Background: Toll-like receptors (TLRs) had been regard to play an important role in inducing stroke-related focal inflammatory reaction. TLRs are not only related to innate immunity and adaptive immunity, but also activated by damaged cells. In brain, glia cells and neurons can express several types of TLRs, and it has been proved that TLR2 and TLR4 can worsen the ischemic damage during ischemic stroke. As for TLR8, besides its role in defending virus, it can also induce apoptosis as well. However, it is unknown whether TLR8 is upregulated during ischemic stroke and affecting apoptosis of neuron. Aim: The purpose of this study is to evaluate whether TLR8 gene is upregulated during ischemic stroke, and whether the protein level of TLR8 is increased. Methods: In this study, the modified stroke mouse model was created by “transient unilateral middle cerebral artery and bilateral common carotid arteries occlusion method”, and the stroke area was confirmed by TTC stain. The neurological deficit of stroke mice was evaluated by Longa 5 grading method. We analyzed the level of TLR8 mRNA of bilateral cerebral cortex by RT-PCR and real-time quantitative PCR, and compared the genetic expression at different time points of reperfusion. Besides, we used immunohistochemistry to verify whether ischemic stroke increases local expression of TLR8 protein, and to clarify the cell types with increased TLR8 expression. Besides, Western blot was used to evaluate the expression level of TLR8 protein, and to compare whether the expression level at stroke lesion side would be higher than contralateral side and sham-control mice. Results: The modified mouse stroke model was successfully created, which had an infarction at the cerebral cortex of the right middle cerebral artery territory. As compared with the model made by occlusion of the right middle cerebral artery, this modified model had larger infarct volume and higher mortality rate. Longer reperfusion time was associated with fewer neurological deficits. In the analysis of mRNA expression level, there were trends of increased expression in the ipsilateral cerebral cortex of stroke after ischemia for 90 min followed by reperfusion for 1 hour and 6 hours, and the differences between the group with reperfusion for 6 hours and sham-operated group had statistical significance (p = 0.021). In the immunohistochemistry, there were many cells in the ischemic region after reperfusion for 6 hours, which was characterized with condensed nuclei indicating apoptosis. These cells also had strong positive TLR8 stain in their cytoplasm. On the contrary, there was no TLR8 stain in the contralateral hemisphere. In the mouse brain with reperfusion for 18 hours, the cellularity in ischemic region reduced markedly, and these residual cells were also characterized by condensed nuclei and positive TLR8 stain. Besides, we also revealed that neurons and glia cell could express TLR8 during ischemic stroke. In the result of Western blot, the brain of mice underwent ischemia and reperfusion for 6 hours had increased expression of TLR8 in bilateral hemispheres, but there was no obvious side-to-side difference. Conclusion: This study revealed that, in the mouse stroke model, the cells in ischemic region had upregulation of mRNA and protein level of TLR8 during ischemic stroke. Furthermore, the study demonstrated that the cell types expressing TLR8 in ischemic stroke were neurons and glia cells. Further study is needed to clarify the function of TLR8 upregulation is protective or damage for neurons.