Post-traumatic Epilepsy - Pathophysiology

Pathophysiology

For unknown reasons, trauma can cause changes in the brain that lead to epilepsy. There are a number of proposed mechanisms by which TBI causes PTE, more than one of which may be present in a given person. In the period between a brain injury and onset of epilepsy, brain cells may form new synapses and axons, undergo apoptosis or necrosis, and experience altered gene expression. In addition, damage to particularly vulnerable areas of the cortex such as the hippocampus may give rise to PTE.

Blood that gathers in the brain after an injury may damage brain tissue and thereby cause epilepsy. Products that result from the breakdown of hemoglobin from blood may be toxic to brain tissue. The "iron hypothesis" holds that PTE is due to damage by oxygen free radicals, the formation of which is catalyzed by iron from blood. Animal experiments using rats have shown that epileptic seizures can be produced by injecting iron into the brain. Iron catalyzes the formation of hydroxyl radicals by the Haber-Weiss reaction; such free radicals damage brain cells by peroxidizing lipids in their membranes. The iron from blood also reduces the activity of an enzyme called nitric oxide synthase, another factor thought to contribute to PTE.

After TBI, abnormalities exist in the release of neurotransmitters, chemicals used by brain cells to communicate with each other; these abnormalities may play a role in the development of PTE. TBI may lead to the excessive release of glutamate and other excitatory neurotransmitters (those that stimulate brain cells and increase the likelihood that they will fire). This excessive glutamate release can lead to excitotoxicity, damage to brain cells through overactivation of the biochemical receptors that bind and respond to excitatory neurotransmitters. Overactivation of glutamate receptors damages neurons; for example it leads to the formation of free radicals. Excitotoxicity is a possible factor in the development of PTE; it may lead to the formation of a chronic epileptogenic focus. An epileptic focus is the part of the brain from which epileptic discharges originate.

In addition to chemical changes in cells, structural changes that lead to epilepsy may occur in the brain. Seizures that occur shortly after TBI can reorganize neural networks and cause seizures to occur repeatedly and spontaneously later on. The kindling hypothesis suggests that new neural connections are formed in the brain and cause an increase in excitability. The word kindling is a metaphor: the way the brain's response to stimuli increases over repeated exposures is similar to the way small burning twigs can produce a large fire. This reorganization of neural networks may make them more excitable. Neurons that are in a hyperexcitable state due to trauma may create an epileptic focus in the brain that leads to seizures. In addition, an increase in neurons' excitability may accompany loss of inhibitory neurons that normally serve to reduce the likelihood that other neurons will fire; these changes may also produce PTE.