Abstract
Variable-duration oscillations and repetitive, high-voltage spikes have been recorded in the electrocorticogram (ECoG) of rats weeks and months after fluid percussion injury (FPI), a model of traumatic brain injury. These ECoG events, which have many similarities to spike-wave-discharges (SWDs) and absence seizures, have been proposed to represent nonconvulsive seizures characteristic of post-traumatic epilepsy (PTE). The present study quantified features of SWD episodes in rats at different time points after moderate to severe FPI, and compared them with age-matched control rats. Control and FPI-injured rats at 1 year of age displayed large-amplitude and frequent SWD events at frontal and parietal recording sites. At 3–6 months, SWDs were shorter in duration and less frequent; extremely brief SWDs (i.e., “larval”) were detected as early as 1 month. The onset of the SWDs was nearly always synchronous across electrodes and of larger amplitude in frontal regions. A sensory stimulus, such as a click, immediately and consistently stopped the occurrence of the SWDs. SWDs were consistently accompanied by behavioral arrest. All features of SWDs in control and experimental (FPI) rats were indistinguishable. None of the FPI-treated rats developed nonconvulsive or convulsive seizures that could be distinguished electrographically or behaviorally from SWDs. Because SWDs have features similar to genetic absence seizures, these results challenge the hypothesis that SWDs after FPI reflect PTE.
Introduction
Traumatic brain injury (TBI) is a common cause of acquired epilepsy (vs genetic epilepsy), characterized by spontaneous, recurrent seizures that are often focal and nonconvulsive, but can spread and undergo secondary generalization to become convulsive (Agrawal et al., 2006; Engel, 2013). Post-traumatic epilepsy (PTE) is often intractable, so developing strategies to prevent or treat PTE would benefit from appropriate animal models. One of the most common animal models of TBI is fluid percussion injury (FPI) in Sprague-Dawley rats (D'Ambrosio et al., 2004; Kharatishvili et al., 2006), mimicking closed head injury in humans (Thompson et al., 2005). However, well documented evidence of spontaneous recurrent seizures resulting from TBI that are distinctly different from normal rhythmic or oscillatory events in control animals is limited (Kharatishvili et al., 2006; Statler et al., 2009; Shultz et al., 2013; Campbell et al., 2014). Considerable debate has occurred on what constitutes an epileptic seizure that could form the basis for a model of PTE (D'Ambrosio and Miller, 2010; Dudek and Bertram, 2010), and investigations of mechanisms and intervention strategies for PTE, with unequivocal epileptic seizures, are lacking.
Previous studies using rostral parasagittal FPI report that injury-induced, electrocortically and behaviorally distinct, seizure-like events are never observed in sham-operated controls (D'Ambrosio et al., 2004, 2009), suggesting that they are specific to FPI-treated rats and thus represent PTE. The interpretation that these postinjury events are epileptic seizures is surprising given that their electrographic and behavioral characteristics appear identical to those described for high-voltage rhythmic spiking, which are labeled spike-wave-discharge (SWD) in uninjured rats, including the Sprague-Dawley breed (Aldinio et al., 1985; Kleinlogel, 1985; Buzsáki et al., 1990b; Kelly et al., 2001; Kharlamov et al., 2003; Pearce et al., 2014) used in previous FPI experiments. SWD are quasiperiodic signals having unique spectra with high values at a fixed fundamental frequency (7–9 Hz for SWD) and at whole multiples (harmonics) of this fundamental frequency. These spectral characteristics so distinctly identify SWD (Shaw, 2004) that they have been used for automated SWD detection (Van Hese et al., 2003, 2009). They are also exactly the same as those described for cortical discharge produced by rostral parasagittal FPI (D'Ambrosio et al., 2004). Additionally, normal SWDs are invariably associated with behavioral arrest and facial automatisms (Vanderwolf, 1975; Hammond et al., 1979; Robinson and Gilmore, 1980; Semba et al., 1980; Vergnes et al., 1982; Kaplan, 1985; Shaw, 2004), also noted as a unique characteristic of seizures in FPI rats. The common presence of SWD and associated behavioral arrest in uninjured Sprague Dawley rats raises the possibility of confounds in the interpretation of results from PTE models if they are thought to also reflect seizures. The present study visually examined continuous video/electrocorticogram (ECoG) recordings for possible seizures and also quantified features of SWD episodes in control rats between 1 and 12 months of age using automated procedures, with the objective of distinguishing normal brain activity from that associated with PTE. These results were compared with the same timeline in brain-injured rats receiving moderate and severe rostral parasagittal FPI.
Materials and Methods
Ninety adult viral-free male Sprague-Dawley rats (Harlan Laboratories) were housed in pairs in temperature (23 ± 3°C) and light (12 h light/dark) controlled rooms with ad libitum access to food and water. All procedures were performed in accordance with University of Colorado Institutional Animal Care and Use Committee guidelines for the humane use of laboratory rats in biological research. Rats were randomly assigned to the following groups: sham operated (n = 20), naive (n = 20), FPI-moderate (n = 15), and FPI-severe (n = 35).
Fluid percussion injury and experimental groups.
The rostral parasagittal FPI used in this study were described previously (D'Ambrosio et al., 2004; Frey et al., 2009; Rodgers et al., 2012). Briefly, FPI rats were anesthetized with halothane (Abbott Laboratories; 3.5% induction, 1.5–2.0% maintenance) and mounted in a stereotaxic frame. A 3.0-mm-diameter craniotomy was centered at AP −2.0 mm and ML 3.0 mm from the midsagittal suture (Fig. 1A), with the exposed dura remaining intact. A female Luer-Loc hub (inside diameter of 3.5 mm) was secured over the craniotomy with cyanoacrylate adhesive. Following hub implantation, rats were removed from the stereotaxic frame and connected to the FPI apparatus, and after recovering from anesthesia sufficiently that the forepaw withdrawal reflex could be elicited, the impact was delivered. The FPI apparatus delivered one of two impact pressures (10 ms pulse), either an impact force of 2.0 or 3.4 atm (moderate or severe injury, respectively). All rats experienced apnea following injury and were revived after 15 s. The injury cap was then removed, scalp sutured, and the rats returned to their home cages for recovery. The righting time was ∼10 min following injury. There was a ∼10% mortality rate for severe impact pressures. Sham-operated rats underwent identical surgical preparation, but did not receive the brain injury. Naive rats only received electrode implantation surgery described below.
Chronic video/ECoG recording.
One week following FPI or sham surgery, epidural bilateral stainless steel screw electrodes were implanted for ECoG recording, using septic surgical procedures for all chronic preparations. Under halothane anesthesia (3.5%), rats were implanted with bilateral screw electrodes ipsilateral and contralateral to injury (Fig. 1A) over parietal (AP −6.0 mm, ML 4.5 mm) and frontal (AP 0 mm, ML 4.5 mm) cortex, a reference screw (AP 3.0 mm, ML 1.0 mm), and a ground screw (AP −7.5 mm, ML 1.0 mm). Following a 1 week recovery period, animals were tethered to an electrode harness (Plastics One, 363) and slip-ring commutator (Plastics One, SL6C) permitting free movement for 24/7 video/ECoG monitoring throughout the duration of the experiment. Spontaneous ECoG signals were amplified (×10000) and digitized at 500 Hz. Spontaneous ECoG and video were stored for subsequent SWD event detection and related behavioral analysis. After mortality/attrition, a total of 37 FPI rats underwent subsequent (beginning 2 weeks postinjury) continuous video/ECoG (Fig. 1E) to establish a temporal profile of SWD events over time.
Semiautomated SWD detection and quantification.
Automated detection was only used to quantify SWD events, and did not replace visual examination of all video/ECoG for seizure and epileptiform discharge detection. ECoG data were analyzed in 1 s segments, across 48 h time epochs per rat at 1, 3, 6, 9, and 12 months of age (Fig. 1F). Recording was biased toward rats ≥6 months of age according to previous reports of greater incidence of SWD in this age group (Aldinio et al., 1985; Kaplan, 1985; Kleinlogel, 1985; Buzsáki et al., 1990a,b; Kelly et al., 2001; Kharlamov et al., 2003; Pearce et al., 2014). Approximately 20 segments containing SWD were visually selected to establish a template for each rat. Auto-covariance functions were computed for identified segments to capture the amplitude, frequency, and waveform morphology of the SWD. Covariance functions for SWD trials and similar functions for segments containing representative noise were used to train a support vector machine (Orrù et al., 2012) to automatically discriminate between SWD and noise throughout 48 h of data for each rat at each age recorded for that rat. All detected SWD events for a given 48 h period were visually examined and artifacts deleted before the number and durations of SWD events were extracted for statistical analysis. In rats where all four electrodes were viable for comparison, recordings of 10 SWD epochs per rat were also examined to assess asynchronous versus synchronous onset. If SWD began in one electrode channel at least 100 ms before activity could be detected in other channels, it was considered an asynchronous onset. Synchronous onsets were characterized by no detectable delay of SWD between the four recording electrodes. Isolated onsets were defined as SWD bursts that never spread beyond a single electrode. Behavior during automatically detected SWD was assessed for representative 48 h periods with time-locked video. Rats were also visually observed during SWD to detect subtle behaviors (i.e., vibrissa and jaw movements).
Convulsive seizure detection and quantification.
Visual detection of potential convulsive seizures was performed using custom software. All video/ECoG recorded 24/7 for a given rat was displayed in 30 min blocks on high-resolution monitors. For an event to qualify as a convulsive seizure, ECoG activity had to be differentiated from background noise by the appearance of large-amplitude (at least three times baseline), high-frequency (minimum of 5 Hz) activity, with progression of the spike frequency that lasted for a minimum of 20 s. With this electrographic identification, video data would then determine seizure intensity and to confirm ECoG seizure activity versus potential animal-generated noise, such as eating and grooming, and be rated according to Racine's behavioral scale (Racine, 1972), recently modified to rate the intensity of post-traumatic seizures (D'Ambrosio et al., 2004). ECoG was simultaneously examined for putative epileptiform spikes distinct from either convulsive seizures or SWD.
Results
FPI injury
By 5 months postinjury, FPI typically induced damage at the locus of the craniotomy beginning at the level of the dorsal hippocampus. Contralateral brain structures appeared to be morphologically preserved, although some ventricular enlargement could be seen in FPI-treated rats contralateral to injury. Just caudal to the craniotomy (Fig. 1D; “ipsi”), FPI induced marked structural damage, cortical atrophy, deformation and atrophy of the hippocampus, and ventricular enlargement.
Appearance and incidence of SWD events
Figure 2 shows a 20 min epoch of ECoG recorded from a control rat (9 months). During this time period, the animal displayed a characteristic range of SWD durations, from long (several minutes; Fig. 2A, red traces) to short (several seconds; Fig. 2B, blue traces). Frequent and very brief SWD bursts (i.e., “larval,” <1 s; Fig. 2C, blue traces at bottom), comprised of only a few spikes, also typified SWD recordings. In Figure 3, exemplary traces from Figure 2 (A–C) are replotted at different timescales. SWD events, such as those depicted here, were typically characterized by an abrupt (<1 s) onset and termination (Fig. 3A,B, arrows), lack of postevent amplitude suppression, and spindle-like variations in amplitude throughout the event. SWD frequency (∼8 Hz in this example) and morphology appeared stable through the entire event duration (Fig. 3A). There were also no clear differences in SWD characteristics between long and short events (Fig. 3A and B, respectively). Larval SWDs (Fig. 3C) were typically reduced in amplitude but displayed a similar waveform morphology to longer epochs.
SWD incidence rate was indistinguishable between FPI and control animals F(1,9) = 0.321, p = 0.587, across all recording time-points. The incidence rate ranged from 66.7–100% at the 1 and 3 month time points, and from 90–100% at the 6 month, 9 month, and 1 year time points. As noted below, although the incidence of SWD was high even at 1–3 months, the number and duration of events was far lower than at later time points.
Pattern recognition of SWD events
Figure 4 shows a 6 s SWD event (Fig. 4A, red) detected in an uninjured 12-month-old rat. For automated event detection, data were analyzed in successive 1 s blocks. The auto-covariance function for each block (Fig. 4B,C, dark trace) captured both the amplitude and morphology of SWD (Fig. 4C, light trace) with clear spike and wave components (Fig. 4C; “S” and “W,” respectively). A quadratic kernel was trained on the auto-covariance functions of 20–30 visually identified 1 s blocks of SWD for each rat at each age, and then used to detect subsequent SWD for that animal.
Spatiotemporal features of SWD events
A total of 470 and 510 SWD events in the FPI and control rats, respectively, were examined for isolated, asynchronous, or synchronous onset. In no animals did SWD in the two parietal leads precede the frontal electrodes. While right versus left asynchronous onsets in the frontal leads were observed, a majority of SWD events in FPI and control animals began synchronously (79% and 90%, respectively). In FPI rats, 13% of SWD showed asynchronous onset starting in the right frontal electrode at the site of injury, compared with 6% starting in the left hemisphere. However, there was also a right hemisphere preference (7%) compared with the left hemisphere (2%) for SWD onset in the control animals. We recorded isolated (1 electrode only) SWD in only a very small number of events for either FPI or control rats (2% and 1%, respectively). A one-way ANOVA conducted to compare the effect of injury group (FPI-injured or uninjured controls) showed no significant group effects on synchronous (F(1,96) = 1.39, p = 0.241), left hemisphere asynchronous (F(1,96) = 1.46, p = 0.229), right hemisphere asynchronous (F(1,96) = 0.00, p = 0.997), or isolated SWD onsets (F(1,96) = 1.88, p = 0.174).
Behavioral features of SWD events
When time-locked video was examined, SWD events detected in both uninjured and injured rats were associated with inactivity or interruption of ongoing movement. Real-time visual examination of a subset of control and FPI rats revealed that SWD were often accompanied by vibrissa extension and slight vibrational tremor, similar to previously described “α-tremor” in normal Long–Evans rats (Semba and Komisaruk, 1984), and frequently terminated by bruxing movements of the incisors that were sometimes sufficiently intense to produce eye “boggling” (rapid movement of the eye in and out of the socket due to flexing of the masseter muscle). No events exceeding a seizure intensity score of 2 were observed in either FPI or control rats.
SWD counts and lengths as a function of age and injury
Figure 5 exemplifies SWD in an uninjured rat recorded across 1–12 months of age. One second samples shown here typify SWD in the majority of normal control rats across the recording period (Fig. 5A). SWD were fully developed at 12 months with a clear spike and wave morphology. The number and duration of SWD events increased with age, but short bursts of larval SWD could be detected at all ages. Despite age-related increases in the number and duration of events, the morphology and frequency, best visualized in the averaged SWD (Fig. 5B) and auto-covariance function (Fig. 5C), appeared similar even when comparisons were made between 1 and 12 month records (Fig. 5; 12 month, light and dark traces, respectively).
The number (p = 0.099) and duration (p = 0.132) of SWDs did not differ between surgically naive and sham controls, so these groups were combined for the overall analyses. Age-related increases in the number and duration of SWD events are summarized in the grouped control and FPI rats (Fig. 6A,B). A two-way ANOVA was conducted to examine the effect of age (1–12 months) and injury group on the number of SWD events. There was no significant interaction between the effects of age and injury on the number of SWD events (Fig. 6A) for any time point postinjury (F(11,356) = 0.600, p = 0.700). There was a main effect found for age, with the total number of SWD events significantly increasing with age (F(4,356) = 2.951, p = 0.020). Post hoc comparisons showed that the older (9–12 month) FPI and control rats displayed more SWD events than the younger rats, which was statistically higher at both the 9 month (p < 0.01) and 1 year (p < 0.01) time points. However, there was not a significant main effect for injury group (F(2,356) = 0.338, p = 0.713), indicating no difference in the number of SWD events between FPI-injured and uninjured control rats.
A two-way ANOVA examining the effect of age and injury on the duration of SWD events also revealed no significant interaction (Fig. 6B; F(11,356) = 1.259, p = 0.281). A significant main effect was found for age (F(4,356) = 7.189, p = 0.000), reflecting significantly longer SWD duration as a function of age, across both groups. In both FPI and control groups, SWD duration was significantly longer at the 6 month (p < 0.05), 9-month (p < 0.05) and 1 year (p < 0.05) time points. As with the number of SWD events, there was no main effect for injury group and SWD duration across any time point postinjury (F(2,356) = 2.041, p = 0.131).
Characterization of the SWD events by burst length in uninjured controls (Fig. 6C) showed that the number of SWD bursts declined with increasing length. SWD burst length parameters for FPI-injured rats (Fig. 6D) followed very similar age-related patterns and were not significantly different from the uninjured controls (F(39,2379) = 1.491, p = 0.078). There was not a significant main effect found for injury group (F(39,2379) = 2.563, p = 0.110). There was a significant main effect found for burst length (F(39,2379) = 123.881, p = 0.000), revealing that there were significantly more 1–3 s SWD events than 4–20 s events (p < 0.010).
SWD frequency, morphology, and sensory interruption as a function of injury
SWD frequency (referring to spike repetition rate, not frequency of bursts) was consistently in the range of 7–9 Hz and did not differ between uninjured (7.7 Hz ± 0.4) and injured (7.9 Hz ± 0.3) animals (Fig. 7A). SWD morphology was also qualitatively similar between groups (Fig. 7B). In a final comparison, we used automated SWD detection to trigger an auditory stimulus (∼65 dB SPL; 20 cm distance) during ongoing SWD events in a subset of 9 control and 12 FPI rats (Fig. 8). It has been noted in other studies that, unlike seizures, normal SWD may be interrupted by sensory stimulation and arousal (Robinson and Gilmore, 1980; Semba et al., 1980; Vergnes et al., 1982; Kaplan, 1985; Buzsáki et al., 1990b; Wiest and Nicolelis, 2003; Shaw, 2004; Pearce et al., 2014). Similar to these previous reports, a click had the effect of rapidly aborting ongoing SWD in our control rats (single trial example shown in Fig. 8A). Figures 8B,C, shows averaged spectrograms (n = 10 trials each) of click-evoked SWD suppression for two control and two FPI rats, respectively. Note also in these spectrograms, the stereotyped harmonic spectral bands for SWD marked with white lines at the fundamental frequency (7–9 Hz) and the first higher harmonic (14–18 Hz). The percentage of click-evoked SWD suppression was calculated for all rats by comparing the ratio of total root mean squared (RMS) power for 2 s before and after the click. The average suppression was 89.3 ± 0.48% and 90.5 ± 0.55% for the control and FPI, respectively (Fig. 8D), and did not significantly differ between the groups (p = 0.16).
Convulsive seizures
None of our injured or uninjured rats developed convulsive seizures based on criteria used to identify these events in poststatus epilepticus models of epilepsy, even when recorded to 12 months of age. We also failed to observe epileptiform discharges (spikes) in our injured or control rats.
Summary of results
The key results from these experiments are as follows: (1) The SWD episodes from FPI rats had waveforms, durations, and frequencies that were virtually identical to previous reports on a highly similar FPI model of PTE (D'Ambrosio et al., 2004, 2005; Curia et al., 2011). (2) Unlike previous reports, however, the SWDs were equally prominent in sham-surgery and uninjured control rats, with close similarities in both electrographic and behavioral features. (3) In both FPI and control rats, the SWDs were generally only a few seconds in duration, but could persist for tens of seconds, although these longer duration events were comparatively rare and only seen in older animals (including controls). (4) The onset of SWDs was usually synchronous across the cortical recording electrodes; however, SWD onset could occur earlier on one particular electrode, but the difference in apparent onset was brief (hundreds of milliseconds) and not consistently related to the site of injury. (5) A variety of sensory stimuli, such as a “click,” consistently blocked the SWDs in both groups. (6) The SWDs appeared remarkably similar to events previously reported by others in several strains of uninjured inbred and outbred rats. (7) Convulsive seizures, characteristic of other animal models of acquired epilepsy arising from induced status epilepticus or perinatal hypoxia-ischemia, were never observed.
Discussion
In human epilepsy, nonconvulsive seizures have classically been divided into two general types: complex partial (i.e., focal dyscognitive; Berg et al., 2010) and absence seizures. These seizure types have distinctly different etiologies and electrographic/behavioral properties, but each can be misinterpreted for the other.
SWD after FPI do not reflect complex partial seizures
PTE and other forms of acquired epilepsy are characterized by simple (i.e., motor or sensory) and complex (loss of consciousness) partial (focal) seizures that: (1) initially have a seizure onset zone near the site of the injury, and (2) have prolonged durations (minutes), particularly when they spread to other areas. Although formal plots of the distribution of seizure durations are lacking, abundant clinical data (Theodore et al., 1983, 1994; Williamson et al., 1985; Devinsky et al., 1988; Jenssen et al., 2006; Afra et al., 2008; Kim et al., 2011) have characterized simple and complex partial seizures (CPSs) in humans with PTE and other forms of acquired epilepsy as having minimum durations of 10–20 s, but often lasting minutes. Thus, the seizure durations of CPSs are markedly different from the distribution of durations observed here (Fig. 6) and are nearly an order of magnitude longer than those most of the events described for the FPI model (Eastman et al., 2015).
Other characteristics of SWDs recorded here are also at odds with those of CPSs in humans and with the nonconvulsive seizures that can occur in kainate and pilocarpine models of acquired epilepsy in rats. The seizures in acquired human epilepsy and in these other models typically: (1) increase intensity over many seconds at onset, (2) undergo an evolution in activity over time during the seizure, and (3) show a postictal suppression of ECoG activity—unlike the: (1) sudden onset, (2) relatively homogeneous pattern, and (3) abrupt termination typical of SWDs. Finally, SWDs can be easily terminated with mild sensory stimulation, a phenomenon not observed with CPSs.
SWD after FPI may reflect absence seizures
Absence epilepsy, a form of childhood genetic epilepsy, involves absence seizures that are shorter than CPSs (5–15 s, but can range from 1 to tens of seconds). Absence seizures are more frequent than CPSs; a frequency of many seizures per day is common, and occasionally dozens per hour occur. CPSs, however, are rarely more frequent than a few per day, and these would generally be considered “clusters.” SWDs recorded here from FPI and control animals occurred many times per hour and were commonly only a few seconds in duration, which are properties virtually identical to those classically described for absence seizures (Sato, 1983; Pearl and Holmes, 2008), also interpreted as “nonconvulsive” seizures in a recent FPI study but observed regularly in control, sham, and injured rats (Campbell et al., 2014). Other features of SWDs recorded in our FPI and control rats had much closer similarity to absence seizures than CPSs. For example, the rhythmic nature of SWD events in the range of 5–10 Hz, slightly faster but similar to absence seizures in humans, has been amply described in several models of absence epilepsy in inbred (Danober et al., 1998) and as normal events in outbred rats, such as the Long–Evans (Shaw, 2004; Huang et al., 2012) and Sprague-Dawley strains (Wiest and Nicolelis, 2003). The distinct waveform of SWDs, their rapid onset and termination, and their lack of postictal suppression are defining characteristics of absence seizures in these animals but not of CPSs. Finally, it has been shown that SWDs in uninjured outbred Sprague-Dawley rats can be abolished by ethosuximide (a human anti-absence drug; Pearce et al., 2014), strengthening the connection with absence seizures.
As a form of primary generalized epilepsy, absence seizures can have synchronous onsets at all electrode sites, similar to the SWDs observed here. Occasionally, SWD activity appeared to begin at one electrode, but this was rare and was independent of injury location. Although previous studies of the FPI model have suggested that focal onsets may be a key feature distinguishing postinjury subconvulsive events from absence seizures (D'Ambrosio et al., 2005), there is a lack of quantitative control data illustrating this distinction. In addition, absence seizures in inbred rats often display asynchronous onsets with the leading cortical focus in rostral electrode sites near the perioral region of sensorimotor cortex (Meeren et al., 2002), leading to the current “cortical focus” theory of absence epilepsy (Meeren et al., 2005). Signal analytic methods have also demonstrated early focal changes in thalamocortical interactions demonstrating a perioral cortical hot-spot of hyperexcitability triggered seconds in advance of SWD (Lüttjohann and van Luijtelaar, 2015).
Progression of SWDs with age
An important concept in acquired epilepsy is that the frequency and severity of spontaneous recurrent seizures often increase with time after the injury. Using both nonconvulsive and convulsive seizures with durations comparable with those observed in human CPSs, a progressive increase in seizure frequency has been demonstrated in models of status epilepticus (Aldinio et al., 1985; Lothman and Bertram, 1993; Bertram and Cornett, 1994; Nissinen et al., 2000; Kelly et al., 2001; Kharlamov et al., 2003; Williams et al., 2009), and also more recently in a model of perinatal hypoxia-ischemia (Kadam et al., 2010). Previous studies with FPI (Eastman et al., 2015), based on relatively brief SWD-like events occurring at a frequency of many per hour, have also reported a progressive increase in frequency after brain insult. Although this observation would appear to be evidence of acquired epilepsy in the FPI model, our data showing increases in frequency and duration of SWD in control rats puts this interpretation in question.
Absence epilepsy is most prominent in childhood. However, in accepted inbred rat models of absence, as well as the present data, SWD events are rare in younger animals and become more frequent and prolonged as animals become older (Coenen and van Luijtelaar, 1987). Thus, the analogy with absence epilepsy in humans is poor in regard to life history of the disease. This has been noted as one of several weaknesses of absence epilepsy models (Kaplan, 1985), but does not suggest similarity to CPS of acquired epilepsy, because age-related increases in SWD are common in outbred and inbred rats.
Other brain-injury models of acquired epilepsy in the rat
Our failure to obtain CPS was surprising in light of other reports (Kharatishvili et al., 2006; Bolkvadze and Pitkänen, 2012; Shultz et al., 2013; Campbell et al., 2014; D. Poulsen, personal communication). This may indicate a marked sensitivity of the model to experimental parameters. We relied on rostral parasagittal FPI reported by others to be highly successful (D'Ambrosio et al., 2004, 2005; Curia et al., 2011). Like these studies, FPI resulted in a 10% mortality rate with severe impact pressures and post-trauma apnea >15 s that required resuscitation. Yet, these outcome measures alone may not indicate sufficient cortical and subcortical damage for epileptogenesis. Recent studies suggest caudal and lateral impact locations with a wider (5 mm) craniotomy may be more effective in yielding convulsive seizures and that the impact must be sufficient to produce damage to entorhinal cortex and hippocampus, as well as resulting in mortality rates on the order of 32% (Kharatishvili and Pitkänen, 2010). Only these examples seem appropriate as models of bona fide acquired epilepsy, producing CPSs in 50% of rats monitored continuously for 12 months. If the rostral parasagittal percussion model were equally effective in producing CPSs instead of SWD, we should have had at least five rats with convulsive seizures in the FPI group monitored for 1 year. Instead, we recorded no CPS or epileptiform discharges in any of our rats.
Chronic recurrent seizures with the characteristics of acquired epilepsy have also been seen after controlled cortical impact, another possible model of PTE (Statler et al., 2009; Bolkvadze and Pitkänen, 2012). In a perinatal hypoxia-ischemia model (Kadam et al., 2010) and in a new model of penetrating brain injury (Kendirli et al., 2014), both nonconvulsive and convulsive seizures have been observed. Thus, several other animal models of severe brain injury, including TBI and stroke, and not limited to status epilepticus, have shown nonconvulsive and convulsive seizures that appear substantially different from the SWDs observed here, and different from the SWD events previously attributed to epilepsy from FPI.
Conclusions
We conclude that the SWDs recorded here, in both FPI and control rats, are a model of absence seizures in humans. The fact that SWDs in normal Sprague-Dawley rats may be genetically enhanced in inbred species further strengthens the connection to human genetic epilepsy. Just like mild sensory stimulation, observed here to abort SWD, would not affect actual CPSs, methods for epilepsy therapy based on control of post-traumatic SWDs (D'Ambrosio and Miller, 2010; Eastman et al., 2015) are unlikely to impact human CPSs. All features of SWD events in the present results are remarkably similar to reports of models of PTE based on FPI (D'Ambrosio et al., 2009). The data reported here, combined with previous work (Kelly et al., 2006; Pearce et al., 2014), raises serious questions about the validity of the FPI model of acquired epilepsy. These studies suggest that a major reassessment of “What is a seizure?” in the context of acquired epilepsy, and thus “What defines a model of acquired epilepsy?,” is needed.
Footnotes
This work was supported by the US Army Medical Research and Material Command (Grant PR100040).
F.E.D. has equity interest in and receives consultant fees from Epitel, which is a company that makes telemetric recording devices; however, this work did not use these devices. The remaining authors declare no competing financial interests.
- Correspondence should be addressed to Dr Daniel S. Barth, Department of Psychology and Neuroscience, University of Colorado, Campus Box 345, Boulder, CO 80309. daniel.barth{at}colorado.edu