A novel MRI-based tumor-targeting theragnostic agent: Magnetoelectric nanoparticles in an in vivo murine KRAS/P53 pancreatic flank tumor model.

Abstract

3075 Background: Magnetoelectric nanoparticles (MENPs) are a novel material with a magnetoelectric (ME) property that allows for conversion of an external magnetic field to a local electric field (EF) that can be exploited to generate a Coulomb force to target and electroporate the relatively non-polarized tumor cell walls. We hypothesized that their local EF and superparamagnetic cores can be exploited as an MRI-based anti-cancer theragnostic agent for solid tumors. Methods: 35 immunocompetent C57BL/6 mice were inoculated with KPC961 pancreatic adenocarcinoma cells in their flank. The 27 mice with the largest tumors at 4 weeks were randomized into 5 cohorts based on treatment: 300 µg of MENP (300; n=6), 600 µg of MENP (600; n=6), 300 µg of low-ME coefficient MENP (LM; n=5), 300 µg of MENP without M1 MRI (NM; MRI field control, n=5), and normal saline (NS; MENP causal effect control; n=5). The 300, 600, LM, and NS cohorts had T2 MRI maps (M0) on a 7T MRI. NM had T2 weighted MRIs at M0. All mice had a neodymium magnet placed over their tumors for 12 hours after tail vein injections (300 µl for all mice) for targeting. The 300, 600, LM, and NS cohorts then underwent MRI mapping (M1) after magnet removal (No M1 MRI for NM). MRI mapping was repeated 5 days after (M2). NM had a T2 weighted MRIs at M2. M1 and M2 data were used to assess relaxation time (contrast effect) and tumor volume from M0, respectively. Student t and ANOVA tests were used to compare differences for tumor volume and relaxation time data and one-sided Fisher’s exact test was used for complete response (CR) data. Results: The median M0 tumor volume was 109.6 mm3 for all mice, and there were no differences between any cohort ( p = 0.978; Table). The 300 and 600 MENP cohorts demonstrated a 102.7% reduction in volume (M2/M0; 56.7% vs. 159.4% for NS and NM controls, p = <0.001) and a 7.2% T2 negative contrast effect (M1/M0; 94.2% vs. 101.3% for NS, p = 0.046) compared to controls. Six mice in 300, 600, and LM (2 each) achieved a clinical CR (between 1 to 2 weeks after M1) vs. none in the NS and NM control cohorts ( p = 0.0418), without any recurrences until end of study (6 weeks after M2). Conclusions: This is the first report demonstrating the theragnostic effects of MENPs having both T2 contrast and locally ablative therapy properties as an in vivo tumor targeting agent. These results confirm prior pilot study and point towards irreversible electroporation as the likely mechanism of action (MOA) since the antitumor effect is not seen within the NM cohort. Additional studies characterizing the MOA, dose-response relationships, and immunomodulatory effects are needed to better understand their full clinical potential.[Table: see text]