Sex and Estrous Cycle Stage Shape Left-Right Asymmetry in Chronic Hippocampal Seizures in Mice

Abstract Lateralization of hippocampal function is indicated by varied outcomes of patients with neurologic disorders that selectively affect one hemisphere of this structure, such as temporal lobe epilepsy (TLE). The intrahippocampal kainic acid (IHKA) injection model of TLE allows for targeted damage to the left or right hippocampus, enabling systematic comparison of effects of left-right asymmetry on seizure and nonseizure outcomes. Although varying nonseizure phenotypic outcomes based on injection side in dorsal hippocampus were recently evaluated in this model, differences in chronic seizure patterns in left- (IHKA-L) versus right-injected (IHKA-R) IHKA animals have yet to be evaluated. Here, we assessed hippocampal seizure incidence in male and female IHKA-L and IHKA-R mice. Females displayed increased electrographic seizure activity compared with males at both two and four months postinjection. In addition, IHKA-L females showed higher seizure frequency than IHKA-R on diestrus and estrus at two months postinjection, but seizure duration and percent time in seizures were only higher in IHKA-L females on diestrus. These cycle stage-associated changes, however, did not persist to four months postinjection. Furthermore, this lateralized difference in seizure burden was not observed in males. These results indicate for the first time that the side of IHKA injection can shape chronic electrographic seizure burden. Overall, these results demonstrate a female-specific left-right asymmetry in hippocampal function can interact with estrous cycle stage to shape chronic seizures in mice with epilepsy, with implications for neural activity and behavior in both normal and disease states.


Introduction
The human brain is structurally and functionally lateralized (Gazzaniga, 1995). Although the hippocampus shows structural symmetry, neuroimaging studies suggest distinct functional roles of the two human hippocampi (Maguire and Frith, 2003;Howard et al., 2011). Importantly, several neurologic diseases affect the hippocampus, and the damage inflicted from neurologic disorders such as stroke and epilepsy can be unilaterally localized. Furthermore, patient outcomes can vary based on whether this damage is present in the left or right hippocampus. For example, patients with ischemic stroke injury in the left hippocampus have more apparent memory dysfunction than those with damage in the right (Schaapsmeerders et al., 2015). Additionally, people with epilepsy whose seizures arise from the left hippocampus show a higher degree of cognitive impairment than with right hippocampal seizure foci (Alessio et al., 2006;Addis et al., 2007;Phuong et al., 2021). This variation in outcomes based on the hemisphere containing the unilateral seizure focus may result from underlying functional lateralization in the hippocampus.
Temporal lobe epilepsy (TLE) is a common form of focal epilepsy in which seizures arise from a specific subregion and hemisphere of the temporal lobe, particularly the hippocampus (Engel, 2001). Interestingly, clinical observations in women with TLE suggest that the lateralization of a patient's seizure focus can impact seizure patterning in relationship to the menstrual cycle. For instance, clinical evidence suggests left-sided seizure foci are associated with higher incidence of seizures that cluster in the few days before and during menstruation, known as perimenstrual catamenial seizures, whereas right-sided seizure foci are associated with noncatamenial patterning of seizures spread across the menstrual cycle (Herzog, 2008;Quigg et al., 2009). Women with catamenial epilepsy are at higher risk for resistance to antiseizure medications (Choi et al., 2020), underscoring the importance of identifying the underlying mechanisms. Furthermore, recent imaging studies have suggested that shifting levels of ovarian hormones across the menstrual cycle can have structural and functional ramifications on the human hippocampus (Taylor et al., 2020;Gloe et al., 2021), although it remains unclear how these effects may interact with seizure focus lateralization to shape seizure patterning in relation to the ovarian cycle.
Recent studies demonstrating lateralization in the rodent hippocampus (Jordan, 2020) support the use of rodent models in investigating the mechanisms that underlie these differences. The intrahippocampal kainic acid (IHKA) mouse model of TLE, which allows for epileptogenic insults to be selectively targeted to the left or right hemisphere, shows neuropathological changes similar to human TLE (Bouilleret et al., 1999;Riban et al., 2002;Gröticke et al., 2008). This model also displays epileptiform discharges and spontaneous recurrent seizures (Bouilleret et al., 1999) that are hallmarks of human TLE (French et al., 1993;Mathern et al., 1995;Rusina et al., 2021). To date, researchers using this model have arbitrarily targeted the left or right hippocampus for KA injection, in the absence of systematic examination of differential outcomes of left and right IHKA injections. In a recent study, however, nonseizure phenotypic outcomes in C57BL/6J females injected with KA in the left or the right dorsal hippocampus were compared (Cutia et al., 2022). It was determined that dentate gyrus granule cell dispersion was altered in an injection site-specific manner (Cutia et al., 2022), indicating lateralized phenotypes at the level of the hippocampus. However, recent work has suggested that granule cell dispersion does not correlate to chronic seizure severity in left-injected IHKA mice (Lisgaras and Scharfman, 2022). Therefore, whether the lateralization effect in granule cell dispersion contributes to functional differences in hippocampal seizure incidence remains unclear. Furthermore, it is unknown whether potential lateralized differences in seizure occurrence are shaped by animal sex and, in females, estrous cycle stage. Here, the hypothesis that the laterality of IHKA injection leads to differential patterning of subsequent spontaneous recurrent seizures, both based on sex and estrous cycle stage, was tested.

Animals and estrous cycle monitoring
Animal procedures used in this study complied with the ARRIVE guidelines and were approved by the Institutional Animal Care and Use Committee of the University of Illinois Urbana-Champaign. Female and male C57BL/6J mice (#000664, The Jackson Laboratory) were purchased for delivery at six weeks of age. Mice were then housed in a 14/10 h light/dark cycle (lights off at 7 P.M.) and given food and water ad libitum. Animals were group-housed (two to five mice per cage) until the time of electrode implantation, after which all mice were housed singly.
Beginning one week after arrival, estrous cycle monitoring in females was performed between 9 and 11 A.M. using a vaginal cytology protocol previously described (Pantier et al., 2019). Female mice were assessed for at least 14 d to verify regular cycles before entering the study and resumed estrous cycle monitoring for the duration of the local field potential (LFP) recording periods. Cycle lengths for each mouse at each recording period were calculated as the average time to progress from one stage of estrus through all other stages to another phase of estrus for all captured cycles (J. Li et al., 2017Li et al., , 2018. To evaluate the development of differences in seizures over time, mice were recorded and underwent estrous cycle monitoring at both two and four months postinjection (mpi).

Stereotaxic IHKA and LFP electrode implantation surgeries
All stereotaxic surgeries were conducted under isoflurane anesthesia (2-3%, vaporized in 100% oxygen) with carprofen (0.5 mg/ml) for analgesia. Female mice underwent stereotaxic unilateral injection of KA (Tocris Bioscience; 50 nl of 20 mM prepared in 0.9% sterile saline) on the first day of diestrus following the first estrous cycle monitoring period. Age-matched males (. postnatal day 60) were injected in the same manner. Injections were randomly targeted to the left or right dorsal hippocampal region (relative to bregma: 2.0 mm posterior, 1.5 mm lateral, 1.4 mm ventral to cortical surface) as previously described (J. Li et al., 2017). Age-matched controls were injected with the same volume at the same location with saline. Saline-injected animals (female: left n = 5, right n = 5; males: left n = 3, right n = 4) showed no seizures and thus were not included in analyses.
All animals were allowed two weeks to recover from the injection before undergoing a second surgery for LFP electrode implantation. Two twisted bipolar electrodes (P1 Technologies) were implanted into the ipsilateral hippocampus just dorsal and lateral to the injection site (relative to bregma: 2.0 mm posterior, 1.75 mm lateral, 1.25 mm ventral; Armstrong et al., 2013;J. Li et al., 2020;Cutia et al., 2022;. Anchor microscrews (J.I. Morris Co) were placed into the skull and stabilized with dental cement (Teets "Cold Cure" Dental Cement). Mice were singly housed after electrode implantation and for the duration of the remaining experimental period.

LFP recording and analysis
One week after electrode implantation, the mice were tethered to an electrical commutator (P1 Technologies) connected to a Brownlee 440 amplifier (NeuroPhase) with gain set at 1 K. LFP signals were recorded as the local field potential differential between the two electrodes (Armstrong et al., 2013), sampled at 2 kHz and digitized to recorder software written in MATLAB (Armstrong et al., 2013). Mice were recorded at 1, 2, and 4 mpi. The 2 and the 4 mpi recording periods were evaluated in the current study; the LFP data collected at 1 mpi from the female animals in the present study were included in another study    (Cutia et al., 2022), and are therefore not shown here. In addition, some female mice (IHKA-R = 2, IHKA-L = 5) included in this study were included in a previous publication (J. Li et al., 2020), but the analysis of the data from these animals conducted in the previous work is distinct from that reported here. All recordings were analyzed with an automated electrographic seizure analyzer (Zeidler et al., 2018) with the minimal seizure duration set at 5 s and the interictal interval at 6 s. It should be noted that most seizures detected in the IHKA mouse model are electrographic and do not generalize to behavioral convulsive seizures (Bouilleret et al., 1999;Gröticke et al., 2008;Klein et al., 2015).

Hippocampal granule cell dispersion visualization and quantification
Brains from a randomly selected subset of females and males (8-10 mice per group) were sectioned into 40-mmthick coronal sections using a freezing microtome (Leica SM 2010R). Every third section from the dorsal hippocampal region was used for histology, with a total of four to six sections evaluated for each mouse. Sections were stained with cresyl violet (Sigma-Aldrich C5042) for 12 min at room temperature, dehydrated using graded ethanol solutions (70-100%), before being cleaned with Xylene and coverslipped with Permount. Images were collected using an Olympus BX43 brightfield microscope with an Infinity 3-6UR Teledyne Lumenera Camera and Infinity Capture software (Lumenera). Dentate gyrus granule cell dispersion ipsilateral to the KA injection was quantified as previously described (Cutia et al., 2022;Lisgaras and Scharfman, 2022).

Ovarian hormone assays
After completion of LFP recordings at 4 mpi, trunk blood was collected from the female mice at the time of euthanasia. All female mice were euthanized by decapitation on diestrus between 12 and 4 P.M. Trunk blood was stored at 4°C for 24 h, and centrifuged for 15 min at 4°C. Serum was then isolated and stored at À80°C until the time of assay. ELISAs for progesterone (IBL America, IB79105) and estradiol (American Laboratory Products Co, 11-ESTHU-E01) were performed on serum samples using commercial kits according to the manufacturers' instructions and evaluated using a Bio-Tek 800TS Microplate Absorbance Reader. One serum sample from the IHKA-L and one from the IHKA-R group were excluded from the study based on low quality. One IHKA-R sample was tested for progesterone but not for estradiol because of limited sample volume. Additionally, given limited sample volume, all samples were run in singlet to accommodate multiple hormone assays. Intra-assay coefficient of variation values calculated from controls run in duplicate were 5.1 for estradiol and 6.8 for progesterone.

Statistical analysis
All statistical comparisons were performed using R software. Comparisons of seizure parameters between male and female IHKA-L and IHKA-R animals were made using two-way ANOVA and Tukey's post hoc tests. Comparisons of seizure parameters between IHKA-L and IHKA-R females within individual estrous cycle stages were made using twosample t tests, or Wilcoxon rank-sum tests depending on the normality of the data. Comparisons of progesterone, estradiol, and the progesterone-to-estradiol (P 4 :E 2 ) ratio between IHKA-L and IHKA-R groups were made using Wilcoxon rank-sum tests. Normality was evaluated using Shapiro-Wilks tests, and homogeneity of variance was evaluated using Levene's tests. Correlations between percent of time in seizures and granule cell dispersion, estrous cycle length, and hormone levels were made using Pearson's correlations. Information on the estimation statistics used to generate statistically significant results in the study is provided in Table 1.

Sex differences in seizure duration and percent time in seizures persist to four months after injection
To characterize the progression of seizure activity over time in these animals, the same animals evaluated at 2 mpi were also evaluated at 4 mpi, with the exception of two IHKA-R females that died before the four-month time point. By 4 mpi, there was no effect of injection site (F (1,49) = 0.0001, p = 0.99) or sex (F (1,48) = 2.17, p = 0.15; Fig. 2A) on seizure frequency. Seizure duration, however, was still affected by sex and higher in females compared with males (F (1,49) = 11.84, p = 0.001; Fig. 2B). Percent time in seizures was also influenced by sex (F (1,49) = 8.95, p = 0.004; Fig. 2B), as IHKA females displayed higher time in seizures than male counterparts (IHKA-L: p = 0.02, IHKA-R: p = 0.02; Fig. 2B). Together, these results indicate that IHKA females maintain higher seizure duration and percent time in seizures than males when recorded at 4 mpi.
Left-right asymmetry in seizure burden in IHKA females is most pronounced on diestrus at two months after injection To investigate the relationship of estrous cycle phase to seizure patterns, female animals were evaluated across diestrus, estrus, and proestrus. Recordings from 3 d of each estrous cycle stage from at least three different cycles per mouse were averaged to quantify seizure parameters present on each estrous cycle stage. At 2 mpi, IHKA-L females displayed higher seizure frequency than IHKA-R during diestrus and estrus (diestrus: t = 2.05, pvalue = 0.05; estrus t = 2.41, p-value = 0.02; Fig. 3A), with a trend toward elevated seizure frequency in IHKA-L females during proestrus (t = 1.97, p = 0.06; Fig. 3A). However, seizure duration and percent time in seizures were higher in IHKA-L compared with IHKA-R females only during diestrus [seizure duration: W = 261, p-value = 0.04 (Fig. 3B); time in seizure: W = 286, p-value = 0.004 (Fig. 3C)]. These results suggest that there are distinct elevations in seizure parameters in IHKA-L compared with IHKA-R females at 2 mpi, and that these differences are more pronounced during diestrus.

Left-right asymmetries and effects of estrous cycle stage on seizure burden in females are dampened by four months after injection
In contrast to the pattern of asymmetric seizure burden at 2 mpi, there were no appreciable differences between IHKA-L and IHKA-R females in any seizure parameters on diestrus or estrus at 4 mpi (Fig. 4). During proestrus, however, IHKA-R animals showed trends for elevated seizure frequency (t = À2.00, df = 32, p = 0.05; Fig. 4A) and percent time in seizures (t = À1.99, df = 32, p = 0.06; Fig. 4C). These results suggest that the influences of injection side on seizure parameters in females are less distinct at 4 mpi.

Degree of granule cell layer dispersion is not correlated to seizure burden severity
Once LFP recordings were completed, brains from a subset of IHKA-L (male n = 9; female n = 10) and IHKA-R (male n = 8; female n = 10) mice were collected and sectioned for analysis of granule cell layer dispersion through visualization with Nissl stain (Fig. 5A). Granule cell dispersion was calculated as the ratio between the value for the hippocampus ipsilateral to the site of injection and the equivalent portion of hippocampus contralateral to the side of injection (I:C ratio) (Cutia et al., 2022). There were no differences between IHKA groups in proportions of mice with and without granule cell dispersion (Fig. 5B). As all brain samples were collected after completion of recordings at the 4 mpi time point, these ratios were compared with the average percent of time that each animal spent in seizures at the 4 mpi recording period. There were no correlations between percent time spent in seizures and I:C ratio in IHKA-L (males: r 2 = 0.60, Research Article: New Research p = 0.08; females r 2 = 0.1, p = 0.77) nor IHKA-R mice (males: r 2 = À0.34, p = 0.38; females: r 2 = À0.28, p = 0.5; Fig. 5C). These results indicate that the degree of granule cell dispersion and seizure severity are not correlated when assessed at 4 mpi in the IHKA model.

Estrous cycle prolongation is not correlated to seizure burden
Estrous cycle disruption is common in a majority of female IHKA mice (J. Li et al., 2017;Cutia et al., 2022). To determine whether the degree of estrous cycle disruption is correlated to the severity of seizure burden, and whether this relationship changes over time, estrous cycle lengths of each mouse were quantified from the cycle monitoring data collected during LFP recordings and correlated to the percentage of time in seizures of each mouse over a 7-d period encompassing all cycle stages. There were no correlations found between estrous cycle length and percent of time in seizures for IHKA-R mice at either 2 (r 2 = 0.3, p = 0.20) or 4 mpi (r 2 = 0.08, p = 0.75; Fig. 6). IHKA-L females showed a weak correlation at 2 mpi (r 2 = 0.5, p = 0.04) but showed no correlation at 4 mpi (r 2 = 0.15, p = 0.56). These data align with previous work that reported no significant correlation between cycle length and seizure burden in IHKA-R mice at 2 mpi (J. Li et al., 2020).

Discussion
Clinical evidence indicates that the hemisphere of a temporal lobe seizure focus may influence seizure cluster patterning in women with epilepsy (Herzog, 2008;Quigg et al., 2009). Preclinical evidence suggests that the IHKA model of TLE holds validity for investigating mechanisms of the aforementioned clinical findings, as differences in hippocampal granule cell dispersion and pituitary gene expression are altered based on site of IHKA injection (Cutia et al., 2022). Despite this evidence, the relationship between seizure patterns in IHKA animals and the site of injection has yet to be documented. In the present study, we evaluated the development and presentation of seizures recorded with LFP at 2 and 4 mpi in male and female IHKA-L and IHKA-R mice. The results indicate a distinct sex difference in seizure parameters between male and female IHKA mice, with higher seizure burden in females. In addition, IHKA-L females display higher overall seizure burden compared with IHKA-R females on diestrus at 2 mpi. On proestrus and estrus, however, this effect is only present for seizure frequency. These results suggest that the phase of the estrous cycle influences left-right asymmetry in seizure burden in IHKA females. Sex differences have been observed across multiple animal models of TLE and seizure induction . For example, female rats typically have longer latency to acute seizures and lower mortality rates after systemic pilocarpine injection (Mejías-Aponte et al., 2002). In another study, male rats treated systemically with pilocarpine developed longer lasting seizures over a period of several months, whereas female rats tended to have higher frequency of seizures (Matovu and Cavalheiro, 2022). In a systemic kainic acid injection seizure induction model, male rats had greater susceptibility to seizures than their female counterparts (Mejías-Aponte et al., 2002). In mice, however, the results regarding systemic KA injection have been mixed, with one study reporting higher mortality rates, more severe seizures, and increased neurodegeneration in females (Zhang et al., 2008), but another study describing higher mortality, seizure severity, cognitive impairment, hippocampal neuron loss, and reactive gliosis in males (F. Li and Liu, 2019). With respect to chronic epilepsy in the IHKA model, one report indicated that female mice do not show the same latent period duration following IHKA injection as males, and that hippocampal paroxysmal discharges were rare in females when examined four weeks after injection (Twele et al., 2016). By contrast, another study conducted using the IHKA model did not indicate an effect of sex on seizures, cognitive impairment, or histopathology (Zeidler et al., 2018), although this latter study was not powered to evaluate sex differences. Here, males showed reduced overall seizure burden compared with females, in contrast to other IHKA studies in mice. However, the effect of sex in animal models of epilepsy can vary greatly, influenced by factors such as methodology of seizure induction, measurement criteria for seizures, the species and/or strain of animal, and the age at which seizures are induced (Scharfman and MacLusky, 2014;Christian et al., 2020). Once brain tissue was harvested at 4 mpi, the level of granule cell dispersion was quantified and correlated to the percentage of time spent in seizures for each animal.
The lack of correlations observed between granule cell dispersion and seizure burden is in agreement with other recent studies (Lisgaras and Scharfman, 2022). Although pyramidal cell layer length has been correlated with seizure severity in IHKA mice, this relationship was shown in a cohort in which seizure activity was monitored at the cortical surface using subdural screw electrodes (Lisgaras and Scharfman, 2022). A similar analysis could not be done using the present dataset because of the location of the LFP electrode in the hippocampus. Another limitation is that the tissue could only be collected after all LFP recordings were complete at 4 mpi. In this regard, lateralized differences in granule cell dispersion at 2 mpi were previously shown in a cohort of animals that were not implanted with LFP electrodes (Cutia et al., 2022). As we observed a decrease in lateralized effects in seizure parameters at 4 mpi, it remains possible that granule cell dispersion (and/or other signs of hippocampal sclerosis) and seizure burden are correlated at 2 mpi.
The differences in seizure patterns of IHKA-L and IHKA-R mice on certain estrous cycle stages may arise because  of interactions between fluctuating ovarian hormones and basal differences in the left and right hippocampi. For example, the left and right murine hippocampi have distinct populations of synapses (Shinohara et al., 2008;El-Gaby et al., 2015), and there is evidence for left-right asymmetry in hippocampal function in mice (Shipton et al., 2014). There is also evidence that gonadal hormones can impact hippocampal lateralization, with androgen receptor signaling suggested to underlie larger granule cell layer volume in the right hippocampus of both male and female C57BL/6J mice (Tabibnia et al., 1999). Therefore, it is possible that the fluctuations in ovarian hormones across the estrous cycle, and lateralized interactions between ovarian hormones and the hippocampus, produce left-right asymmetry in emergent hippocampal phenotypes. In mice, the P 4 :E 2 ratio is higher on diestrus than on proestrus and estrus (Walmer et al., 1992;Christian et al., 2020), and lower P 4 :E 2 may promote seizure activity in humans (Bonuccelli et al., 1989;Herzog et al., 1997;Herzog, 2015). A limitation of the lack of correlation between chronic seizure burden and progesterone/estradiol levels in the present study is that the hormones were measured in blood samples collected at 4 mpi, whereas the left-right asymmetry in seizure burden was most prominent at 2 mpi. However, previous work indicated a lack of difference in serum progesterone and estradiol, and P 4 :E 2 ratio, between IHKA-L and IHKA-R diestrous females at 2 mpi (Cutia et al., 2022), suggesting that a relationship between circulating levels of these hormones and left-right asymmetry in seizure burden at 2 mpi is unlikely. However, a differential response of left versus right hippocampus to estradiol and/or progesterone actions cannot be ruled out, nor can differences in local hippocampal synthesis of these hormones or their metabolites (Tokuda et al., 2011;Sato and Woolley, 2016;Brann et al., 2022).
Previous work established that the estrous cycle can have impacts on interictal spike presentation in systemic kainic acid and pilocarpine models of TLE in rats (D'Amour et al., 2015), and IHKA mice can exhibit elevated seizure duration and time spent in seizures on proestrus and estrus combined compared with diestrus (J. Li et al., 2020). Importantly, most IHKA female mice exhibit elongated estrous cycles (J. Li et al., 2017Li et al., , 2018Li et al., , 2020Cutia et al., 2022;Ingram et al., 2022;. Here, estrous cycle length was not significantly correlated to seizure burden in either IHKA-L or -R mice, consistent with previous reports (J. Li et al., 2020). Therefore, it does not appear that higher epilepsy severity drives greater estrous cycle disruption, nor is there a reciprocal relationship of cycle disruption promoting increased seizure burden in the IHKA model. In previous work examining mice without LFP recordings, estrous cycle disruption persisted to 4 mpi in IHKA-R but not IHKA-L females (Cutia et al., 2022). The dissipation in phenotypes in IHKA-L females suggests that asymmetries may be influenced by the progression of the disease, the increased age of the animals, or both. The progressive decline of certain physiological functions as mice age could shape the varied patterns seen at different timepoints. It is also possible that the observed differences at 2 mpi are indicative of differential rates of disease progression that eventually normalize, such that seizure severity lacks overt sex-based and hemisphere-based differences by 4 mpi. In total, these findings suggest that injection site and time of recording after injection in IHKA female mice are factors to be considered in experimental design that can shape overall seizure burden outcomes.
The female-specific presence of seizure burden asymmetries aligns with clinical findings of reproductive endocrine disorder development among TLE patients. Male and female patients with TLE often develop reproductive endocrine dysfunction (Herzog et al., 1986a, b), but females more consistently develop higher rates of dysfunction than the general population (Herzog et al., 1986b;Herzog and Schachter, 2001). Moreover, the propensities for developing polycystic ovary syndrome or hypothalamic amenorrhea are differentially based on the hemisphere of the seizure focus in females (Herzog, 1993;Kalinin and Zheleznova, 2007). These findings indicate that there may be differential mechanisms in the left and right hemispheres that contribute to the ability of seizures to promote reproductive endocrine dysfunction. Furthermore, the different patterns of seizure clustering in association with menstrual cycle phase in females with left-sided or right-sided TLE (Herzog, 2008;Quigg et al., 2009) suggest that left-right asymmetry can shape the presentation of both epilepsy and associated comorbidities. The present findings of female-specific asymmetry in seizure presentation are thus consistent with clinical reports, and support the translational validity of the IHKA mouse model in recapitulating at least some mechanistic differences in structural or functional changes because of seizures in the left and right hippocampus, as well as sex differences in this lateralization.
The IHKA mouse model displays many characteristics recapitulating human epilepsy, underscoring the validity of its use in investigating neural mechanisms of TLE. The present work indicates that seizure burden outcomes within this preclinical model are influenced by sex and, in females, laterality of epileptogenic insult. Female mice also show estrous cycle-associated changes in seizure activity that vary depending on the hemisphere of targeted hippocampal damage. This work thus reveals female-specific left-right asymmetry in functional properties of the murine hippocampus, with implications for both normal and disease states.