Proportion aging is increasing rapidly in recent years. The worldwide population of people over the age of 65 has been predicted to become 761 million in this year 2025. Hence, the aging society will have a great demand of health-care system for elders, especially an integrated portable one. In this thesis, a preliminary design of high-integrated and low power consumption for processing multi signals such as electroencephalogram （EEG）signal, electrocardiogram （ECG）signal and diffuse optical tomography （DOT）is presented. The significance of this system is to enable the practical development of integrated portable health-care system for brain-heart monitoring. As the biomedical signals are weak, it is necessary to amply them for accurate monitoring. The weak biomedical signals are easily affected by external noise, so the circuit has to reduce the inference of noises. The different biomedical signals have different amplitudes and different bandwidths. Therefore, the circuit also has to deal with these problems. Finally, the biomedical signals are analog signals, but the signals are not only for monitoring but also for signals processing for the most urgent treatment conveniently. So, the analog-to-digital converter cannot be avoided. In other words, it is difficult to integrate these designs on a chip for portable health-care system. To solve this problem, Chopper Differential Difference Amplifier, Adjustable Gain Amplifier, Adjustable Bandwidth Low Pass Filter and Successive Approximation Registers Analog-to-Digital Converter are presented in this thesis. Finally, the results from this front-end circuit will convey to back-end for digital signal processing to achieve the multi-capability biomedical system monitoring chip. This multi-channel, high integrated and low power consumption has been implemented using TSMC 180 nm CMOS Mixed Signal RF General Purpose Standard Process.