Spatiotemporal differences in the c-fos pathway between C57BL/6J and DBA/2J mice following flurothyl-induced seizures: A dissociation of hippocampal Fos from seizure activity

Kadiyala, Sridhar B.; Papandrea, Dominick; Tuz, Karina; Anderson, Tara M.; Jayakumar, Sachidhanand; Herron, Bruce J.; Ferland, Russell J.

doi:10.1016/j.eplepsyres.2014.11.009

Cited by 13 publications

(15 citation statements)

References 50 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For determination of forebrain and brainstem seizure thresholds throughout the repeated‐flurothyl paradigm, a second group of male mice (C57BL/6J [n = 24] and DBA/2J [n = 24]) were utilized, and their generalized forebrain and brainstem seizure thresholds were determined at three time points in the repeated‐flurothyl model: after one or eight flurothyl induction trials, or following eight flurothyl seizures, 28‐day incubation, and final flurothyl rechallenge (n = 8/time‐point/strain). Mice were ~8 weeks old when seizure testing began, consistent with previous studies utilizing the repeated‐flurothyl model …”

Section: Methodssupporting

confidence: 63%

“…Previously, we have shown that the ventromedial nucleus of hypothalamus (VMH) displays increased bilateral neuronal activity, as determined by Fos immunolabeling, in C57BL/6J mice having forebrain→brainstem seizures . Functionally, bilateral ibotenic acid lesions of the VMH are able to block the expression of the brainstem seizure component of forebrain→brainstem seizures .…”

mentioning

confidence: 97%

“…Following a 1‐month incubation period and a flurothyl rechallenge, C57BL/6J mice subsequently express a clonic‐forebrain seizure that rapidly transitions uninterruptedly into a tonic‐brainstem seizure . We refer to these seizures as forebrain→brainstem seizures, denoting the ictal progression from the forebrain seizure network to the brainstem seizure network . In fact, there is a loss of ictal discharge in hippocampal electrodes when the behavioral seizure transitions from the clonic phase to the brainstem phase .…”

mentioning

confidence: 99%

See 2 more Smart Citations

Dissociation of spontaneous seizures and brainstem seizure thresholds in mice exposed to eight flurothyl‐induced generalized seizures

Kadiyala

Ferland

2016

Epilepsia Open

Self Cite

View full text Add to dashboard Cite

Summary Objective C57BL/6J mice exposed to eight flurothyl-induced generalized clonic seizures exhibit a change in seizure phenotype following a 28-day incubation period and subsequent flurothyl rechallenge. Mice now develop a complex seizure semiology originating in the forebrain and propagating into the brainstem seizure network (a forebrain→brainstem seizure). In contrast, this phenotype change does not occur in seizure-sensitive DBA/2J mice. The underlying mechanism(s) was the focus of these studies. Methods DBA2/J mice were exposed to eight flurothyl-induced seizures (1/day) followed by 24-hour video-electroencephalographic recordings for 28-days. Forebrain and brainstem seizure thresholds were determined in C57BL/6J and DBA/2J mice following one or eight flurothyl-induced seizures, or after eight flurothyl-induced seizures, a 28-day incubation period, and final flurothyl rechallenge. Results Similar to C57BL/6J mice, DBA2/J mice expressed spontaneous seizures. However, unlike C57BL/6J mice, DBA2/J mice continued to have spontaneous seizures without remission. Because DBA2/J mice do not express forebrain→brainstem seizures following flurothyl rechallenge after a 28-day incubation period, this indicated that spontaneous seizures were not sufficient for the evolution of forebrain→brainstem seizures. Therefore, we determined whether brainstem seizure thresholds were changing during this repeated-flurothyl model and whether this could account for the expression of forebrain→brainstem seizures. Brainstem seizure thresholds were not different between C57BL/6J and DBA/2J mice on day one or on the last induction seizure trial (day eight). However, brainstem seizure thresholds did differ significantly on flurothyl rechallenge (day 28) with DBA/2J mice showing no lowering of their brainstem seizure thresholds. Significance These results demonstrated that DBA/2J mice exposed to the repeated-flurothyl model develop spontaneous seizures without evidence of seizure remission and provide a new model of epileptogenesis. Moreover, these findings indicated that the transition of forebrain ictal discharge into the brainstem seizure network occurs due to changes in brainstem seizure thresholds that are independent of spontaneous seizure expression.

show abstract

Section: Methodssupporting

confidence: 63%

mentioning

confidence: 97%

mentioning

confidence: 99%

See 1 more Smart Citation

Dissociation of spontaneous seizures and brainstem seizure thresholds in mice exposed to eight flurothyl‐induced generalized seizures

Kadiyala

Ferland

2016

Epilepsia Open

Self Cite

View full text Add to dashboard Cite

show abstract

“…Studies are currently underway attempting to elucidate what these genetic differences could be and the signaling pathways that may be involved. Last, gene expression changes have been observed in C57BL/6J mice over the course of the flurothyl induction period (Kadiyala et al, 2015), which could indicate the possibility of flurothyl-induced and/or seizure-induced changes in gene expression contributing to the transient nature of spontaneous seizures in C57BL/6J mice. Genes that were shown to change with flurothyl-induced seizures were similar to what has been observed in electrical kindling models (Christensen et al, 2010;Kadiyala et al, 2015).…”

Section: Discussionmentioning

confidence: 99%

Eight Flurothyl-Induced Generalized Seizures Lead to the Rapid Evolution of Spontaneous Seizures in Mice: A Model of Epileptogenesis with Seizure Remission

Kadiyala

Yannix

Nalwalk

et al. 2016

Journal of Neuroscience

View full text Add to dashboard Cite

The occurrence of recurrent, unprovoked seizures is the hallmark of human epilepsy. Currently, only two-thirds of this patient population has adequate seizure control. New epilepsy models provide the potential for not only understanding the development of spontaneous seizures, but also for testing new strategies to treat this disorder. Here, we characterize a primary generalized seizure model of epilepsy following repeated exposure to the GABA A receptor antagonist, flurothyl, in which mice develop spontaneous seizures that remit within 1 month. In this model, we expose C57BL/6J mice to flurothyl until they experience a generalized seizure. Each of these generalized seizures typically lasts Ͻ30 s. We induce one seizure per day

show abstract

“…Following a one month incubation period and a rechallenge with flurothyl, C57BL/6J mice express a clonic-forebrain seizure that rapidly and uninterruptedly transitions into a tonic-brainstem seizure (Samoriski and Applegate, 1997; Ferland and Applegate, 1998b). We refer to these seizures as forebrain→brainstem seizures denoting the ictal progression from the forebrain seizure network to the brainstem seizure network (Papandrea et al ., 2009; Kadiyala et al ., 2015). Lastly, C57BL6/J mice exposed to the repeated flurothyl seizure model rapidly develop spontaneous seizures that appear to remit without treatment following 1 month (Kadiyala et al ., 2016), in contrast to DBA2/J mice which also rapidly develop spontaneous seizures that do not remit (Kadiyala and Ferland, 2017).…”

Section: Introductionmentioning

confidence: 99%

The Repeated Flurothyl Seizure Model in Mice

Ferland

2017

BIO-PROTOCOL

View full text Add to dashboard Cite

Development of spontaneous seizures is the hallmark of human epilepsy. There is a critical need for new epilepsy models in order to elucidate mechanisms responsible for leading to the development of spontaneous seizures and for testing new anti-epileptic compounds. Moreover, rodent models of epilepsy have clearly demonstrated that there are two independent seizure systems in the brain: 1) the forebrain seizure network required for the expression of clonic seizures mediated by forebrain neurocircuitry, and 2) the brainstem seizure network necessary for the expression of brainstem or tonic seizures mediated by brainstem neurocircuitry. In seizure naïve animals, these two systems are separate, but developing models that can explore the intersection of the forebrain and brainstem seizure systems or for elucidating mechanisms responsible for bringing these two seizure systems together may aid in our understanding of: 1) how seizures can become more complex overtime, and 2) sudden unexpected death in epilepsy (SUDEP) since propagation of seizure discharge from the forebrain seizure system to the brainstem seizure system may have an important role in SUDEP because many cardiorespiratory systems are localized in the brainstem. The repeated flurothyl seizure model of epileptogenesis, as described here, may aid in providing insight into these important epilepsy issues in addition to understanding how spontaneous seizures develop.

show abstract

Spatiotemporal differences in the c-fos pathway between C57BL/6J and DBA/2J mice following flurothyl-induced seizures: A dissociation of hippocampal Fos from seizure activity

Cited by 13 publications

References 50 publications

Dissociation of spontaneous seizures and brainstem seizure thresholds in mice exposed to eight flurothyl‐induced generalized seizures

Dissociation of spontaneous seizures and brainstem seizure thresholds in mice exposed to eight flurothyl‐induced generalized seizures

Eight Flurothyl-Induced Generalized Seizures Lead to the Rapid Evolution of Spontaneous Seizures in Mice: A Model of Epileptogenesis with Seizure Remission

The Repeated Flurothyl Seizure Model in Mice

Contact Info

Product

Resources

About