Sleep States Differentiate Single Neuron Activity Recorded from Human Epileptic Hippocampus, Entorhinal Cortex, and Subiculum

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The Journal of Neuroscience, July 1, 2002, 22(13):5694-5704

Sleep States Differentiate Single Neuron Activity Recorded from Human Epileptic Hippocampus, Entorhinal Cortex, and Subiculum
Richard J. Staba¹, Charles L. Wilson²^,⁴, Anatol Bragin²^,⁴, Itzhak Fried³^,⁴, and Jerome Engel Jr¹^,²^,⁴
Departments of ¹ Neurobiology, ² Neurology, and ³ Neurosurgery, and ⁴ The Brain Research Institute, David Greffen School of Medicine at University of California Los Angeles, Los Angeles, California 90095

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Animal models of epilepsy have shown that synchronous burst firing is associated with epileptogenesis, yet the evidence fromhuman studies linking neuronal synchrony and burst firing to epileptogenesisremains equivocal. Sleep-wake states have been shown to differentiallymodulate the generation of epileptiform EEG spikes between brainregions of greater and lesser seizure-generating potential, providinginformation that helps to identify the primary epileptogenic region.Using these state-dependent mechanisms to assist us in identifyingneuronal correlates of human epilepsy, we recorded interictalneuronal activity from mesial temporal lobe (MTL) areas in epilepticpatients implanted with depth electrodes required for medicaldiagnosis during polysomnographically defined sleep-wake states.Results show that single neurons recorded ipsilateral to seizure-initiatingMTL ("epileptic") areas had significantly higher firing rates(p = 0.01) and burst propensity (p = 0.01) and greater synchronyof discharges (p = 0.003) compared with neurons recorded fromcontralateral non-seizure-generating MTL ("non-epileptic") areas.In particular, during episodes of slow wave sleep (SWS) and rapideye movement (REM) sleep, epileptic hippocampal neurons had significantlyhigher burst rates compared with non-epileptic hippocampal neurons(both p = 0.01). In contrast, during episodes of wakefulness (Aw),no difference in burst firing between epileptic and non-epileptichippocampal neurons was observed. Furthermore, synchronous firingwas significantly higher between epileptic MTL neurons comparedwith non-epileptic MTL neurons during SWS (p = 0.04) and REM sleep(p = 0.02), but no difference in neuronal synchrony was foundbetween epileptic and non-epileptic neurons during Aw. These resultsprovide evidence that sleep states differentially modulate abnormalepileptogenic neuronal discharge properties within human MTL andconfirm that neuronal burst firing and enhanced neuronal synchronyobserved in experimental animal models of epilepsy characterizeshuman epilepsy aswell.

Key words: slow wave sleep; REM sleep; bursting; synchrony; epilepsy; limbic system

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Numerous studies using animal models of epilepsy have shown that synchronous neuronal burst firing is associated with epileptogenicity(Wyler et al., 1975; Schwartzkroin and Prince, 1977; Perez-Velazquezet al., 1994; Jensen and Yaari, 1997; Scharfman et al., 2001).In contrast, investigations of the neuronal electrophysiologicalcorrelates of human epilepsy are few, and the evidence from humaninterictal recordings that does exist does not strongly agreewith the data from experimental animal models. For example, Wylerand colleagues (1982) rarely observed synchronous firing betweensingle neurons within epileptogenic areas except at the onsetof an ictal event. Other investigators have reported either nodifference in the distribution of burst-firing neurons or a reductionin burst firing among neurons recorded ipsilateral to seizure-generatingregions compared with neurons within contralateral homotopic areas(Isokawa-Akesson et al., 1989; Colder et al., 1996a; Telfeianet al., 1999).

Most of the evidence of human neuronal correlates of epileptogenicity derives from either in vitro studies (Prince and Wong,1981) or in vivo recordings without attention to behavioral state(Wyler and Ward, 1981; Babb et al., 1987; Isokawa-Akesson et al.,1987, 1989; Colder et al., 1996a-c). However, an extensive literatureindicates that epileptiform EEG abnormalities and clinical seizuresare generally influenced by changes in state of vigilance, alertness,or awareness, such as those during the sleep-wake cycle (Autretet al., 1997; Jobst et al., 2001; Mendez and Radtke, 2001). Typically,episodes of non-rapid eye movement (NREM) sleep are associatedwith an increase in epileptogenicity, whereas episodes of REMsleep are associated with a reduction in epileptogenicity (Shouseet al., 2000). Investigations into the cellular mechanisms involvedin the generation of the characteristic EEG patterns associatedwith sleep states offer important insights into the activationof epileptiform activity during sleep (Steriade and Contreras,1995). Networks of cortical neurons involved in synchronizingthalamically generated $delta$ oscillations that occur during slow wavesleep (SWS) may serve as the preferential substrate for epileptiformspike-wave activity (Steriade et al., 1998). Furthermore, polysomnographicstudies of human epilepsy have provided evidence that brain regionsconsistently initiating seizures generate epileptiform EEG eventsthat are more autonomous than non-seizure-initiating regions,i.e., they demonstrate less rate change across sleep-wake states.This information can be used to help localize the primary epileptogenicarea for surgery (Lieb et al., 1980; Rossi et al., 1984; Sammaritanoet al., 1991).

Given the importance of comparing human epileptogenic neuronal activity with that found in animal models of epilepsy, andthe utility of polysomnography as an investigative tool, we askedwhether changes across the sleep-wake cycle would affect the firingof neurons recorded ipsilateral to seizure-generating mesial temporallobe (MTL) areas differently than it affects neurons recordedfrom contralateral MTL areas where seizure initiation did notoccur. Interictal neuronal activity was recorded in epilepticpatients implanted with depth electrodes required for medicaldiagnosis and was quantitatively evaluated during polysomnographicallydefined episodes of waking (Aw), SWS, and REM sleep. Measuresof firing rate, burst propensity, and synchronous discharge werethus compared on the basis of epileptogenicity (ability of brainregion to generate spontaneous seizures), sleep-waking state,and anatomical structure to identify single neuron discharge correlatesofepileptogenesis.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Subjects. Interictal recordings were obtained from 17 patients with medically intractable complex partial seizures. Beforeclinically required depth electrode implantation for the investigationand localization of seizure onset area, patients gave their informedconsent for participation in these research studies under theapproval of the University of California Los Angeles (UCLA) InternalReview Board. Each patient was surgically implanted with 8-14flexible polyurethane clinical depth electrodes (1.25 mm diameter)stereotactically targeted to clinically relevant brain areas.These electrodes were monitored on a 24 hr basis along with videobehavioral monitoring to find those brain areas in which spontaneousseizure activity began first (Fried et al., 1999). Patients inwhom a seizure onset area could be localized became candidatesfor surgical removal of epileptic sites if resection of the areawould not produce any unacceptable neurological deficit. Localizationof the seizure onset zone was based on the recording of 3-10 seizuresduring the average 2 weeks that patients spent in the hospital.For each subject, functional and anatomical data from depth electroderecordings and neuroimaging were used to identify the epileptogenicregion (Engel, 1996).

Electrodes and localization. Neuronal activity was recorded from bundles of nine platinum-iridium microwires, which were insertedthrough the lumen of the seven-contact clinical depth electrodes,so that they extended 3-5 mm beyond the tip of the clinical electrode.Microwires were 40 µm in diameter with impedances ranging from200 and 500 k $Omega$ . Electrode tips were localized using the combinedinformation from post-implant computed tomography (CT) scans co-registeredwith pre-implant 1.5 T magnetic resonance imaging (MRI) scansand skull x-ray films (Fig. 1). The imaging software that wasused (Brain Navigator, Grass-Telefactor Corp., Philadelphia, PA)allowed for visualization and highlighting of electrode tip locationson CT scans, which were automatically registered to the MRI scans.Anatomical boundaries were based on references of mesial temporallobe anatomy by Duvernoy (1998) and Amaral and Insausti (1990).Only microwires verified to be located in hippocampus (Hip), subiculum(Sub), and entorhinal cortex (EC) were used in analyses.

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Figure 1. Electrode tips were localized using post-implant CT images co-registered with pre-implant MRI scans. A, An axial CT image from patient 316 shows three electrodes within the plane from which this slice was taken. Areas of bright signal intensity inside the contours of the skull designate clinical electrode contacts and microwire bundles. The white arrow points to one of the microelectrode bundles extending beyond the distal tip of a clinical electrode. B, A coronal MRI scan co-registered with the axial CT image shown above reveals that the microelectrode bundle highlighted in A was located within the left hippocampus (microelectrodeindicated by black + within hippocampus, marked H). An arrow also points to subiculum, marked S (no microelectrode shown). C, MRI scans were reconstructed in the axial (data not shown) and sagittal planes to locate the position of electrodes in three dimensions. This sagittal MRI scan, reconstructed from the coronal MRI shown in B, shows the position of the microelectrode (black +) within the middle hippocampus. Two black lines demarcate the boundaries of the anterior (A), middle (M), and posterior (P) areas of the hippocampus.

Overnight polysomnographic sleep studies. Sleep studies were conducted on the hospital ward within each subject's room. Studieswere conducted 48-72 hr after surgery and typically began betweenthe hours of 10 P.M. and midnight and ended at 7 A.M. the followingmorning. Patients continued taking their standard doses of anticonvulsantmedications during this period. Sleep staging was performed accordingto the criteria of Rechtschaffen and Kales (1968). The sleep montageconsisted of two disc electrodes placed supra- and infra-orbitallyto record eye movements; two disc electrodes were placed on thechin to record submental muscle tone, and two O-Flexon stainlesssteel needle electrodes were placed during surgery at "10-20"positions C3 and C4 on the scalp, with each referred to the contralateralauris externa to record cortical EEG activity. Sleep-wake stageswere categorized as waking, stages 1 through 4 sleep, and rapideye movement sleep. Single neurons recorded during the stagesdefined as Aw, stages 3 and 4, from herein referred to as SWS,and REM sleep were analyzed for firing rate, bursting activity,and synchrony of discharges. Sleep stages 1 and 2 were not includedfor analyses to better contrast neuronal activity during statesof wakefulness and non-REMsleep.

Electrophysiology and data analysis. Continuous EEG was recorded wide band (0.1 Hz-5 kHz) and sampled at 10 kHz with 12-bitprecision using RC Electronics software (Santa Barbara, CA). Datafiles containing up to 16 channels of EEG were copied onto compactdisc for off-line analysis. Channels were visually examined forthe presence of neuronal activity and high-pass filtered at 300Hz with 36 dB roll-off (Fig. 2A). Extracellularly recorded actionpotentials with amplitude >3:1 signal-to-noise were triggeredand separated using DataWave Technologies, CP Analysis software(Longmont, CO). Separation of action potentials ("spikes") representingthe activity from a single neuron was performed using a spikewaveform-based "cluster-cutting" technique described previously(Staba et al., 2002). Briefly, spike waveform attributes, likethe two illustrated in Figure 2B, were extracted from each triggeredspike and plotted on x-y scatterplots. Spikes with similar attributeswould form clusters and would be grouped. To confirm the accurateplacement of cluster boundaries and to remove any remaining artifacts,spike waveforms were visually inspected, and autocorrelogramswere constructed with a time base of 100 msec and bin-width of1 msec for each single neuron (Fig. 2C). A spike train with anabsence of spikes within the 0-2 msec bins (refractory period)was considered a single neuron. A spike train with counts greaterthan mean firing frequency during the refractory period was consideredmultiple neurons and reclustered. During reclustering, a spiketrain with an absence of a clear refractory period was termedmultiple neuron activity and omitted from the analysis. Cross-correlogramswith 1 msec bin-widths were constructed for all simultaneouslyrecorded neurons. Pairs of neurons recorded on different microwiresin the same electrode bundle that demonstrated 0 msec coincidentinteractions exceeding 99% confidence (Abeles, 1982) were consideredthe same neuron, and one neuron was eliminated.

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Figure 2. Single neuron detection and separation based on a waveform clustering method. A, High-pass-filtered signal (300 Hz) used in triggering spike waveforms. Asterisk denotes burst of spikes (action potentials). B, Waveform separation using cluster-cutting method. Spike waveform attributes, such as peak amplitude and first positive peak amplitude, are plotted on x-y scatterplots. Waveforms with similar attributes tend to form clusters and are grouped as representative of the activity from putative single neurons. Shown above the scatterplot are the averaged waveforms of the spikes within each cluster. C, Autocorrelograms of spike activity from neuron 1 (C1) and neuron 2 (C2). Note the absence of any spikes in bins after time 0 and <5 msec, indicating that no spikes occurred within the refractory period of the neuron. Bin width = 1 msec.

Neuronal discharge activity was characterized by measuring mean firing rate and number of bursts per minute (burst rate).Burst detection involved serially scanning each spike train toidentify short-duration, high-frequency discharge episodes. Aburst was defined as a set of at least three consecutive spikeswith all intervals <20 msec; moreover, the set had to be bothpreceded and followed by at least one interval >20 msec. Synchronousdischarge was evaluated through the construction of cross-correlogramswith a time base of ±800 msec and bin-width of 10 msec. Significantsynchronous discharge was determined by the appearance of peaksexceeding the 99% confidence interval based on the mean numberof coincidences expected by chance. Cross-correlograms were theninterpolated with a cubic spline (up sampling factor of 10), andsignificant peak area was integrated with Euler's trapezoidalmethod to determine duration of time lead or lag. Strength ofinteraction was assessed by measuring the area under the significantcentral peak and above the mean firing rate. Areas were normalizedby dividing by the mean number of coincident discharges that wouldbe expected to occur by chance for each pair of neurons. Neuronsthat were successfully recorded during Aw, SWS, and REM sleepfor at least 600 sec in each state were included in theanalysis.

Classification of single neuron pathology. To identify single neuron recording sites as "epileptic," two major criteria wereused: electrographic seizure onsets and hippocampal atrophy. Electrographicseizure onsets were recorded during the patient's depth electrodetelemetry monitoring, and attending neurologists in the UCLA SeizureDisorders Center identified locations of seizure onset on thebasis of these recordings. A single neuroradiologist at UCLA evaluatedevery patient's MRI scans for the presence or absence of hippocampalatrophy and its location as part of the clinical evaluation. Recordingsites were defined as epileptic if located ipsilateral to areasof seizure onset and either ipsilateral or contralateral to hippocampalatrophy. Also defined as epileptic were all recording sites locatedin MTL structures of patients (n = 3) with bilateral ictal onsets.Recording sites were defined as "non-epileptic" if seizure initiationand hippocampal atrophy were located contralaterally, or if seizureinitiation was contralateral and no atrophy was detected. Recordingssites contralateral to seizure onset and ipsilateral to hippocampalatrophy were excluded fromanalyses.

Statistical analysis. Discharge variables were analyzed using a three-factor repeated measures ANOVA design. The factors usedin the statistical model were anatomical structure or "recordingsite" (EC, Hip, and Sub) and "epileptogenicity" (epileptic andnon-epileptic) as the between group factors, and "state" (Aw,SWS, and REM sleep) as the within group or repeated measures factor.Consistent with the requirement for normality, dependent variableswere transformed with a logarithmic function such that Y' = log(Y). Post hoc analyses of all significant main effects and interactionsin the ANOVA model were performed using Scheffé's test for betweengroup comparisons and Tukey-Kramer test for within group comparisons.Comparison of the proportion of significant cross-correlationsbetween epileptic and non-epileptic neurons across the three stateswas performed using $chi$ ² test. Comparison of the strength of significant firing interactionof these cross-correlations was performed using two-way ANOVAwith epileptogenicity and state as the two factors. Significancelevel for all statistical tests was set at p $<=$ 0.05.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Single neuron population

A total of 105 well isolated single neurons were recorded from the temporal lobes of 17 patients. Thirty-one single neuronsrecorded in 11 patients did not meet the sampling criterion ofbeing successfully recorded during all three states. For the remaining74 single neurons, a total of 40.4 hr of interictal activity from13 patients was analyzed during polysomnographically defined statesof Aw, SWS, and REMsleep.

Location of recording electrodes

Locations of recording electrode tips were visualized with 1.0 mm MRI coronal slices (for technique, see Materials and Methodsand Fig. 1). Table 1 shows the number of single neurons recordedfrom each MTL area. Starting at the anterior-most point and proceedingposteriorly along the longitudinal axis of the Hip, 22 of the42 Hip neurons were located within the anterior hippocampal region(also known as uncal hippocampus or pes hippocampi). Ten Hip neuronswere located in the middle or body of the hippocampus (at anterior-posteriorlevels identified by the presence of the lateral geniculate nucleion the coronal slices), although the remaining 10 neurons werelocated in the posterior hippocampus or hippocampal tail. Theblack lines on the sagittal MRI section shown in Figure 1C demarcatethe boundaries of the three hippocampal areas. The 13 Sub neuronswere located in subicular complex beginning posterior and inferiorto the amygdalohippocampal border and extending posteriorly throughlevels immediately preceding the presence of the lateral geniculatenuclei identified on coronal slices (Fig. 1B). The 19 EC neuronswere located within cortical areas beginning anterior and inferiorto levels identified by the hippocampal head and extending posteriorlyto levels in which the body of the hippocampus becomes visiblydistinct from the head of the hippocampus. The EC area is limitedto that designated anterior hippocampus in the sagittal sectionin Figure 1C.


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Table 1. Number of single neurons recorded within each mesial temporal lobe structure and segregated based on pathology

Results from non-primate studies suggest that a functional differentiation may exist along the septotemporal axis of the hippocampusbased on differences between dorsal and ventral neuronal dischargeproperties and place field selectivity (for review, see Moserand Moser, 1998). To assess whether there may be differences inneuronal discharge rate and bursting along the anterior-posterioraxis of the human hippocampus, we compared discharge propertiesamong all neurons recorded within anterior, middle, and posteriorhippocampal areas during sleep-wake states. Our results showedthat there was no distinction among the different human hippocampalrecording sites on the basis of mean firing rate (F_(2,123) = 0.29;p = 0.7) or burst rate (F_(2,123) = 1.01; p = 0.3). Additionally,changes across states did not assist in differentiating neuronsrecorded from the three hippocampal areas on the basis of firingrate (F_(4,117) = 1.29; p = 0.2) or burst rate (F_(4,117) = 1.34;p = 0.2). For these reasons, hippocampal neurons recorded fromanterior, middle, and posterior regions were combined and analyzedas agroup.

Proximity of recording sites to pathology

Of the 74 single neurons analyzed (Table 1), 36 were recorded ipsilateral to areas generating spontaneous seizures (epileptic).Twenty-one of these 36 neurons recorded were also ipsilateralto atrophic hippocampi. The remaining 15 neurons were recordedfrom patients without detectable atrophy in either hippocampus.The MTL neurons that we recorded ipsilateral to seizure onsetslocalized to the frontal lobe did not meet the sampling criterionof being successfully recorded during all three states. Thirty-eightof the 74 total neurons were recorded contralateral to area ofseizure onset (non-epileptic). Of the 38 neurons recorded withinnon-epileptic areas, 15 neurons were recorded contralateral toatrophic hippocampi, although the remaining 23 were recorded frompatients without detectable hippocampal atrophy. Additionally,6 of the 38 neurons recorded within non-epileptic areas were recordedcontralateral to seizure onsets localized to the frontal lobe,although the remaining 32 neurons were contralateral to epilepticmesial temporal lobesites.

Epileptogenicity: epileptic versus non-epileptic

Figure 3A shows that overall single neurons within epileptic areas had significantly higher firing rates compared with neuronsrecorded from non-epileptic areas (F_(1,220) = 5.19; p = 0.02).The mean (±SE) firing rate of epileptic neurons was 4.26 ± 0.33spikes per second compared with the mean firing rate of non-epilepticneurons of 2.95 ± 0.29 spikes per second (p = 0.01).

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Figure 3. Effects of epileptogenicity on mean single-neuron firing rate and burst rate. A, Neurons recorded within epileptic areas had significantly higher firing rates compared with neurons recorded in non-epileptic areas (firing rate reported as action potential or spikes per second). B, Mean burst rates were significantly higher for epileptic neurons compared with non-epileptic neurons. Values are mean ± SE in this and the remaining figures. *p = 0.01.

Spike bursts, like the ones illustrated in Figure 4, A and B, were detected from single neurons recorded within epilepticand non-epileptic areas. As can be seen in the raster plots inFigure 4, A and B, the single neuron recorded within epilepticHip demonstrates an irregular burst firing pattern (bursts denotedby black triangles) compared with less frequently occurring burstdischarge of the neuron recorded within non-epileptic Hip. Autocorrelograms(Fig. 4A,B) further illustrate the propensity for the epilepticneuron to discharge at short interspike intervals (ISIs) comparedwith the non-epileptic neuron. Neurons recorded within epilepticareas had significantly higher burst rates (number of bursts perminute) compared with neurons within non-epileptic areas (F_(1,220)= 4.20; p = 0.04) (Fig. 3B). Figure 3B shows that the mean burstrate of neurons recorded from epileptic areas was 11.22 ± 1.52bursts per minute compared with 5.79 ± 0.85 bursts per minutefor neurons recorded from non-epileptic areas (p = 0.01). Themean ISI within bursts was significantly shorter for epilepticneurons (10.4 ± 0.19 msec) compared with non-epileptic neurons(11.4 ± 0.23 msec; F_(1,181) = 4.17; p = 0.04). No significantdifference was observed in the mean number of spikes found withineach burst event between epileptic and non-epileptic neurons (3.7± 0.07 spikes per burst vs 3.5 ± 0.05 spikes per burst, respectively).

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Figure 4. Burst firing from single neurons recorded within epileptic and non-epileptic hippocampal areas. The top two traces (A, B) illustrate a typical burst event detected from two single hippocampal neurons. To the right of each trace are the autocorrelograms for each neuron. The burst event on the left (A) was recorded from a neuron located within the left posterior, non-atrophic hippocampus of a patient who had seizures initiating from the left mesial temporal lobe. The burst event on the right (B) came from a neuron recorded within the left middle hippocampus of a different patient who had seizures initiating from the right mesial temporal lobe that contained a right sclerotic hippocampus. The two raster plots show 600 sec of discharge activity recorded during SWS from the two neurons illustrated above, respectively. Note the more frequently occurring bursts (denoted by black triangles above tick marks) and longer intervals of discharge suppression from the neuron recorded within the epileptic Hip compared with the neuron from the non-epileptic Hip. Inset (top right), Bar graph shows burst rate for each neuron. Mean firing rate for each neuron was 1.9 spikes per second. Because of the slow sweep speed, individual spikes are not distinguishable during periods of burst discharge but appear as a dense clustering of tick marks. Calibration: A, B, 10 msec.

To assess the extent of synchronous discharge, we constructed cross-correlograms, like the one in Figure 5A, for all simultaneouslyrecorded pairs of neurons. Of the 381 cross-correlograms constructed,93 cross-correlograms had a significant peak that occurred aroundthe origin, indicating that these neuronal pairs were dischargingsynchronously. More than 95% of significant correlations occurredbetween neurons recorded on individual tips of single microwirebundles (tips separated by millimeters), whereas <5% of significantcorrelations were found between neurons recorded on tips of microwirebundles from two different depth electrodes (separated by centimeters).Because 16% of epileptic neurons and 30% of non-epileptic neuronsdischarged at rates <1 spike per second, we were unable to reliablydetect significant negative interactions (appearance of a centraltrough in cross-correlogram) between neuronal pairs. Seventy-eightof the 93 (84%) cross-correlograms had significant peak interactionsthat occurred within ±20 msec of time 0 msec. The remaining 15cross-correlograms had peaks that occurred within ±200 msec oftime 0 msec. By quantifying the incidence of synchronous firing,our results showed that there was a greater proportion of significantcross-correlations between pairs of neurons recorded within epilepticareas compared with neuron pairs recorded in non-epileptic areas(Fig. 5B). Thirty-one percent of the total cross-correlations(n = 189) between neuronal pairs recorded within epileptic areasidentified synchronous firing compared with 18% of cross-correlations(n = 192) between neuronal pairs within non-epileptic areas ( $chi$ ² = 8.70; df = 1; p = 0.003). There was no difference in the proportionof cross-correlograms between pairs of epileptic neurons recordedwithin the same structure (94%) compared with the number of cross-correlogramsbetween pairs of non-epileptic neurons recorded within the samestructure (85%; p > 0.05). We measured the strength of coincidentdischarge between simultaneously recorded neurons that demonstrateda significant firing interaction by calculating the area belowthe peak of the cross-correlograms (Fig. 5A, area illustratedby shaded peak) and compared the strength of synchronous firingbetween epileptic and non-epileptic neurons. Although the tendencyfor epileptic neurons to fire synchronously was significantlygreater compared with non-epileptic neurons, the results of thisanalysis showed no overall difference in the strength of synchronousfiring between epileptic and non-epileptic neurons (F_(1,91) =1.58; p = 0.2).

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Figure 5. Cross-correlation analysis between single neurons recorded in epileptic regions compared with single neurons recorded within non-epileptic regions. A, Cross-correlogram of a pair of single neurons simultaneously recorded from an epileptic hippocampus during SWS. Each neuron was recorded on a separate microwire from a bundle of microwires with contacts spaced at 500 µm increments from the proximal to distal tip of the bundle. Two long-dashed lines represent the upper and lower 99% confidence intervals. The short-dashed line represents the mean firing rate. The portion of the correlogram shaded black represents the area under the significant peak used to quantitatively assess the strength of interaction. Bin size = 10 msec. B, Percentage of cross-correlograms showing significant discharge interactions between pairs of neurons recorded within epileptic areas (n = 189) compared with pairs of neurons recorded within non-epileptic areas (n = 192). Values represent the mean percentage of cross-correlograms showing significant interactions with upper and lower confidence intervals of 95%. The solid horizontal line indicates no overlap between confidence intervals.

State: sleep versus waking

Figure 6, A and B, shows that the divergence in firing rate and burst rate between epileptic and non-epileptic neurons wasmore pronounced during episodes of SWS and REM sleep comparedwith Aw. Contrary to these noticeable trends, our analyses ofstate-related changes in neuronal firing rate and burst rate revealedthat there was no significant interaction between state and epilepsy(firing rate, F_(2,219) = 1.41, p = 0.2; burst rate, F_(2,219) =0.56, p = 0.6). Interestingly, Figure 6B shows that both epilepticand non-epileptic neurons had the highest rates of burst firingduring SWS compared with REM sleep and Aw. Ignoring the effectsof epileptogenicity on neuronal activity, Figure 6C reveals significantstate-related differences in neuronal burst firing (F_(2,219) =15.42; p < 0.0001). Mean burst rate during episodes of SWS wassignificantly higher compared with both Aw and REM sleep (11.17± 1.90 bursts per minute vs 7.50 ± 1.16 and 6.63 ± 1.35, respectively;both p = 0.05), and in addition, burst rate during Aw episodeswas greater than during REM sleep (p = 0.05). In contrast, nostate-related differences in firing rate were found (F_(2,219)= 2.90; p = 0.06) (Fig. 6C).

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Figure 6. Mean firing rate and burst rate during episodes of Aw, SWS, and REM sleep. A, Mean firing rate of epileptic and non-epileptic neurons during sleep-wake states. B, Comparison of burst firing between epileptic and non-epileptic neurons across states. C, Combination of epileptic and non-epileptic neurons, mean firing rate, and burst rates for each state. Burst rate was significantly higher during episodes of SWS compared with both Aw and REM sleep. Episodes of Aw were found to have higher burst rates compared with REM sleep. *p = 0.05.

Examination of the interaction between state and epileptogenicity on neuronal synchrony revealed significant differences duringepisodes of SWS and REM sleep. Figure 7A shows that during SWS,49% of the cross-correlograms between neurons recorded withinepileptic areas demonstrated significant firing interactions comparedwith 30% of cross-correlograms between pairs of neurons recordedwithin non-epileptic areas ( $chi$ ² = 4.28; df = 1; p = 0.04). During REM sleep the proportion ofcross-correlograms indicating significant synchronous dischargewithin epileptic and non-epileptic areas was 22 and 6%, respectively( $chi$ ² = 5.41; df = 1; p = 0.02). Episodes of Aw did not discriminatesynchronous firing between neurons recorded in epileptic comparedwith non-epileptic areas (p = 0.6).

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Figure 7. Comparison of neuronal synchrony and strength of interaction between epileptic and non-epileptic neurons during sleep-wake states. A, The proportion of cross-correlograms (epileptic, n = 63 per state; non-epileptic, n = 64 per state) showing significant discharge interactions was significantly greater between pairs of epileptic neurons compared with non-epileptic neurons during episodes of SWS (*p = 0.04) and REM sleep (⁺p = 0.02). The black triangle indicates that among epileptic neurons synchronous pairs of neurons were observed during SWS significantly more often than during Aw and REM sleep. The black circle indicates that among non-epileptic neurons significantly more pairs of neurons showed synchronous interactions during SWS compared with REM sleep. B, Strength of synchronous discharge interaction. Strength of interaction was measured as the area under the central peak of the cross-correlogram and expressed as the number of coincidences. No difference was observed in the strength of neuron firing interaction between neurons recorded within epileptic areas compared with non-epileptic areas. However, across all recorded neurons, episodes of SWS were associated with greater synchronous discharge compared with episodes of Aw. *p = 0.02.

Further examination of the effect of state on neuronal synchrony using $chi$ ² shows that both epileptic and non-epileptic neurons were similarlymodulated by behavioral state. In Figure 7A, the black triangledenotes that synchronous firing between neurons recorded withinepileptic areas was greater during SWS compared with Aw and REMsleep (p = 0.0008 and 0.0002). However, no difference in the proportionof neuronal discharge interactions was observed between episodesof Aw and REM sleep. Similarly, synchronous discharge betweenneurons recorded within non-epileptic areas was significantlygreater during SWS compared with REM sleep, represented in Figure7A by the black circle (p = 0.0007). Trends but no significantdifferences were observed between episodes of Aw compared withSWS (p = 0.06) or between Aw compared with episodes of REM sleep(p = 0.07). It is interesting to note that differences in neuronalsynchrony were found between the two desynchronized states ofAw and REM sleep. For neurons within non-epileptic areas, synchronousfiring was notably reduced during REM sleep compared with episodesof Aw, whereas synchronous firing between epileptic neurons duringREM sleep was comparable to levels found during episodes of Aw(Fig. 7A). Examination of the interaction between state and epileptogenicityon the strength of neuronal synchrony revealed a trend for greaterstrength of synchronous discharge between epileptic neurons comparedwith non-epileptic neurons during SWS and REM sleep (Fig. 7B).However, statistical analyses found no significant interactionbetween behavioral state and epileptogenicity (F_(2,90) = 0.49;p = 0.6). Analysis for the effects of state alone did reveal significantstate-related changes in the strength of synchronous discharge(F_(2,90) = 3.48; p = 0.04). Figure 7B shows that pairs of neuronsrecorded during episodes of SWS demonstrated greater strengthof synchronous firing compared with Aw (p = 0.02), whereas therewas no significant difference in strength of neuronal synchronybetween episodes of SWS and REM sleep (p = 0.4) or between episodesof Aw and REM sleep (p = 0.6).

Temporal lobe recording sites: hippocampus versus subiculum versus entorhinal cortex

Table 2 shows that significant differences were found in both firing rate (F_(2,219) = 2.86; p = 0.003) and burst rate (F_(2,219)= 3.11; p = 0.05) between specific MTL brain areas. The mean firingrate of Sub neurons was greater than Hip neurons (5.06 ± 0.59vs 2.91 ± 0.28 spikes per second; p = 0.01). Similarly, mean burstrate of Sub neurons was greater than Hip neurons (14.12 ± 2.69vs 7.47 ± 1.17 bursts per minute; p = 0.05). Comparisons of meanfiring rate and burst rate between EC and Sub neurons failed toreach statistical significance, as did the comparison betweenEC and Hip neurons. Examination of the MTL recording site in relationto epileptogenicity did not reveal significant differences inneuronal firing rates (F_(2,219) = 0.37; p = 0.7) or burst rates(F_(2,219) = 0.59; p = 0.6; data not shown). Because of the lownumber of simultaneously recorded neurons within each epilepticand non-epileptic MTL area, we were unable to evaluate each MTLrecording site in relation to epileptogenicity on the basis ofneuronal synchrony.


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Table 2. Mean firing and burst rates (±SE) for single neurons recorded within EC (n = 19), Hip (n = 42), and Sub (n = 13) during episodes of Aw, SWS, REM sleep, and mean of all states combined

Despite the significant differences in firing rate shown in Figure 8A between epileptic Hip and Sub neurons compared withnon-epileptic Hip and Sub neurons, the combined effects of stateand recording site did not discriminate discharge frequenciesbetween epileptic and non-epileptic neurons (F_(4,218) = 1.03;p = 0.4). However, in contrast to mean firing rate, further analysisshowed that the combination of state and recording site differentiatedepileptic and non-epileptic neurons on the basis of burst rate(F_(4,218) = 2.81; p = 0.03). Figure 8B shows prominent differencesin burst firing between neurons recorded within epileptic Hipareas compared with non-epileptic Hip areas. Epileptic Hip neuronshad significantly higher burst rates compared with non-epilepticHip neurons during episodes of both SWS (p = 0.01) and REM sleep(p = 0.01). No difference was observed between epileptic and non-epilepticHip neurons during episodes of Aw, nor did we observe significantdifferences in burst rate between epileptic and non-epilepticEC or Sub neurons during any of the sleep-wake states.

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Figure 8. Mean firing rate and burst rate of single neurons recorded in EC, Hip, and Sub during Aw, SWS, and REM sleep. A, Comparison of mean firing rate. B, Mean burst rate was higher among neurons recorded from epileptic Hip compared with non-epileptic Hip across episodes of SWS and REM sleep. No differences were observed between neurons recorded from epileptic EC compared with non-epileptic EC or between epileptic Sub and non-epileptic Sub. **p = 0.01.

Inspection of Figure 8 also revealed that there were similar state-related changes in firing rate and burst rate between epilepticand non-epileptic neurons within each MTL area. Table 2 summarizesmean firing rate and burst rate of neurons within each structureduring Aw, SWS, and REM sleep. In regard to firing rate, a significantinteraction was found between state and MTL recording site (F_(4,218)= 3.35; p = 0.01). Neurons recorded within EC had higher firingrates during episodes of Aw compared with both SWS (p = 0.01)and REM sleep (p = 0.05), whereas there was no difference in firingrate between SWS and REM sleep. Significant interactions werealso found between state and recording site on the basis of burstrate (F_(4,218) = 6.05; p = 0.0002). Both Hip and Sub neurons hadhigher burst rates during episodes of SWS compared with both Aw(p = 0.01) and REM sleep (p = 0.01), whereas no difference inburst rate was observed between Aw and REM sleep. Unlike bothHip and Sub, EC neurons had higher burst rates during episodesof Aw compared with both SWS (p = 0.05) and REM sleep (p = 0.05).Within EC, there was no significant difference in burst rate betweenSWS and REMsleep.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

This study addressed, for the first time, the question of how sleep-waking states influence epileptogenic neuronal dischargefrequency, pattern, and synchrony in the human mesial temporallobe. The main findings from this study can be summarized as follows.(1) When recordings from both waking and sleeping periods arecombined, neurons recorded within epileptic MTL areas demonstratedhigher firing rates, increased frequency of burst discharge, andgreater synchrony of discharges compared with neurons recordedwithin non-epileptic MTL areas; (2) episodes of SWS and REM sleepwere associated with significantly greater synchronous firingbetween pairs of neurons recorded within epileptic MTL areas comparedwith non-epileptic MTL areas, whereas there was no differencein synchronous firing of neurons recorded in epileptic versusnon-epileptic areas during waking; and (3) during sleep states,epileptic hippocampal neurons demonstrated higher burst ratescompared with non-epileptic hippocampal neurons, whereas therewas no difference in burst firing rate duringwaking.

Although the term non-epileptic was used to categorize those neurons recorded within an MTL area where clinical depth electrodesnever recorded the onset of a seizure and MRI-identified atrophywas absent, we cannot absolutely exclude the possibility thata non-epileptic limbic area has never been involved in seizuregenesis. This is because our recordings spanned only a few weeks,and all of the patients studied had seizure histories spanningyears. Therefore, the terms epileptic and non-epileptic must beinterpreted to represent areas of greater and lesser epileptogenicpotential, respectively (Engel, 1993).

Neuronal correlates of epileptogenicity

Studies from experimental models of epilepsy have found that prolonged membrane depolarizations giving rise to multiple actionpotentials are characteristic of neurons within epileptogenicareas (Matsumoto and Ajmone-Marsan, 1964; Jensen and Yaari, 1997;Bertram et al., 1998; Smith and Dudek, 2001). Despite the evidenceof enhanced synaptic excitability in animal models of epilepsy,many intracellular studies of neurons within resected human epileptogenictissue (Schwartzkroin et al., 1983; Telfeian et al., 1999) andin vivo interictal studies of human epileptogenic regions (Isokawa-Akessonet al., 1989; Colder et al., 1996a,b) found no evidence of abnormalor excessive neuronal burst firing. However, a few studies havereported neuronal responses resembling paroxysmal depolarizationshifts (Prince and Wong, 1981; Isokawa and Levesque, 1991; Strowbridgeet al., 1992). The inconsistent findings among human studies ofepilepsy (Isokawa-Akesson et al., 1989; Colder et al., 1996a,b)may be attributable to the fact that recordings were performedprimarily while the patients were awake or in states of drowsiness,potentially masking the abnormal neuronal activity associatedwith the more epileptogenic brain region. Analyses of dischargeproperties during polysomnographically defined episodes of wakingand sleep contributed to the overall finding in this study thathigher firing rates and increased propensity for burst firingare characteristic of human seizure-generating regions. This isparticularly important during SWS when epileptiform dischargesare activated, and in contrast, during REM sleep when epileptiformactivity is restricted to the more epileptogenic region (Montplaisiret al., 1987; Sammaritano et al., 1991).

Neurons within human MTL areas ipsilateral to the site of seizure genesis have been observed to discharge with greater synchronythan neurons contralateral to the site of seizure onset by some(Isokawa-Akesson et al., 1987, 1989) but not by others (Wyleret al., 1982; Colder et al., 1996c). By combining recordings duringepisodes of Aw and sleep, the present study found significantlygreater synchrony of discharges between epileptic MTL neuronscompared with non-epileptic MTL neurons. Dissimilarity among theprevious studies may be attributable in part to differences inquantification of neuronal synchrony and the time lags withinwhich coincident discharge was considered significant. The increasedpropensity for burst firing that we observed among epileptic neuronsmay have contributed to the higher incidence of synchronous discharge.However, Colder and colleagues (1996c) from the same studies citedabove found no correlation between neuronal burst propensity andsynchrony. On the other hand, evidence using whole-cell recordingsfrom CA1 pyramidal cells suggests that bursts of action potentialsmay facilitate presynaptic neurotransmitter release and increasethe probability of signal transmission between neurons (Stevensand Wang, 1995; Lisman, 1997).

Sleep-waking states and epileptogenicity

Transitions from periods of wakefulness to states of sleep, regulated by cholinergic and aminergic brainstem and basal forebrainsystems (Steriade and McCarley, 1990; Szymusiak, 1995), are accompaniedby changes in the patterns and synchrony of firing between neuronsof the corticothalamic system (Steriade et al., 1993). Duringepisodes of SWS, thalamocortical neurons discharge in a slow,rhythmic burst-firing mode that is transmitted to other thalamicnuclei and modulated by corticothalamic input resulting in widespreadsynchronization across neuronal assemblies (Steriade et al., 1991;Nunez et al., 1992). This global level of synchronization is characteristicallyobserved in cortical EEG as $delta$ oscillations. In contrast, episodesof REM sleep are accompanied by more tonic modes of neuronal discharge,synchrony becomes more localized within neuronal networks, andcortical EEG appears as low-amplitude fast activity (Destexheet al., 1999). Consistent with sleep-related changes observedin EEG at the cortical level, in a previous study (Staba et al.,2002) and in the present study, we found that single neurons withinthe human MTL demonstrated the greatest probability for burstfiring during SWS and the lowest probability during REM sleep.In addition, the present study found that synchronous firing betweenMTL neurons reaches its highest levels during SWS compared withREM sleep and that the strength of synchronous discharge was significantlygreater during SWS compared with Aw, whereas REM sleep was intermediate.The SWS-related increase in human MTL burst firing and synchronyof discharges coincides with sleep episodes when the probabilityfor hippocampal sharp waves is the greatest (Buzsaki, 1986; Suzukiand Smith, 1987). The overall increase in neuronal activity thatoccurs throughout the hippocampal-EC during sharp wave periodshas also been implicated in hippocampal-neocortical communicationduring memory consolidation (Buzsaki, 1998).

Researchers studying the relation of behavioral state to the occurrence of epileptiform activity have generally found thatepisodes of NREM sleep activate epileptiform discharges, whereasepisodes of REM sleep are associated with a suppression of epileptiformactivity (Sammaritano et al., 1991; Shouse et al., 1997; Malowet al., 1998; Herman et al., 2001). In agreement with these humanEEG studies, during SWS, we found significantly greater synchronybetween neurons recorded within epileptic areas compared withneurons within non-epileptic areas, whereas episodes of Aw didnot differentiate neuronal synchrony between epileptic neuronsand non-epileptic neurons. Although synchrony between non-epilepticneurons declined to its lowest levels during REM sleep comparedwith both SWS and Aw, synchronous firing between epileptic neuronsduring REM sleep did not decline relative to Aw and was equivalentto that found during Aw (Fig. 7A). In addition, non-epilepticneuronal firing rate and burst firing showed a precipitous declineduring episodes of REM sleep, whereas epileptic neuronal firingrate and burst rates were consistently maintained across all states(Fig. 6A,B). These data provide neuronal evidence supporting the"autonomy" hypothesis that the primary epileptogenic region demonstratesstability of epileptiform activity rates across sleep-wake states,especially during the epileptiform-suppressing state of REM sleep(Rossi et al., 1974; Gentilomo et al., 1975; Lieb et al., 1980).

Because all subjects in the present study were taking anti-epileptic drugs, evaluation of these data must take into considerationthe possible influences of anticonvulsant medications on sleeppatterns. Although there is evidence that epilepsy and anticonvulsantmedication can influence sleep architecture (Gigli and Gotman,1992; Bazil et al., 2000; Sammaritano and Sherwin, 2000), characterizationof neuronal activity was based on stable, 10 min episodes of wakefulness,SWS, and REM sleep that were clearly defined by standard polysomnographiccriteria.

Mesial temporal lobe structures and epileptogenicity

Studies investigating the involvement of the entorhinal-hippocampal loop in seizure genesis have found each of these MTL areascapable of initiating and propagating epileptiform activity (Waltheret al., 1986; Spencer and Spencer, 1994; Nagao et al., 1996).We found higher firing rates among epileptic Hip and Sub neuronsacross all states compared with non-epileptic homotopic sites,and higher burst rates among epileptic EC and Hip neuron acrossall states compared with non-epileptic EC and Hip sites, respectively(Fig. 8). However, significant differences in burst firing werefound only between epileptic and non-epileptic Hip when we examinedthe combined effects of recording site and state on epileptogenicity;sleep states differentiated epileptogenic Hip burst firing, whereasepisodes of Aw did not. Differences in local circuit interactionswithin each MTL structure (Traub et al., 1985; Dhillon and Jones,2000; Harris and Stewart, 2001) and differences in the severityof damage across MTL areas that are associated with chronic epilepticseizures (Mathern et al., 1996) may explain our finding of differencesin epileptogenicity between Hip and other MTLareas.

Comparison of discharge properties of neurons in Hip, Sub, and EC revealed several interesting differences. Several authorshave reported that neurons within the non-primate subiculum showa propensity for burst firing (Mason, 1993; Behr et al., 1996).Consistent with these non-primate findings, in the present studyhuman Sub neurons had significantly higher firing rates and burstrates compared with Hip neurons, whereas EC was intermediate.In addition, we observed that both Sub and Hip neurons had thegreatest propensity for burst firing during SWS compared withAw and REM sleep, similar to the SWS-related bursts found in neuronsof the corticothalamic system (Steriade et al., 1993; Weyand etal., 2001). Conversely, EC neurons demonstrated higher firingrates and burst firing during Aw compared with both sleep states,counter to the observations of Ravagnati et al. (1979) who reportedthat human EC neurons had the highest firing rates during episodesof REM sleep. The diversity of cell types with different dischargeproperties that have been described within the EC may accountfor these discrepancies (Gloveli et al., 1997; Frank et al., 2001).

Conclusion

As observed previously from human EEG studies, the present study shows that MTL single-neuron burst firing and synchrony ofdischarges remain elevated even during epileptiform-suppressingepisodes of REM sleep and provides neuronal evidence that theprimary epileptogenic region is relatively more autonomous thannon-primary regions. Investigations are needed to determine howwell the single-neuron discharge properties that we reported reflectthe network activity of the neuronal populations that make upthe epileptogenic region, and how the modulating effect of thesleep-wake cycle may enhance epileptogenicity to precipitate ictalevents. Animal experiments have shown that single neurons arecapable of initiating and synchronizing the activity of the localneuronal population (Miles and Wong, 1983; Cobb et al., 1995).The increased propensity for single-neuron burst firing combinedwith greater synchronous firing between MTL neurons during SWSand REM sleep may augment signal transmission across neuronalnetworks in areas of seizure onset and create a lower thresholdfor initiation and spread of ictaldischarges.

  FOOTNOTES

Received Feb. 5, 2002; revised April 4, 2002; accepted April 10, 2002.

This work was supported by National Institutes of Health Grants NS-02808 and NS-33310. We thank Dr. G. Kreiman for assistancewith data analysis, Dr. J. Segundo for helpful comments, and T.Fields and E. Behnke for their excellent technicalassistance.

Correspondence should be addressed to Dr. Charles L. Wilson, 2155 Reed Neurological Research Center, 710 Westwood Plaza, DavidGreffen School of Medicine at University of California Los Angeles,Los Angeles, CA 90095. E-mail: clwilson{at}ucla.edu.

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MATERIALS AND METHODS
RESULTS
DISCUSSION
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