Non-invasive PD-L1 quantification using [18F]DK222-PET imaging in cancer immunotherapy

Background Combination therapies that aim to improve the clinical efficacy to immune checkpoint inhibitors have led to the need for non-invasive and early pharmacodynamic biomarkers. Positron emission tomography (PET) is a promising non-invasive approach to monitoring target dynamics, and programmed death-ligand 1 (PD-L1) expression is a central component in cancer immunotherapy strategies. [F-18]DK222, a peptide-based PD-L1 imaging agent, was investigated in this study using humanized mouse models to explore the relationship between PD-L1 expression and therapy-induced changes in cancer.Methods Cell lines and xenografts derived from three non-small cell lung cancers (NSCLCs) and three urothelial carcinomas (UCs) were used to validate the specificity of [F-18]DK222 for PD-L1. PET was used to quantify anti-programmed cell death protein-1 (PD-1) therapy-induced changes in PD-L1 expression in tumors with and without microsatellite instability (MSI) in humanized mice. Furthermore, [F-18]DK222-PET was used to validate PD-L1 pharmacodynamics in the context of monotherapy and combination immunotherapy in humanized mice bearing A375 melanoma xenografts. PET measures of PD-L1 expression were used to establish a relationship between pathological and immunological changes. Lastly, spatial distribution analysis of [F-18]DK222-PET was developed to assess the effects of different immunotherapy regimens on tumor heterogeneity.Results [F-18]DK222-PET and biodistribution studies in mice with NSCLC and UC xenografts revealed high but variable tumor uptake at 60 min that correlated with PD-L1 expression. In MSI tumors treated with anti-PD-1, [F-18]DK222 uptake was higher than in control tumors. Moreover, [F-18]DK222 uptake was higher in A375 tumors treated with combination therapy compared with monotherapy, and negatively correlated with final tumor volumes. In addition, a higher number of PD-L1+ cells and higher CD8(+)-to-CD4(+) cell ratio was observed with combination therapy compared with monotherapy, and positively correlated with PET. Furthermore, spatial distribution analysis showed higher [F-18]DK222 uptake towards the core of the tumors in combination therapy, indicating a more robust and distinct pattern of immune cell infiltration.Conclusion [F-18]DK222-PET has potential as a non-invasive tool for monitoring the effects of immunotherapy on tumors. It was able to detect variable PD-L1 expression in tumors of different cancer types and quantify therapy-induced changes in tumors. Moreover, [F-18]DK222-PET was able to differentiate the impact of different therapies on tumors.

Automated summary

This study investigated the relationship between PD-L1 expression and therapy-induced changes in cancer using a peptide-based PD-L1 imaging agent, [F-18]DK222, in humanized mouse models. The results showed that [F-18]DK222-PET has potential as a non-invasive tool for monitoring the effects of immunotherapy on tumors, detecting variable PD-L1 expression, quantifying therapy-induced changes, and differentiating the impact of different therapies on tumors.