4 weeks (n = 5, 6, 6, 6,and 18, respectively) after the last trial. The eight-trial groupwas the same as that described above and was used for comparisonpurposes.

The results of these experiments indicated that fewer than eight generalized seizures did not produce a significant changein the behavioral seizure response when retested after a 4 weekstimulus-free interval. Therefore, we evaluated whether fewerthan eight generalized seizures required a longer stimulus-freeinterval for the change in the behavioral seizure response tobecome apparent. Consequently, 2 (n = 6) or 4 (n = 6) generalizedclonic seizures were elicited in separate groups of mice thatwere then retested after an 8 week stimulus-free interval.

Finally, to determine whether similar changes in the behavioral seizure response occurred without an intervening stimulus-freeinterval, a separate group of mice (n = 6) was tested once every24 hr for 21 consecutive days to characterize the effects of continuoustesting on the behavioral seizure response. The behavioral profileof this group was compared with animals that had exhibited eightdaily seizures followed by either a 1 or 2 week stimulus-freeinterval.
Seizure induction and quantitation After a 2 hr acclimatization period after transport to the laboratory from the animal facility, mice were individually placedin a 2.4 liter closed Plexiglass chamber. Generalized seizureswere elicited using a 10% solution of flurothyl (2,2,2-trifluoroethylether, Aldrich Chemical, Milwaukee, WI) in 95% ethanol. Flurothylwas administered by infusion (0.15 ml/min) onto a gauze pad (changedafter each exposure) suspended at the top of the chamber usinga 20 ml B-D Multifit syringe driven by a Sage infusion pump (SageInstruments, White Plains, NY). Infusion was terminated and thechamber opened to room air with the onset of sustained generalizedseizure activity. Onset of a generalized seizure was defined asa sustained loss of postural control (>2 sec). Seizure tests wereconducted between 8:00 A.M. and 10:00 A.M. to minimize circadianinfluences on flurothyl-induced seizure thresholds (Davis andWebb, 1963). Latencies (in seconds) from the start of infusionto the onset of each seizure behavior were recorded and used todefine the convulsive threshold for each motor behavior expressed.The duration of the total sustained generalized seizure and ofeach component of the motor seizure was also noted. In all cases,the number of myoclonic jerks was recorded.
Behavioral rating of flurothyl-induced seizures To quantify changes in the convulsive pattern expressed, as a function of the number of seizures or the temporal intervalbetween induction of the sensitized state and reexposure to theconvulsant stimulus, generalized seizure behaviors were classifiedusing the following behavioral scoring system: grade 1, purelyclonic seizure; grade 2, "transitional" behaviors involving high-frequency/low-magnitudebouncing and/or rapid backward motion; grade 3, running/bouncingepisode; grade 4, secondary loss of posture with bilateral forelimband hindlimb treading; grade 5, secondary loss of posture withbilateral forelimb tonic extension and bilateral hindlimb flexionfollowed by treading; grade 6, secondary loss of posture withbilateral forelimb and hindlimb tonic extension (THE) followedby treading; grade 7, THE followed by death. The score assignedreflects the highest grade seizure behavior expressed by the animalwithin a trial. The progression of seizure grades, within thisscoring system, reflects specific sets of behaviors expressedby the animal using this paradigm and partially reflects the orderin which the behaviors are expressed. This scoring system is notmeant to suggest that the magnitude of one behavior is greaterthan that of another. In all cases, a grade 2 seizure is precededby a grade 1 seizure. Similarly, grade 3 seizure behaviors arealways preceded by a grade 1 seizure, with or without the expressionof grade 2 behaviors. Expression of a grade 3 seizure acts asa branch point within the behavior network; that is, the seizurecan either end or progress to any one of the grades 4-7 behaviors,but never a combination of the grade 4-7 behaviors.

Because running/bouncing seizures and generalized tonic seizure manifestations can be elicited in the absence of forebrainconnections (Kreindler et al., 1958; Browning and Nelson, 1986),these seizure behaviors have been collectively referred to as"brainstem seizures." Therefore, generalized seizures featuringany of the motor behaviors defined above as grades 3-7 are designated"brainstem seizures." Similarly, grades 1-2 seizure behaviorsare designated "forebrain seizures," because these behaviors arenot expressed after high mesencephalic transection (Magistriset al., 1988; Browning et al., 1993). In addition, myoclonic jerks(MJ), although not a part of this seizure-grading system, arealso eliminated after transection. Therefore, this early seizuremanifestation is considered to be a component of forebrain seizureactivity, but is dealt with separately in the behavioral analysis.
Data analysis Animals exhibiting one or multiple generalized seizures during the induction phase were treated as independent groups anddistinguished by the duration of the stimulus-free interval orthe number of seizures exhibited before the interval that precededthe retest trial. Inclusion of an animal within a particular groupin any experiment was by random selection.

To characterize the acute changes in seizure threshold that occur in response to the repeated induction of generalized seizureactivity and to determine the effect of treatment on the long-lastingnature of these changes, latencies to the first MJ or the generalizedmotor event were combined on a per-trial basis to compute a "grandmean" for that seizure endpoint for that trial. The grand meanrepresents all animals in the study (excluding those exhibiting21 consecutive daily seizures), the total number of which rangedfrom 101 on trial 1 to 66 by trial 8. This resulted in a "population"profile for both the threshold to the first MJ and GST. Thesedata were used to construct a curve of best fit defined by a polynomialequation. Before this analysis, a one-way ANOVA was performedon the GST for each trial to confirm that between-group differencesdid not exist. To evaluate differences between individual trialsand to determine when the curves became asymptotic, a one-wayANOVA was performed on the grand mean data and post hoc comparisonsmade using Scheffe's procedure.

To determine the effect of treatment on the long-lasting nature of the threshold change, the mean latency to the first MJand generalized seizure for the retest trial of each experimentalgroup was compared with the grand mean, using the regression equationderived from the least-squares fit. By solving for x in the equation,where y is the measured threshold of the sample, we were ableto approximate the location on the curve of the test threshold(retest trial). This allowed us to determine to which trial, withinthe induction phase, the test threshold was best matched. If,for example, the threshold on the last trial contributed to theasymptotic portion of the regression curve and the threshold onthe retest trial was calculated to fall within this portion ofthe curve, the change in threshold was interpreted to be long-lasting.By contrast, a test threshold estimated to fall within that portionof the regression curve, before it becoming asymptotic, was interpretedas partial or full recovery. Paired t tests were used to describedifferences in the GST in a subset of animals that were rechallenged50 d after their retest trial.

Differences in the number of animals exhibiting "brainstem seizures" on the retest trial compared with the last trial weredetermined using the McNemar test; differences between groupswere assessed using the $chi$ ² test. The effect of the number of seizures or the duration ofthe stimulus-free interval on the type of seizure behavior expressedwas determined within groups by comparing the behavioral seizurescore obtained on the retest trial with the behavioral seizurescore of the last trial using the Wilcoxon signed-ranks test.The Spearman rank correlation was used to describe the relationshipbetween the behavioral seizure response and the GST.

RESULTS

General
No adverse changes in the health or natural behavior of the animal were observed in the interictal period, in response toeither acute or repeated exposure to flurothyl or to flurothyl-inducedseizures. The animals gained weight characteristic of their ageand strain. In addition, the animals were not more aggressivetoward either their cage mates or the investigator as a resultof the treatment. Importantly, we have exposed >200 mice to thisexperimental paradigm and have never observed a spontaneous ictalevent. Mice were in the laboratory daily during flurothyl inductiontrials and were observed a minimum of every third day during stimulus-freeintervals to maintain identification markings. At no time weremice observed to express spontaneous behavioral seizures. In addition,mice exposed to this paradigm are histologically normal at a qualitativelevel of inspection (our unpublished observations). Thus, thetime-dependent changes in seizure susceptibility that occur inresponse to repeated flurothyl-induced seizures (see below) maybe driven by distinct processes from those reported in other experimentalmodels in which repeated seizure activity produces widespreadhistopathology (Buterbaugh and Hudson, 1990; Lothman et al., 1990)

Although most of the animals were 7 or 8 weeks of age at the start of the experiment, a few 9- and 11-week-old animals wereused. In general, the difference in age at the beginning of theexperiment did not influence the changes in seizure susceptibilitythat result from the repeated expression of generalized seizures.Although there was a tendency for the GST to be higher on trials2 and 3, in 11-week-old animals, no between group differenceswere observed as a function of age when the GST was combined overthe eight trials (F_{(3, 523)} = 1.53, p = 0.21).

Flurothyl-induced generalized seizure behaviors
On initial trials (1-3), mice exhibited normal exploratory behaviors that noticeably decreased ~3 min after the start of flurothylinfusion. The observable reduction in the spontaneous motor activitywas restricted to the early trials, because the degree of exploratoryactivity is less from the outset in later trials. Shortly afterthe decrease in spontaneous motor activity during early trials,the mouse assumed a posture in which the thoracic and abdominalareas rested on the floor of the chamber, occasionally exhibitingbrief intervals of ambulation while maintaining this posture.This posture was rarely observed after the third trial.

The first overt seizure behavior produced by exposure to flurothyl was an MJ of the head and neck musculature. The numberof MJs expressed before the onset of sustained seizure activitywas variable, dependent on the seizure history of the animal.Sometimes, particularly in the early trials, a brief burst offorelimb clonus accompanied the MJ episode. Several MJs were expressedbefore the sustained generalized seizure, the number of whichdecreased with repeated exposure.

Two patterns of flurothyl-induced generalized seizure behaviors were observed in this study, the expression of which was determinedby the seizure history. The first pattern (Fig. 1A), exhibitedby naïve animals and animals in which the kindled state had notadequately developed, was defined by the expression of "forebrainseizure" behaviors followed by a period of behavioral postictaldepression. "Forebrain seizure" behaviors were characterized bya behavioral response score of grade 1 or grade 2. Generalizedclonic seizures (grade 1) consisted of a sustained loss of posturalcontrol, pronounced oro-facial clonus, clonus of the forelimbsand/or hindlimbs, and, in most cases, dorsiflexion of the head.After ~8 sec, the animal regained postural control and continuedto exhibit facial and forelimb clonus with rearing and, sometimes,falling. Occasionally, these purely clonic behaviors progressedto a qualitatively distinct motor event characterized by high-frequency/low-magnitudebouncing and/or rapid backward motion (grade 2). Using the protocolsof this study (see Materials and Methods), the generalized seizurewas restricted to these "forebrain seizure" behaviors, after whichthe animal became postictal. If, however, the animal was exposedcontinuously to flurothyl vapor, then the postictal period wasfollowed by another series of MJs and, ultimately, the expressionof a running/bouncing seizure, with or without the expressionof additional "brainstem seizure" behaviors (Fig. 1A) (that is,prolonged exposure to flurothyl in naïve mice resulted in both"forebrain" and "brainstem" generalized seizures). The expressionof these two seizure types, however, was separated by a significant(minutes) postictal interval.
Fig. 1. Diagrammatic representation of the behavioral progression of flurothyl-induced generalized seizures. "Forebrain" seizure behaviorsare represented in round-cornered boxes, and "brainstem" seizurebehaviors are represented in square-cornered boxes. A, In naivemice, generalized seizures consist of a generalized clonic seizurethat is followed by a period of behavioral postictal depressionand recovery. "Brainstem" seizure behaviors are rarely observedusing our protocols. However, if flurothyl infusion is continuedthrough the postictal period, naive mice will express seizureswith a "brainstem" phenotype. B, After the development of flurothylkindling, there is an uninterrupted progression from a "forebrain"seizure immediately to a "brainstem" seizure, suggesting a facilitatedpropagation of seizure activity between the two anatomical systemsmediating these two generalized seizure phenotypes. FL, Forelimb;HL, hindlimb.
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In contrast, the progression of behaviors, shown in Figure 1B, was characteristic of animals in which the minimum requirementsfor the initiation and development of the kindled state had beenexceeded. In these animals, the progression from a "forebrainseizure" to a "brainstem seizure" was not interrupted but wasa continuous succession of motor events, even though the chamberhad been opened at the start of sustained generalized seizureactivity. As in the animals described above, the flurothyl-inducedgeneralized seizure always began with the expression of "forebrainseizure" behaviors. However, instead of becoming behaviorallypostictal after the generalized clonic seizure, the animal progressedimmediately to a running/bouncing episode (grade 3). After expressionof the grade 3 behavior, the seizure either ended or continuedto evolve uninterrupted into a second loss of postural controlfollowed by either bilateral forelimb/hindlimb treading (grade4), bilateral tonic extension of the forelimbs and hindlimb treading(grade 5), or bilateral tonic extension of the forelimbs and hindlimbsfollowed by treading (grade 6). In four cases, expression of THEresulted in the spontaneous death of the animal (grade 7).

Behaviors most often expressed immediately after the end of the overt motor seizure included twitching of the vibrissae andpinnae, head nodding, and periods of digging and gnawing. In addition,animals that expressed "brainstem seizure" behaviors often exhibiteda period of "disoriented" ambulation lasting ~20-30 sec. In allcases, a period of behavioral postictal depression followed theseizure, the duration of which varied as a function of the expressedseizure phenotype ("brainstem seizures" more than forebrain "seizures").

Threshold effects
The repeated induction of generalized seizure activity resulted in the progressive reduction in the threshold to the firstMJ (Fig. 2A) and sustained generalized seizure (Fig. 2B). Scheffe'scomparisons indicated that the threshold was significantly lowerwith each trial up to the fourth for the first MJ, and up to thefifth for the GST. The latency to the first MJ on trials 4-8 didnot differ significantly among each other. Similarly, the GSTwas not different among trials 5-8. These data indicate that thedecrease in the MJ threshold and the GST was maximal and had reachedasymptote by the fourth and fifth trials, respectively.
Fig. 2. Effect of the repeated induction of flurothyl-induced generalized seizures on the threshold to the first MJ (A) and the GST(B) for all mice in this study. The number of animals ranges frombetween 101 on trial 1 to 66 on trial 8. Both thresholds exhibita progressive and significant decrease with each trial, up totrial 4 for the first MJ and trial 5 for the GST. The arrows inA and B indicate the point in the induction phase at which therespective threshold becomes asymptotic, indicating a maximaland sustained reduction. Data were evaluated statistically usingone-way ANOVA, and comparisons between trials were made usingthe Scheffe's procedure. The line represents the least-squaresfit of the grand mean data. This equation was used to estimatethe point in the induction phase with which a sample threshold(on retest) was best matched (cf. Table 1). All values are mean± SEM.
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The number of generalized seizures exhibited before a 4 week stimulus-free interval was found to be an important factor inthe long-term maintenance of the threshold reduction. No long-termchange in either the MJ threshold or the GST was apparent 4 weeksafter the expression of one or two generalized seizures, comparedwith when the animals left the paradigm. In addition, the acutereduction in the MJ threshold and GST observed, after the expressionof four or six generalized seizures, was not long-lasting. Onretesting, both thresholds partially recovered to a level similarto that observed on trial 2 (Table 1). The same results wereobtained if two or four generalized seizures were followed byan 8 week stimulus-free interval. By contrast, eight generalizedseizures resulted in both an acute (Fig. 2A,B) and long-term (Table1) maximal reduction in both the MJ threshold and the GST.

Table 1. Long-term changes in the generalized seizure threshold and the threshold to the first MJ: effect of the number of seizuresand the duration of the stimulus-free interval (SFI)

Trials +4 wk SFI (no.) Measured threshold (sec)^a Predicted trial (no.)^b Trials +8 wk SFI (no.) Measured threshold (sec) Predicted trial (no.) 8 Trials + weeks SFI Measured threshold (sec) Predicted trial (no.)

Generalized seizure threshold

1 315.8 ± 10.0 2.05 1 230.9 ± 11.9 4.62

2 328.3 ± 24.5 1.82 2 427.8 ± 17.4 0.21 2 220.8 ± 9.8 5.22

4 325.0 ± 20.4 1.88 4 311.8 ± 30.3 2.15 3 266.2 ± 10.7 3.27

6 282.3 ± 12.4 2.83 4 207.2 ± 9.7 6.64

8 207.2 ± 9.7 6.64

Trials +4 wk SFI (no.) Measured threshold (sec)^a Predicted trial (no.)^b Trials +8 wk SFI (no.) Measured threshold (sec) Predicted trial (no.) 8 Trials + weeks SFI Measured threshold (sec) Predicted trial (no.)

Threshold to first MJ

1 261.4 ± 17.6 1.58 1 209.4 ± 13.2 3.40

2 247.2 ± 17.9 1.94 2 256.8 ± 9.6 1.69 2 193.3 ± 10.8 4.54

4 240.8 ± 7.0 2.12 4 228.2 ± 11.6 2.55 3 232.9 ± 11.4 2.38

6 246.7 ± 17.4 1.95 4 180.0 ± 9.0 5.95

8 180.0 ± 9.0 5.95

^a Mean ± SEM of the latency (seconds) to the seizure endpoint for the sample. ^b Value is the calculated point on the x-axis for the sample threshold using the regression equation generated from the datadepicted in Figure 2. The equation is based on the grand meanof the latency to the sustained generalized seizure (y = $-$ .04x⁴ + 0.25 x³ + 5.72x² $-$ 4.39x + 443.4) or the first MJ (y = 0.09x⁴ $-$ .01x³ + 18.54x² $-$ 7.86x + 361.74) for all animals on a per-trial basis and isused to estimate the population.

There appears to be some variability in the maintenance of the threshold reduction after eight generalized seizures for boththe first MJ and GST; however, if retested 1, 2, or 4 weeks afterthe last of the 8 seizures, the reduction in the MJ thresholdwas apparently maintained, although at 1 week, there appears tobe some recovery. By comparison, when animals were retested aftera 3 week stimulus-free interval, the observed threshold is equivalentto that of trial 2 (Table 1), indicating a significant reboundof the MJ threshold over time after repeated flurothyl exposure.

The GST exhibited a similar profile. When mice were retested 1, 2, or 4 weeks after the induction of eight daily generalizedseizures, the GST corresponded to a trial value of 4.6, 5.2, and6.6, respectively, based on the regression equation (Fig. 2B,Table 1); that is, the values obtained were within the portionof the curve that is asymptotic. If, however, mice were retested3 weeks after the last trial, the GST partially recovered to avalue equivalent to trial 3 (3.3). This outcome was observed intwo independent replications, with groups of animals representedat each time point. The groups that made up a time point werenot different on either the last (1 week, t = 0.139, df = 9, p= 0.89; 2 weeks, F_(2,21) = 0.151, p = 0.86; 3 weeks, t = $-$ 0.434,df = 9, p = 0.67; 4 weeks, F_(2,14) = 3.587, p = 0.06) or retesttrial (1 week, t = $-$ 0.039, df = 9, p = 0.97; 2 weeks, F_(2,21)= 0.146, p = 0.87; 3 weeks, t = $-$ 0.099, df = 9, p = 0.92; 4 weeks,F_(2,14) = 0.242, p = 0.79).

The GST also was evaluated in a subset of animals challenged with flurothyl 50 d after their retest trial. These data demonstratedthat although there were small increases in the GST 50 d afterthe retest trial compared with the last of eight consecutive dailyseizures, the GST remained significantly altered compared withthe naive state at all points tested (Fig. 3A).
Fig. 3. The effect of 50 additional stimulus-free days after the retest trial on the GST (A) and the behavioral seizure response (B).A, The GST is significantly lower compared with the naive state(trial 1) up to 50 d after the retest trial. Data are the mean± SEM of a subset of animals rechallenged 50 d after the retesttrial, which followed a 1, 2, or 3 week stimulation-free intervalthat was preceded by eight daily seizures (n = 14); a, p < 0.001versus trial 1; b, p < 0.05 versus trial 8. B, The behavioralseizure response continues to change during an additional 50 dstimulation-free interval. Data are the median seizure score ofthe animals in A (n = 5, 6, 3; 1, 2, 3 weeks, respectively).
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Effects on generalized seizure behavior
The motor behaviors expressed during the eight trials that preceded the stimulus-free interval were almost exclusively clonic,with a median seizure score of grade 1. If, however, an animalthat exhibited eight seizures went unstimulated for a period oftime before a retest trial, these behavioral characteristics werefound to be altered as a function of the duration of the stimulus-freeinterval. After a 1 week stimulus-free interval, no change wasobserved in either the number of animals exhibiting "brainstemseizures" or the median seizure score expressed when the animalwas retested compared with the last trial (Table 2). However,by 2 weeks, a significant increase in both measures was observed.The proportion of mice exhibiting "brainstem" seizures and themedian seizure score progressively increased with longer stimulus-freeperiods (Table 2). Comparisons among groups showed that significantlymore animals expressed "brainstem seizures" after either a 2 ora 3 week stimulus-free interval than after a 1 week interval (p< 0.05, $chi$ ²), and that by 4 weeks, this effect was near maximal, with nearly100% of animals exhibiting seizure behaviors of grade 3 or above(p < 0.001 vs 1 week; p < 0.01 vs 2 weeks, $chi$ ²). No association was found between the GST and the expressionof a specific seizure behavior when the animal was retested afterthe stimulus-free interval (Spearman's $rho$ = $-$ 0.092; Fig. 4).

Table 2. Effect of the duration of the stimulus-free interval on the behavioral seizure response

Animals with behavioral seizure score $>=$ grade 3 (%)^b
Median seizure score^c

Stimulus-free interval^a n First trial Last trial Retest First trial Last trial Retest

1 week 13 0.0 15.4 15.4 1 1 1

2 weeks 24 0.0 0.0 50.0^*** 1 1 2.5^***

3 weeks 11 9.1 0.0 63.6^* 1 1 3^***

4 weeks 18 5.6 11.1 88.9^**** 1 1 4^***

^a Mice were administered 10% flurothyl by inhalation until a sustained generalized seizure was expressed. Eight trials (intertrialinterval, 24 hr) were followed by varying periods of nonexposureto the convulsant stimulus when the mouse was retested and thebehavioral seizure score assigned. ^b Values are the percent of group total expressing a behavioral seizure score of grade 3 or higher. Asterisks indicate statisticallysignificant differences between the retest trial and the lasttrial by the McNemar test; ^* p < 0.05, ^*** p < 0.005, ^**** p < 0.001. ^c Values are the median seizure scores. Asterisks indicate statistically significant differences between the retest trial andthe last trial by the Wilcoxon signed-ranks test; ^*** p < 0.001.

Fig. 4. Correlational analysis indicating a lack of association between the GST and the expression of a specific generalized seizurebehavior on retest. Threshold and behavioral measures were madeafter a 1 (solid circles), 2 (solid squares), 3 (solid triangles),or 4 (solid diamonds) week stimulus-free interval, which was precededby an induction phase of eight consecutive daily seizures (Spearman's $rho$ = $-$ 0.092).
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That the observed changes in seizure behavior do not regress and, in fact, continue to evolve with time is illustrated inFigure 3B. When rechallenged 50 d after the retest trial, themedian seizure score was found to be increased compared with theeighth trial and the retest trial (Fig. 3B). Of particular noteis the increase in the 1 week group. Whereas the behavioral seizureresponse was of the "forebrain" type on both the eighth trialand the retest trial, the predominant seizure phenotype was "brainstem"50 d later (Fig. 3B).

Because the expression of eight daily generalized seizures clearly resulted in an altered behavioral seizure profile, aftera 4 week stimulus-free interval, it was of interest to determinewhether a similar response could be elicited with fewer seizuresfollowed by an identical stimulus-free interval. One generalizedseizure was not sufficient to effect an increase in either theprobability of expressing a "brainstem seizure" or the intensityof the seizure behavior. Although some mice that experienced 2,4, or 6 generalized seizures before the stimulation-free periodwent on to express "brainstem seizure" behaviors when retested,the proportion was not significantly altered compared with thelast trial in each of the three groups (Table 3). By contrast,the induction of eight generalized seizures resulted in a significantincrease in the number of animals expressing "brainstem seizure"behaviors, when retested at 4 weeks, compared with both the lasttrial (Table 3) and the groups that had experienced 1, 2, 4,or 6 seizures before the stimulus-free interval (p < 0.01, $chi$ ²). The maximum seizure grade on the retest trial also was foundto be influenced by the number of seizures expressed (Table 3).Finally, although there is an apparent trend for the proportionof animals expressing "brainstem seizures" to increase, when retestedas a function of the number of pretreatment trials, the medianseizure score of the rechallenge trial, however, did not surpassa grade of 2 until eight seizures had been elicited before the4 week interval (Table 3).

Table 3. Effect of the number of generalized seizures on the behavioral seizure response

Animals with behavioral seizure score $>=$ grade 3 (%)^b
Median seizure score^c

No. of seizures^a n First trial Last trial Retest First trial Last trial Retest

1 5 0.0 xxx 0.0 1 1 1

2 6 0.0 0.0 16.7 1 1 1.5

4 6 0.0 0.0 33.3 1 1 2^*

6 6 0.0 0.0 33.3 1 1 2^*

8 18 5.6 11.1 88.9^**** 1 1 4^***

^a Mice were administered 10% flurothyl by inhalation until a sustained generalized seizure was expressed. A single or multiplegeneralized seizures (intertrial interval, 24 hr) were followed28 d later by a retest trial when the behavioral seizure scorewas assigned. ^b Values are the percent of group total expressing a behavioral seizure score of grade 3 or higher. Asterisks indicate statisticallysignificant differences between the retest trial and the lasttrial by the McNemar test: ^**** p < 0.001. ^c Values are the median seizure scores. Asterisks indicate statistically significant differences between the retest trial andthe last trial by the Wilcoxon signed-ranks test; ^* p < 0.05, ^*** p < 0.001.

To determine whether the failure to elicit a "brainstem seizure" at 4 weeks after the induction of fewer than eight generalizedseizures was a function of the stimulus-free interval, two orfour seizures were evoked in separate groups of animals, followedby an 8 week stimulus-free interval. All animals exhibited grade1 seizures in each trial before the 8 week stimulus-free interval.The behavioral seizure response at 8 weeks was the same comparedwith the animals that had exhibited 2 or 4 seizures before a 4week stimulus-free interval. The induction of two generalizedseizures resulted in a retest behavioral response profile thatwas characterized by a median seizure score of 1.5 and a 16.7%(1/6, both groups) probability of expressing a "brainstem seizure,"regardless of the duration of the stimulus-free interval (4 vs8 weeks). Similarly, a median seizure score of 2 resulted whenanimals were retested 4 or 8 weeks after the last of four generalizedseizures. Although 33.3% (2/6) exhibited "brainstem seizure" behaviorsat 4 weeks and 16.7% (1/6) expressed this seizure phenotype at8 weeks, the difference was not significant ( $chi$ ² = 0.44, p = 0.50).

Effect of 21 daily trials
Repeated generalized seizure induction resulted in a progressive decrease in the GST. The reduction was maximal by trial 7and exhibited no additional decline through trial 21 (Fig. 5).Daily seizure induction also resulted in a progressive increasein the proportion of animals expressing generalized seizure behaviorsof grade 3 or higher beginning on trial 11 (Fig. 5). The probabilityof expressing a "brainstem seizure" by trial 21 was similar tothat observed if the animals had experienced eight generalizedseizures, and then rechallenged, subsequent to a 2 week stimulus-freeperiod (see Table 2).
Fig. 5. Effect of 21 consecutive daily flurothyl-induced generalized seizures on the GST and the generalized seizure phenotype. Pointsrepresent the mean GST ± SEM of six animals. The bars representthe proportion of generalized seizures that were "brainstem seizures"within a defined "bin." A bin is composed of the total numberof seizures in regular three trial intervals. Continuing stimulationfor 2 weeks beyond the first eight trials did not significantlyalter the proportion of mice expressing "brainstem seizures" (cf.Table 2).
[View Larger Version of this Image (17K GIF file)]

DISCUSSION
This study characterizes a model of epileptogenesis in which the repeated induction of generalized seizure activity elicitedby flurothyl modifies the acute and long-term behavioral responseof the animal to the convulsant stimulus. Consistent with previousreports, daily exposure to flurothyl was associated with a progressivedecrease in both the GST and the latency to the first MJ (Adleret al., 1967; Prichard et al., 1969). The present findings showthat although the acute reduction in both seizure thresholds wascomplete by trial 5, eight generalized seizures were necessaryfor the reduction to be long-lasting. The present study also demonstratesthat proepileptogenic processes are triggered by eight daily flurothyl-inducedgeneralized seizures and continue to evolve in the absence ofadditional seizure induction. The long-term changes in neuralfunction that develop during the stimulus-free period were foundto be manifest primarily as a qualitative change in the phenotypeof the seizure expressed. The degree of change in seizure typewas dependent on both the duration of the stimulus-free intervaland the number of seizures elicited before this interval.

Changes in seizure threshold
Altered seizure susceptibility is a well-documented result of repeated seizure activity (Adler et al., 1967; Goddard et al.,1969; Prichard et al., 1969; Mason and Cooper, 1972; Racine, 1972;Cain, 1980; Sangdee et al., 1982). In the present study, the expressionof a single generalized clonic seizure was sufficient to producea significant reduction in the latency to both the first MJ andthe sustained generalized seizure when retested 24 hr later. Boththresholds continued to decline with each subsequent trial untiltrials 4-5, at which time, no additional changes were observed.These threshold profiles suggest that the neural mechanism(s)responsible for the increase in seizure susceptibility can beinduced by a single seizure event. Moreover, the processes responsibleare apparently reinforced with each additional seizure until athreshold "floor" is reached at the fifth trial. Because flurothyldoes not depend on metabolism, either for its action or for itselimination, and because the concentration of flurothyl in brainafter inhalation is not altered by repeated exposure (Gallagher,1969), the change in seizure threshold is most likely attributableto repeated ictal activity rather than to changes in the pharmacokineticsof the drug.

The number of seizures was an important factor in determining whether decreases in seizure threshold were maintained overa stimulus-free interval. Despite the fact that by the fifth trial,seizure thresholds for both the first MJ and the GST were maximallyreduced, this was not sufficient for the change to be long-lasting.For example, the expression of six generalized seizures resultedin a significant and maximal reduction in the GST. However, sixseizures were not sufficient to induce a long-lasting, maximalchange in the GST. Maximal threshold changes were maintained onlyafter the expression of eight seizures. These data suggest thata minimum degree of input is necessary to reinforce alterationsin neuronal excitability, such that the modified susceptibilityis long-lasting.

An unexpected outcome of the threshold analysis was the observed variability in seizure thresholds measured after differentstimulus-free intervals. Although the GST was consistently loweron the retest trial in all groups of mice compared with naiveanimals, there was partial recovery of the GST in all groups.The most pronounced recovery was observed after a 3 week stimulus-freeinterval. At this time point, both thresholds had recovered toa level equivalent to trial 3. This partial recovery was apparentlyreal, because two independent replications were performed withseparate groups of animals represented at each time point. Thesedata suggest that there are active processes that attempt to reestablishthe basal threshold. The fact that the threshold, after a 4 weekstimulus-free interval, was nearly identical to that observedon the last of eight trials indicates that these processes eitherfail or are in a state of continuous flux. Regardless, it is clearthat the GST is permanently altered compared with the naive state,because animals tested 50 d after a specified stimulus-free intervalpresented with a GST significantly different from that observedon the first trial.

Changes in seizure behavior
Terminating the administration of flurothyl and opening the chamber with the beginning of sustained motor seizure activityresulted in the expression of predominantly generalized clonicseizure behaviors over the course of eight daily trials. However,after a 2-4 week stimulus-free interval, a different behavioralresponse resulted when the animal was retested. This responsewas characterized first by the expression of a generalized clonicseizure lasting ~15-20 sec, followed by the progression, withoutinterruption, to a qualitatively distinct set of motor behaviorsconsisting of an initial running/bouncing episode, and the progressionto seizures with tonic manifestations. This progression was stereotyped,in that generalized clonic seizure behaviors always preceded running/bouncingseizure events, which in turn always preceded the expression offorelimb/hindlimb treading or seizures with tonic components (seeFig. 1B). In a naive animal, this progression from clonic to running/bouncingto tonic seizures is rarely seen using our protocols.

The motor components of generalized seizures in experimental animals have been shown to be associated with specific anatomicalsystems. Whereas generalized clonic seizures require the integrityof forebrain structures for their expression (Browning and Nelson,1986; Magistris et al., 1988; Browning et al., 1993), brainstemcircuitry is both necessary and sufficient for the expressionof running/bouncing and tonic motor manifestations (Kreindleret al., 1958; Browning and Nelson, 1986). Thus, the progressionof flurothyl-induced seizure behaviors seen after exposure toour paradigm appears to be the result of an initial activationof the forebrain system followed rapidly by activation of thebrainstem seizure system. This finding suggests that the epileptogenicprocesses triggered by the repeated induction of generalized clonicseizure activity alter neural systems such that recruitment ofbrainstem circuitry by the forebrain is facilitated.

The mechanism by which facilitated recruitment of the brainstem seizure system occurs, after exposure to our paradigm, isunknown. However, this effect could be mediated by (1) a loweringof the threshold for activation of the brainstem seizure system,(2) facilitated propagation of seizure activity between the forebrainand brainstem systems, or (3) a combination of facilitated propagationand lowered brainstem seizure system threshold. Which of thesepossibilities is correct has major implications for concepts ofthe organization of seizure expression systems in the brain andthe effects of repeated seizure activity on those systems. Forexample, if exposure to our paradigm simply lowers the thresholdfor activation of the brainstem seizure system, then forebrainseizure activity must always access the brainstem system. In theseizure-naive state, however, brainstem seizures are not expressed,because forebrain-driven discharge fails to exceed the thresholdfor initiating seizure activity in the brainstem. By contrast,if facilitated propagation from the forebrain to the brainstemis solely responsible for the change in phenotype in our model,then exposure to our paradigm would be conceived of as promotinga fundamental change in the interaction between the forebrainand brainstem seizure systems; that is, in the seizure-naive state,these systems are independent, and seizure activity elicited ineither system is confined to that system. After exposure to ourparadigm, however, the propagation of forebrain seizure activityto the brainstem system is facilitated through the establishmentof a new propagation network. Experiments are currently beingconducted to establish the basis for the reliable change in seizurephenotype observed in our model.

The finding that a significant shift in the behavioral response occurs when an animal is retested after a stimulus-free intervalindicates that seizure-induced changes within the brain continueto evolve independent of additional stimulation. However, theprogression from a purely generalized clonic seizure to a seizureconsisting of "brainstem seizure" behaviors was not observed inall animals when retested after the stimulus-free interval. Instead,the probability of this occurrence and the phenotype of the seizurewere found to be associated with both the duration of the stimulus-freeinterval that preceded the retest trial and the number of seizuresinduced before this interval. A significant increase in the numberof animals exhibiting behaviors of grade 3 or above was observedonly if the animal had experienced eight generalized seizuresand at least a 2 week stimulus-free interval before retesting.By contrast, fewer than eight seizures did not affect the behavioralresponse compared with the last trial, regardless of whether theduration of the stimulus-free interval was 4 or 8 weeks. Thesedata suggest that a minimum of seven or eight generalized seizureevents are necessary to elicit a change in the behavioral seizureresponse. This minimum appears to be an absolute, because fewerthan eight seizures did not reliably result in a change in seizuretype, whether given 4 or 8 weeks to develop. Furthermore, onceinduced, the epileptogenic processes progressively develop inthe absence of continued input, such that the probability of exhibitingthe behavioral progression is directly related to the durationof the stimulus-free interval.

Other lines of evidence suggest that generalized seizure activity induces changes within the brain that are time-dependentand develop in the absence of additional input. For example, cytochromeoxidase activity is unchanged 24 hr after the last of a seriesof eight generalized electroconvulsive shock seizures, but isincreased in a number of brain areas 28 d after the last seizure(Nobrega et al., 1993). Moreover, a single electroshock stimulus,when followed by a treatment-free interval, is as effective inreducing nigral dopamine autoreceptor subsensitivity as is theadministration of repeated electroshock seizures (Chiodo and Antelman,1980). Furthermore, clinical studies have shown that on the recurrenceof seizure activity after a "silent interval," patients presentwith more complex behavioral manifestations than before the seizure-freeinterval (French et al., 1993). Together, these data demonstratethat some of the long-term consequences associated with seizureactivity develop during a period in which overt clinical seizuresare not evident.

An intriguing result of the present study is the observation that the mechanism(s) responsible for the change in seizure phenotypeoccurs equally in the presence or absence of continued daily seizureinduction past trial 8. This raises the possibility that animalsallowed to have a stimulus-free period before retesting experiencedspontaneous ictal activity. During the times when mice were periodicallymonitored, over the course of the stimulus-free interval, we havenever observed any overt motor seizure activity. This does notpreclude the possibility that spontaneous subclinical seizureactivity occurred during this interval. Regardless, this studyhas demonstrated that in either case, the mechanism(s) involvedrequires a minimum of eight generalized seizures to be triggered,which then progressively evolve over a defined time frame.

GST and seizure phenotype
Exposure to our paradigm initiates a process that results in a lowering of GST acutely, which is then variably maintainedin a lowered state for at least 71 d. Exposure to our paradigmalso initiates a process that evolves only slowly over time andthat promotes a change in the final type of seizure expressedby the animal. Correlational analyses indicate a lack of associationbetween measures of GST and the change in seizure phenotype. Thisoutcome suggests that the underlying processes mediating the reductionin GST may be independent from the processes underlying the changein seizure phenotype from clonic to tonic.

Because the initial seizure manifestation in response to flurothyl is always clonic, the latency to clonic seizure onset representsa measure of the threshold for the forebrain seizure system. Repeatedflurothyl exposure has been reported to lower the focal forebrainafterdischarge thresholds of both the amygdala and the frontalcortex and to facilitate the rate of electrical kindling fromboth of these structures (Okada et al., 1985; Wong and Moshe,1987). We have observed identical effects for olfactory bulb kindlingin mice preexposed to our paradigm (our unpublished observations).These data suggest that repeated flurothyl-induced seizures notonly lower forebrain seizure threshold but also facilitate seizurepropagation within the forebrain. Thus, within the forebrain seizuresystem, exposure to our paradigm promotes apparently identicaleffects to those seen after electrical kindling from the limbicsystem. In addition, the outcome of a recent pharmacological studyfrom our laboratory indicates that drugs effective at blockingthe development of electrical kindling also effectively blockthe change in seizure phenotype observed after exposure to ourmodel (Applegate et al., 1997). These data indicate that the synapticmechanisms underlying epileptogenic processes in electrical kindlingand our model system share considerable overlap.

Whether repeated flurothyl-induced seizures lower the threshold and/or facilitates propagation in the brainstem seizure systemis currently unknown. However, previous amygdala kindling to fiveconsecutive stage 5 seizures has been shown to increase the probabilityof tonic hindlimb extension after corneal electroshock stimulation(Applegate et al., 1991). These data suggest that repeated forebrainafterdischarge activity can significantly influence the brainstemseizure system. Experiments are currently underway to elucidatefurther the mechanisms through which these effects are mediated.

In summary, this study describes a model of epileptogenesis in which the repeated induction of generalized clonic seizureactivity results in time-dependent changes in neural functionthat can evolve in the absence of continued seizure induction.Initial alterations involve reductions in the seizure threshold.Mechanisms that require more time to develop and, once initiated,can evolve in the absence of additional input, are manifest primarilyas an erosion of the separation between the two anatomical systemsthat mediate generalized seizure behaviors. Thus, the barrierthat prevents "forebrain seizure" activity from recruiting "brainstemseizure" systems is altered in such a way as to allow the expressionof "brainstem seizure" behaviors. Because the process that promoteschanges in the behavioral response of the animal occurs in theabsence of continued seizure induction, this model may be usefulin studying the mechanisms that underlie increases in seizuresusceptibility and the development of motor seizures, withoutthe confounding influence of an ictal event.

FOOTNOTES

Received Aug. 23, 1996; revised April 21, 1997; accepted April 24, 1997.

This work was supported by National Institutes of Health Grant NS26865 to C.D.A.

Preliminary results of this study have been published in abstract form at the 24th Annual Meeting, Society for Neuroscience,1994.

Correspondence should be addressed to Prof. Craig D. Applegate, Box 605, University of Rochester School of Medicine and Dentistry,601 Elmwood Avenue, Rochester, NY 14642.

Dr. Samoriski's present address: Department of Pharmacology and Physiology, Box 711, University of Rochester School of Medicineand Dentistry, 601 Elmwood Avenue, Rochester, NY 14642.

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