Can structural or functional changes following traumatic brain injury in the rat predict epileptic outcome?

Abstract: Summary Purpose Post-traumatic epilepsy (PTE) occurs in a proportion of traumatic brain injury (TBI) cases, significantly compounding the disability, risk of injury, and death for sufferers. To date, predictive biomarkers for PTE have not been identified. This study used the lateral fluid percussion injury (LFPI) rat model of TBI to investigate whether structural, functional, and behavioral changes post-TBI relate to the later development of PTE. Methods Adult male Wistar rats underwent LFPI or sham-injury.… Show more

“…As shown in Fig. 1, volumetric and morphological changes in the hippocampus and other limbic structures have been reported in both SE [26][27][28][29] and FPI models [11,23,30,31]. However, these changes are typically preceded by abnormalities identified by other more sensitive neuroimaging methods [11,23,[28][29][30][31].…”

“…As seen in Fig. 1, [18F]FDG-PET following FPI in rats has also identified acute and persistent hypometabolism that preceded significant structural atrophy [11,30], and may predict the later onset of PTE [11]. While further research is clearly required, and other limitations must be considered [62], these findings, together with the ability to assess other relevant pathophysiological processes in vivo, make PET a valuable experimental tool in the investigation of epileptogenesis.…”

“…Animal models of epilepsy, both acquired and genetic, provide the opportunity to rigorously investigate experimental subjects known to be experiencing epileptogenic processes, and thereby hold the potential to increase our understanding and identify early biomarkers of this disease. Briefly, some of the most commonly used and well-validated animal models of epilepsy that will be discussed in this section include exposure to proconvulsant chemicals, such as pilocarpine or kainic acid, to induce status epilepticus (SE) and consequent spontaneous seizures modeling temporal lobe epilepsy (TLE) [8]; electrical stimulation, or kindling, of temporal brain regions (e.g., amygdala) to model TLE [8]; and the fluid percussion brain injury (FPI) model of traumatic brain injury (TBI) and posttraumatic epilepsy (PTE) [9][10][11]. This section will provide a summary of the epileptogenic-related changes and neuroimaging biomarkers that have been identified to date within these models.…”

“…However, these changes are typically preceded by abnormalities identified by other more sensitive neuroimaging methods [11,23,[28][29][30][31]. As such, volumetric and morphological changes may not be ideal neuroimaging biomarkers to identify early pathophysiological processes involved in epileptogenesis, but may have more of a role to assess subsequent progressive neurodegenerative changes, in particular atrophy of key structures such as the hippocampus, that may follow an epileptogenic brain insult [11,29,30,32].…”

Neuroimaging the Epileptogenic Process

“…As shown in Fig. 1, volumetric and morphological changes in the hippocampus and other limbic structures have been reported in both SE [26][27][28][29] and FPI models [11,23,30,31]. However, these changes are typically preceded by abnormalities identified by other more sensitive neuroimaging methods [11,23,[28][29][30][31].…”

“…As seen in Fig. 1, [18F]FDG-PET following FPI in rats has also identified acute and persistent hypometabolism that preceded significant structural atrophy [11,30], and may predict the later onset of PTE [11]. While further research is clearly required, and other limitations must be considered [62], these findings, together with the ability to assess other relevant pathophysiological processes in vivo, make PET a valuable experimental tool in the investigation of epileptogenesis.…”

“…Animal models of epilepsy, both acquired and genetic, provide the opportunity to rigorously investigate experimental subjects known to be experiencing epileptogenic processes, and thereby hold the potential to increase our understanding and identify early biomarkers of this disease. Briefly, some of the most commonly used and well-validated animal models of epilepsy that will be discussed in this section include exposure to proconvulsant chemicals, such as pilocarpine or kainic acid, to induce status epilepticus (SE) and consequent spontaneous seizures modeling temporal lobe epilepsy (TLE) [8]; electrical stimulation, or kindling, of temporal brain regions (e.g., amygdala) to model TLE [8]; and the fluid percussion brain injury (FPI) model of traumatic brain injury (TBI) and posttraumatic epilepsy (PTE) [9][10][11]. This section will provide a summary of the epileptogenic-related changes and neuroimaging biomarkers that have been identified to date within these models.…”

“…However, these changes are typically preceded by abnormalities identified by other more sensitive neuroimaging methods [11,23,[28][29][30][31]. As such, volumetric and morphological changes may not be ideal neuroimaging biomarkers to identify early pathophysiological processes involved in epileptogenesis, but may have more of a role to assess subsequent progressive neurodegenerative changes, in particular atrophy of key structures such as the hippocampus, that may follow an epileptogenic brain insult [11,29,30,32].…”

Neuroimaging the Epileptogenic Process

“…Recently, Schultz et al [67] reported that abnormalities in the surface morphology of the ipsilateral hippocampus present at 1 week after lateral FPI predicted the occurrence of epilepsy 6 months after TBI [67]. We recently investigated whether quantitative T2, T1ρ, and diffusion (Dav) assessed with MRI at 9 days, 23 days, or 2 months after TBI in the peri-lesional cortex, thalamus, and hippocampus would predict seizure susceptibility in the PTZ test at 12 months after TBI [68].…”

Epilepsy Related to Traumatic Brain Injury

Epilepsy Biomarkers