Conventionally, recording neural responses to adequate stimuli in peripheral has been the principle method for studying brain functions of somatosensory. However, under prolonged or repeated stimulation, adaptation or sensitization in peripheral may make it difficult to consistently evoke neuronal responses. By utilizing the technique of electrical stimulation instead, neurons can be directly stimulated to evoke controllable excitation and thus analyzed quantitatively, without the limitations of adequate stimulation. In this study, a deep-brain electrical microstimulation method was established and evaluated to verify whether it can be used as a tool to explore neuronal function in the brain. Male Wistar rats were used in this study. Tactile stimulation (TS) was applied to the hindpaw, and the TS-evoked responses in the thalamus and cerebral cortex were recorded independently with two glass microelectrodes. Then, electrical microstimulation (ES) was applied through the same microelectrode previously used for recording in the thalamus, and the ES-evoked cortical responses were recorded also by the same microelectrode in the cortex. The evoked cortical action potentials (APs) of both types of stimulation were carefully compared. The waveforms of ES-evoked APs were similar to those of TS-evoked APs. The transmission latency from thalamus to cortex of the ES-evoked response was also compatible with that of the TS-evoked response. These results suggested that ES can be used to directly stimulate the tactile neuron and mimic the effect of TS. With its precision and fidelity, this method may contribute to the exploration of neuronal functions in the brain.