In portable and implementable biomedical systems, there are two more important design issues in the biomedical chip than other applications, which are very low power consumption and low power supply voltage. Besides, the low power design has to effectively shrink down the chip area and battery volume to satisfy portable and long battery lifetime requirements of biomedical instruments. The high resolution and low power analog-to-digital converter (ADC) is a key component in biomedical systems. By taking the advantage of oversampling technique, the sigma-delta (SD) modulation can relax the design complexity of the analog front end anti-aliasing filter. However, the SD ADC needs the digital decimation filter at the SD modulator output to remove the high frequency noise and down-sampling data. This study proposes a low power and minimized circuit area digital decimation filter design in the SD ADC. Poly-phase decomposition, canonical signed digit (CSD) and common sub-expression sharing (CSE) approaches are applied in the design to achieve low power target. Furthermore, the “search method to minimize filter area” is also proposed to find out the filter coefficients with minimized circuit area and suitable performance. The proposed design is first realized on Altera FPGA emulation board. The performance can achieve 73dB signal-to-noise and distortion ratio (SNDR) and 12bits resolution. Our design is also accomplished in TSMC 0.13um CMOS process with 305uW power consumption and 0.40mm2 chip area to demonstrate the proposed digital decimation filter design in the SD ADC.