The thesis presents the design of analog front-end circuits for biomedical applications. The analog-front-end circuit is the most critical building block in bio-potential monitoring SoC, since it should amplify very weak signals under noisy aggressors. Three circuit architectures are implemented and in this thesis. The first chip proposes a 4-channel low noise amplifier that utilizes a time-multiplexing topology to share a single primary LNA with four independent input channels. So adopting this technique can save large area and large power consumption. However, the characteristic of time-multiplexing technique is not continuous of each channel and it will fold the output noise of LNA back to low frequency. So the noise folding problem will make signal quality degrade. This chip occupies 0.015 mm2 and consumes 4.25 μA per channel. The NEF is 11.56 due to the noise folding problem. It is implemented with TSMC 0.18 μm process. The second chip demonstrates a LNA that adopts an orthogonal frequency chopping (OFC) technique to realize a continuous 2-channel LNA with only one active amplifier. The OFC technique modulates two input signals to be orthogonal to each other before feeding into LNA. After two signals are amplified by LNA, the two signals can be demodulated back easily. Due to the OFC technique, the flicker noise will be modulated to high frequency. The signal quality of this chip is better than chip 1. This chip occupies 0.035 mm2 and consumes 13 μA per channel. The NEF is 3.74. It is implemented with TSMC 0.35 μm process. III The third chip implements a thoracic electrical bio-impedance(TEB) readout system. It uses square-wave current as injection current. The square-wave current can save large power and have good linearity rather traditional way. The proposed demodulated way can achieve high linearity and good accuracy. This chip occupies 0.5 mm2 and consumes 75 μA. The injection current range is from 10 μA to 50 μA. It is implemented with TSMC 0.18 μm process.