Abstract 1935: Tracking angiogenesis induced microvascular changes in a lymphoma model via a new high throughput non-invasive dual modality imaging platform

This study presents a novel dual-modality imaging system for assessing cancer progression in rodents. The system incorporates bioluminescence imaging (BLI), used to assess tumor growth, and contrast-enhanced ultrasound (CEUS), used to assess anatomical information and map microvasculature. The combination of the two modalities has previously been shown to reduce inter-user variability of BLI quantification, and in this work, we demonstrate that a dual BLI/US system can provide a more holistic assessment of disease. NSG (NOD/scid/gamma) female mice were implanted with luc-tagged lymphoma cells (BCBL-1, RRID: CVCL_0165, 1x105 cells, intraperitoneal (IP) injection, N = 8 mice) and imaged using the US and BLI hybrid modality system (SonoVol, Inc.), and a BLI-alone system (Perkin Elmer, Inc.) for comparison to a widely available commercial BLI system. BLI sensitivity was evaluated using a weakly luminescent tritium phantom to find the shortest exposure required to detect signal. In vivo studies consisted of an IP injection of D-luciferin (250 µL at 15 mg/mL) and serial captures of images with exposure times of 60 s every 3 min. Acoustic Angiography (AA), a high-resolution CEUS technique, was used to acquire 3D volumes in the abdomen surrounding the tumor site to assess angiogenesis-induced vascular remodeling associated with tumor growth. In vitro BLI sensitivity experiments showed that the dual-modality system required an exposure of 3 sec to detect signal (p This work demonstrates that non-invasive measurements of in vivo microvascular remodeling can be precisely mapped to changes in tumor growth with a hybrid modality system. The system has comparable sensitivity to a BLI-alone system and provides similar assessments of longitudinal tumor growth. Adding quantitative metrics for vascular remodeling to the widely used luminescent imaging could provide a more comprehensive assessment for tumor functional status than either modality could individually. This should prove valuable when using antiangiogenic therapies because changes in vasculature will precede cell death, and the ability to monitor both the cells and their blood supply might help to elucidate underlying biological processes. Citation Format: Juan D. Rojas, Rajalekha Rajamahendiran, Tomasz J. Czernuszewicz, Brian Velasco, Jonathan Perdomo, Max Harlacher, Graeme O9Connell, James Butler, Blossom Damania, Paul A. Dayton, Ryan C. Gessner. Tracking angiogenesis induced microvascular changes in a lymphoma model via a new high throughput non-invasive dual modality imaging platform [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2019; 2019 Mar 29-Apr 3; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2019;79(13 Suppl):Abstract nr 1935.