A rapid, sensitive, and reproducible in vivo PBMC humanized murine model for determining therapeutic-related cytokine release syndrome
A study developed PBMC-engrafted NSG mouse models to assess CRS in vivo, demonstrating that these models are rapid, sensitive, and reproducible platforms for screening novel therapeutics for CRS.
Immunotherapy is a powerful treatment strategy being applied to cancer, autoim-mune diseases, allergies, and transplantation. Although therapeutic monoclonal antibodies (mAbs) have demonstrated significant clinical efficacy, there is also the potential for severe adverse events, including cytokine release syndrome (CRS). CRS is characterized by the rapid production of inflammatory cytokines following delivery of therapy, with symptoms ranging from mild fever to life-threating pathol-ogy and multi-organ failure. Overall there is a paucity of models to reliably and ac-curately predict the induction of CRS by immune therapeutics. Here, we describe the development of a humanized mouse model based on the NOD-scid IL2rgnull (NSG) mouse to study CRS in vivo. PBMC-engrafted NSG, NSG-MHC-DKO, and NSG-SGM3 mice were used to study cytokine release in response to treatment with mAb immunotherapies. Our data show that therapeutic-stimulated cytokine release in these PBMC-based NSG models captures the variation in cytokine release between individual donors, is drug dependent, occurs in the absence of acute xeno-GVHD, highlighting the specificity of the assay, and shows a robust response following treat-ment with a TGN1412 analog, a CD28 superagonist. Overall our results demonstrate that PBMC-engrafted NSG models are rapid, sensitive, and reproducible platforms to screen novel therapeutics for CRS.