Abstract Background: Locoregional therapy is playing an increasingly central role in the management of hepatocellular carcinoma (HCC), where ablation is distinguished among these techniques by its capacity to effect cure. Electrochemical treatment (EChT), a technique that facilitates necrosis via the application of direct current at low voltages shows promise; however, widespread use has been limited as studies of the underlying biology and the mechanism of action have been limited. Methods: A novel assay for the study of EChT mechanism was designed, wherein HCC cells (2.5e5 cells/mL) were embedded in low-melting temperature agarose (1.5%). EChT was performed on these assays between nitinol cathodes (d = 0.5 mm) and platinum anodes (d = 0.5 mm) in a variety of geometries. Buffering capacity of the encapsulation assay was varied via the addition of HEPES buffer at final concentrations of 10mM, 50mM, or 200mM. Either during or immediately following EChT, the following measurements were recorded: cell viability, pH, ROS burden, transmembrane potential, and temperature. Results: Following EChT, acidic pH was appreciated surrounding the anodes and basic pH surrounding the cathodes in regions where cell death was observed by fluorescence microscopy. Upon increasing the buffering capacity of the assay, the total area of cell death decreased (p < 10-6). There was not sufficient heat generation nor transmembrane potential to account for the observed cell death. A pH-threshold was identified, where a pH > 10.8 or < 4.4 was found to cause cell necrosis in the three different buffer conditions studied. By varying the number of electrodes, their spacing, and length of ablation, it was possible to shape the zone of cell death observed to an arbitrary geometry. Conclusions: The mechanism of EChT-induced cancer cell death is through the spread of acidic and basic species generated by hydrolysis of water upon electron transfer at the electrodes. The diffusion of these species leads to cell death in a predictable, pH dependent manner. These results suggest that an electrochemical ablation device could treat complex HCC tumor geometries with appropriate electrode placement and charge delivery. Citation Format: Nicholas Perkons, Elliot Stein, Chike Nwaezeapu, Joseph Wildenberg, Daniel Ackerman, Gregory Nadolski, Stephen Hunt, Terence Gade. Electrochemical treatment produces pH changes in the tumor microenvironment that are toxic to cancer cells [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 195.