Epilepsy is a neuronal disorder and affects 1% population of the world. One-third of patients have refractory epilepsy, which is hard to be controlled with anti-epileptic drugs (AEDs). Resective surgery is an alternative treatment for refractory epilepsy but not all of patients with refractory epilepsy are suitable for this surgery. Therefore, other alternative therapy, such as an electrical stimulation of deep brain structure is a pressing need for refractory epilepsy. Deep brain stimulation (DBS) has used in the treatment of movement disorders, like Parkinson’s disease. The anterior nucleus of the thalamus (ANT) may be a promising brain region for DBS in suppressing epilepsy, because the ANT has a wide projection to neocortex via the cingulate gyrus. In our study, we are going to evaluate the anti-epileptic efficacy of ANT DBS in pentylenetetrazol (PTZ)-induced epilepsy rat model, assess the effects of ANT DBS on sleep in epileptic rats, and determinate the mechanisms of DBS. Our previous study shows that pre-treatment of DBS for 1 hour prior to the epilepsy onset exhibits better anti-epilepsy efficacy than 30 minutes DBS in pilocarpine-induced epilepsy rats. In current study, rats were divided into three groups: the PTZ group, PTZ with 30-min DBS group (stimulation starting 10 mins prior to the PTZ injection) and PTZ with 3-h DBS group (stimulation starting 1 hr prior to the PTZ injection). We analyzed the latency to seizure onset and the duration of seizure after PTZ injections. Rats in the 30-min DBS group showed a longer seizure onset latency and shorter duration of seizure than the PTZ group in the first four times of PTZ injections. However, after 14th time of PTZ injection, there was no significant difference between PTZ group and PTZ with DBS treatment group in the amplitude and the duration of seizure. DBS prolonged the latency to seizure onset and reduce the duration of seizure at the first few times of PTZ injections. We then analyzed the effects of ANT DBS on sleep in the epileptic rats. Both non-rapid eye movement (NREM) sleep and rapid eye movement (REM) sleep time in light period showed significantly increase in rats received the 1st 30-min DBS, but only the amount of REM sleep remained increasing in rats treated with 30-min DBS after the 14-time PTZ injection. Both NREM sleep and REM sleep in PTZ with 3-h DBS group after the 14-time PTZ injection showed no significant change compared with both PTZ and PTZ with 30-min DBS group. We also found that the delta power during NREM sleep was decreased in epileptic rats with DBS when compared with those without receiving DBS. According to other researches, seizure was facilitated during NREM sleep and suppressed during REM sleep. DBS seems to decrease the power of synchronized brain wave in NREM sleep to increase epilepsy threshold and to increase the amount of REM sleep to suppress epilepsy. Our previous research demonstrated that PTZ increases the expression of the subunits of N-methyl-d-aspartate (NMDA) receptors, which plays important roles in neuronal excitability. The expression of NMDA receptor subunits, NR1, NR2 and p-NR2, in cortex, hippocampus and thalamus after 15 times of ANT DBS and PTZ injection were measured by the Western blot. NR2 was decreased in cortex and hippocampus of ANT DBS 30-min group. NR1 and p-NR2 had no significant difference in ANT DBS 30-min group. The reduction of NMDA receptor expression was involved in the mechanism of ANT-DBS anti-epileptic efficacy. Last, our goal is to apply a close-loop DBS microchip, designed by NTU Department of Electrical Engineering, to the epileptic animals and determine whether the microchip successfully suppresses the seizure propagation.