Perfluorinated substances (PFAS) are being used as additives in various products, such as cookware with a non-stick layer, waterproof material, food packaging and as firefighting foam due to their stability and resistance to grease, water and heat. During the use of these products, especially during their inadequate disposal in the environment, both soil and water pollution may occur. When they reach the environment, bioaccumulation of PFAS occurs, whereby they may not only have a negative effect on fluorine and fauna but also on human health. Therefore, they are often called "eternal chemicals". European regulations recognized this danger and established the maximum allowed concentration of PFAS compounds in drinking water of 0.5 μg/L, therefore it is important to remove them from wastewaters, which means to decompose them. Conventional wastewater treatment systems are not efficient enough for this purpose. On the other hand, advanced methods include membranes that are not effective for degradation but removal of PFAS. Unlike the latter, advanced oxidation processes are partially effective for the degradation of PFAS compounds using hydroxyl radicals. Nevertheless, utter gaol is to achieve defluorination of PFAS compounds, which can be achieved by reductive processes. The aim of this paper is to give a literature review of the existing reductive advanced methods (ARP) for the degradation of PFAS compounds. Thereat, ARP takes place with the help of photogenerated electrons, that is superoxide radicals. In the case of photocatalytic reductive decomposition of PFAS compounds, decomposition products of a simpler structure are formed, whereby the mechanisms of H/F substitution and shortening of the aliphatic chain, which implies breaking the C-F bond, are used. Electrochemical decomposition implies the decomposition of PFAS compounds to the appropriate degree of mineralization, but in doing so, the byproduct HF is formed and its emission must be controlled. The thermal reductive method implies the use of high reductive temperatures during the decomposition of PFAS compounds, where it is also necessary to pay attention to the emission of HF.