Polychlorinated biphenyls (PCBs) are persistent organic pollutants and are emitted during e-waste activities. Once they enter into the environment, PCBs could pose toxic effects to environmental compartments and public health. Reductive dechlorination offers a sustainable solution to manage the PCBs-contaminated environment. Under anaerobic conditions, reductive dechlorination of PCBs occurs, and PCBs congeners serve as potential electron acceptors which stimulate the growth of PCBs-dechlorinating microorganisms. In this review, microbial and chemically induced reductive dechlorination was summarized. During anaerobic conditions, highly chlorinated PCBs undergo reductive dechlorination and are converted into less chlorinated PCBs. The mechanisms involved in reductive dechlorination are mainly attacks on meta and/or para chlorines of PCBs mixtures in a contaminated environment and ortho dechlorination of PCBs. Based on methods, PCBs removal efficiency was as chemical >
biological. Activated carbon (90%) showed more treatment efficiency than bacterial (84%). The review suggested that microbial remediation is a slow process
however, efficiency could be enhanced after amendments. Different microorganisms appear to be responsible for different dechlorination activities and the occurrence of various dehalogenation routes. However, PCBs dechlorination rate, extent, and route are influenced by pH, temperature, availability of carbon sources, and the presence or absence of H