Poly-lactic acid (PLA) is known as a promising material to take the place of traditional petroleum products due to its biodegradability and similar properties to the petroleum-based plastics. Therefore, the treatment of the used PLA products cannot be overemphasized owing to its growing demand of the market. The aim of this study is to utilize PLA products to anaerobically co-digest with the digestate of swine manure. First of all, we found out the optimal pretreatment time of PLA by performing the experiment of mass loss ratio and chemical oxygen demand. By the results, we concluded that 24 hours of pretreatment of PLA was optimal. Biochemical methane potential (BMP) test was performed to optimize the most appropriate mixing ratio of the PLA and the anaerobic digestate as well as to find out the best pretreatment method (acid or alkaline) of PLA. The results showed that at mesophilic temperature (37°C), the optimal mixing ratio of the PLA and the digestate was 3.0, with a yield of 10.4 (mL CH4/g volatile solids added) for a duration of 20 days BMP test. Moreover, under the identical operational conditions, alkaline pretreatment demonstrated better performance. It was found that heating PLA with 0.5 M NaOH for 24 hours would produce 139.4 (mL CH4/g volatile solids added). The results of the BMP test showed that the pretreated PLA can serve as an appropriate carbon source for the anaerobic digestate of swine manure. A continuous operation experiment was followed up at mesophilic and thermophilic conditions. At low hydraulic retention time (10 days) and high concentration (TS=8%) operation conditions, we discovered that PLA pretreated with 0.5M NaOH performed better from gas production and removal efficiency aspects. At mesophilic temperature, the methane production rate of NaOH pretreated PLA co-digestion with the digestate is 1.17 L/L/d, which is 25% more than the co digestion of the untreated PLA and the digestate; and the methane production rate of HCl pretreated PLA co-digestion with the digestate is 1.08 L/L/d, which is 15% more than the co digestion of the untreated PLA and the digestate Moreover, at thermophilic operation, the methane production rate of NaOH pretreated PLA co-digestion with the digestate is 1.38, which is 41% more than the co digestion of the untreated PLA and the digestate; and the methane production rate of HCl pretreated PLA co-digestion with the digestate is 1.18 L/L/d, which is 20% more than the co digestion of the untreated PLA. Operation temperature plays an important role for NaOH pretreated PLA. The rise of the gas production and removal efficiency showed the hydrolysis properties of PLA in alkaline environment.