Chronic epilepsy is thought to develop due to dysfunctions in various ion channels. Previous researchers in the Poolos lab manipulated a signaling cascade regulating these channels and discovered an increase in activation of c-Jun N-terminal kinase (JNK) in animals experiencing seizures. My project aims to understand this connection and the timeline of JNK activity during the development of epilepsy, hypothesizing that JNK activity will precede epilepsy onset and may be a cause of chronic epilepsy. To study epilepsy, we administer research-bred rats a pilocarpine injection. Shortly after, the rat is in status epilepticus (SE), a state of continuous seizures. After one hour, a phenobarbital injection is administered to halt SE. Seizures begin around one week post-SE and achieve steady-state frequency around four weeks. I analyze brain tissue samples taken after one hour, one day, and one week post-SE using Western-blotting to obtain a relationship between phosphorylated-JNK (pJNK) levels from pilocarpine-treated rats to control rats. There are three JNK isoforms, separated into two bands: 54kDa and 46kDa. JNK 1 is primarily in the 46kDa band, JNK 2 is present in both bands, and JNK 3 is predominately in the 54kDa band. For the 54kDa band, I have discovered a significant increase of pJNK one hour post-SE (124±8.1%, p<0.05, n=7), one day post-SE (132±9.2%, p<0.05, n=14), an insignificant change at one week post-SE (100±9.6%, p>0.05, n=10) and a significant increase in chronic epilepsy (126±7.6%, p<0.05, n=12). For the 46kDa band, I have discovered an insignificant change of pJNK at one hour post-SE (101±7.1%, p>0.05, n=8), a significant increase one day post-SE (123±12.8%, p<0.05, n=12), one week post-SE (122±7.6%, p<0.05, n=10) and in chronic epilepsy (116±5.9%, p<0.05, n=12). We hope that, by understanding JNK activation, we can explore avenues for medicine and treatments for epilepsy, through antiepileptic drugs and other therapeutic options.