Nowadays, the treatment of using electrical stimulation has been investigated and verified, such as functional electrical stimulation (FES) and therapeutic electrical stimulation (TES). By stimulating abnormal nerve sites of the patients, they may restore some body functions. As the CMOS process developed, using an implantable device to provide stimulus current can be accomplished. The biomedical chip is made by the combination of microelectronics, medicine and biochemical such as epilepsy prosthetic SoC. The methodology to suppress epilepsy seizure is constant current stimulation, and the effective scale of stimulus current for human body is up to 1-3mA. For safety considerations, the stimulus driver should be designed to deliver charge-balanced biphasic current pulses and reduce the mismatch between the anodic and cathodic pulses to avoid charge accumulation and damaging the never cells. In addition, the electrode-tissue impedance varies with the position and depth of the electrodes in human body. Consider the loading adaptation, high voltage supply 10V is required in the output stage. To be integrated with other circuits into SoC, this work is implemented in low-voltage process. However, the power supply of the SoC is only 1.8V. DC-DC boost converter is required to raise the voltage potential for the stimulus driver. By using voltage limiting technique, the proposed stimulus driver, which consists of low voltage devices, is able to sustain high voltage (10V) without gate-oxide overstress. 3-bit amplitude signals are used to control the scale of stimulus current from 0.5mA to 3mA, with 0.5mA a step. The overall circuit has been fabricated by the TSMC 0.18μm 1.8V/3.3V CMOS process.