Mathematical model suggests current CAR-macrophage dosage is efficient to low pre-infusion tumour burden but refractory to high tumour burden

Chimeric antigen receptor (CAR)-macrophage therapy is a promising approach for tumour treatment due to antigen-specific phagocytosis and tumour clearance. However, the precise impact of tumour burden, CAR-macrophage dose and dosing regimens on therapy prognosis is far from clear. We utilized ordinary differential equation (ODE) mathematical modelling and parameter inference to analyse in vitro FACS-based phagocytosis assay data testing CD19-positive Raji tumour cell against CAR-macrophage, and found that phagocytosing efficiency of CAR-macrophage increases but saturates with both Raji cell and CAR-macrophage concentrations increases. This interaction between CAR-macrophages and Raji cells leads to bistable Raji cell kinetics; specifically, within a particular range of CAR-macrophage concentration, low tumour burdens are effectively inhibited, while high tumour burdens remain refractory. Furthermore, our model indicates that CAR-macrophage dosages typically suggested by current clinical trials yield favourable therapy outcomes only when pre-infusion tumour burden is low. For split CAR-macrophage infusion with fixed total dosage, the first infusion with high CAR-macrophage dose delivers superior treatment outcomes. Finally, we identified alternative infusion regimens: five billion cells administered monthly for three months, or seven billion cells every two months for six months, can efficiently suppress Raji cell kinetics irrespective of tumour burden. Our findings highlight that variations in CAR-macrophage therapy outcomes are strongly influenced by large tumour burden and different dosing regimens. This work underscores that reducing tumour burden, increasing CAR-macrophage dose in the first infusion and prolonging CAR-macrophage persistence are key strategies for achieving durable responses.