Abstract When high pulsed electric fields (PEFs) are applied to the brain electroporation occurs. Depending on the electric fields strength, irreversible electroporation, inducing necrotic cell death or reversible electroporation, inducing BBB disruption may occur. We have developed a unique minimally-invasive setup for treating brain tumors employing a single insulated intracranial electrode with an exposed tip placed within the tumor and an external surface electrode. This unique setup, termed point-source electroporation, provides intratumoral irreversible-electroporation (inducing necrosis) with surrounding reversible BBB disruption, enabling efficient delivery of systemically administered drugs into the infiltrating zone. Treatment duration is 1–2 min. An efficacy study conducted with 120 glioma-bearing rats resulted in suppressed tumor growth rates in the electroporation+Cisplatin group (1.1±0.1) relative to growth rates in the control group (5.2±1.0), p< 0.047, and in the Cisplatin-only group p< 0.012 (3.92±1.0) (Welch’s F(2,12.73)=10.84; p< 0.002; ω2=0.28). Kaplan-Meir analysis revealed that electroporation+Cisplatin prolonged survival significantly (χ2=7.54; p< 0.006). Immunofluorescence analysis revealed significant infiltration of peripheral macrophages and CD8+ cells in the residual tumor. A finite elements simulation demonstrated the feasibility for obtaining clinically-relevant treatment volumes (~6cm diameter) using a single 3mm (diameter) intracranial catheter. Additionally, we discovered that low PEFs, an order of magnitude lower than electroporation threshold, can also transiently disrupt the BBB by a different mechanism, enabling penetration of both small (Gd/NaF) and large (Evans blue bound to serum albumin) molecules and immune cells, non-invasively. The extent of BBB disruption, measured in mice using delayed-contrast MRI, was found to be linearly dependent both on the electric field strength (r2=0.9,p< 0.03) and on the number of applied pulses (r2=0.94,p< 0.003). These results demonstrate the feasibly of applying combined systemic chemotherapy with point-source electroporation, a minimal-invasive/rapid treatment of PEFs, for obtaining significant antineoplastic effects. Furthermore, low PEFs may be applied non-invasively, rapidly and repeatedly for obtaining reversible BBB disruption.