DIPG-08. PROBING THE BLOOD-BRAIN-TUMOR-BARRIER WITH A MICROVASCULAR MODEL OF DIFFUSE MIDLINE GLIOMA

Abstract

Abstract BACKGROUND Pediatric diffuse midline glioma (DMG) is a uniformly fatal brain tumor in children, with most patients surviving less than 12 months. Current treatment for DMG is limited, and outcomes for this tumor have not improved. The blood-brain-barrier (BBB) remains a key challenge for DMG therapeutics, preventing most drugs from entering brain tissue. Functional characterization of the blood-brain-tumor-barrier (BBTB) – the interaction between tumors and BBB vasculature – remains largely unexplored for DMG. There is a need for a preclinical model of DMG that can probe the functional, physiological, and biological properties of the BBTB in vitro as a platform to evaluate therapeutic efficacy that is representative of human physiology. METHODS To generate an in vitro model of DMG with human microvasculature (DMG-BBTB model), we co-cultured DMG neurospheres, human brain microvascular endothelial cells, human brain vascular pericytes, and human astrocytes. Cells are simultaneously seeded into microfluidic devices at varied concentrations within a fibrin matrix. Self-assembled microvascular networks are formed within 7-8 days and used for downstream functional and phenotypic assays. RESULTS Vascular morphology and solute permeability in microvascular networks are influenced by cell identity, growth pattern, and relative concentration. We show that DMG neurospheres exhibit different patterns of growth when co-cultured as uniform spheroids versus single cells in suspension. Devices representing each growth pattern are further characterized for paracellular diffusion and permeability compared to devices without DMG cells through perfusion of high molecular weight dextran. Permeability values are correlated to biologic features such as the abundance and localization of junctional proteins and transporters. CONCLUSIONS We developed a platform to evaluate the microvasculature of the DMG BBTB as a tool to develop new therapies informed by vascular biology. We probed the functional, physiological, and biological properties of the human DMG BBTB in vitro, and in ongoing work are assessing approved and experimental therapeutics.