Recently, a combined method of chemical oxidation treatment and biological degradation treatment to deplete the pentachlorophenol (PCP) and hexachlorobenzene (HCB) pollutants was discussed. In this study, the degradations of PCP and HCB were made by microbial dechlorination coupling with chemical oxidation procedures. The results suggested that the highly chlorinated aromatics were more resisted to Fenton oxidation than less chlorinated ones. On the other hand, highly chlorinated aromatics were strongly dechlorinated by acclimated microorganisms but less chlorinated ones were not. In the oxidation experiment of the dechlorination products of HCB and PCP, 135-trichlorobenzene (135-TCB), 13-dichlorobenzene (13-DCB), 14-DCB, 345-trichlorophenol (345-TCP), and 35-dichlorophenol (35-DCP) were treated by Fenton system with decomposition ratios of 72%, 88%, 86%, 69% and 85%, respectively. However, when HCB and PCP were first dechlorinated by acclimated anaerobic microorganisms for removal of chlorines and then introduced directly to a Fenton system for following oxidation and ring cleavage. The organic matters in the dechlorination solutions had reduced the extent of oxidation. In this study, we also evaluated how the organic contents affected the efficiency of Fenton system.