Abstract
Mechanistic modeling of signaling pathways mediating patient‐specific response to therapy can help to unveil resistance mechanisms and improve therapeutic strategies. Yet, creating such models for patients, in particular for solid malignancies, is challenging. A major hurdle to build these models is the limited material available that precludes the generation of large‐scale perturbation data. Here, we present an approach that couples ex vivo high‐throughput screenings of cancer biopsies using microfluidics with logic‐based modeling to generate patient‐specific dynamic models of extrinsic and intrinsic apoptosis signaling pathways. We used the resulting models to investigate heterogeneity in pancreatic cancer patients, showing dissimilarities especially in the PI3K‐Akt pathway. Variation in model parameters reflected well the different tumor stages. Finally, we used our dynamic models to efficaciously predict new personalized combinatorial treatments. Our results suggest that our combination of microfluidic experiments and mathematical model can be a novel tool toward cancer precision medicine.
Highlights
Mechanistic modeling of signaling pathways mediating patientspecific response to therapy can help to unveil resistance mechanisms and improve therapeutic strategies
Data represent caspase3 (Cas3 in Fig 1B, marked in blue) activation after perturbation with 10 different compounds including seven kinase inhibitors, one cytokine (TNF, stimulated node, in green), and two chemotherapeutic drugs
To investigate the signaling mechanisms behind the differential drug responses of our cell lines and patients, we derived a general logic model of apoptosis pathways involved in the regulation of Cas3, which is considered as effector node and indicator of apoptosis
Summary
Mechanistic modeling of signaling pathways mediating patientspecific response to therapy can help to unveil resistance mechanisms and improve therapeutic strategies. Creating such models for patients, in particular for solid malignancies, is challenging. We present an approach that couples ex vivo high-throughput screenings of cancer biopsies using microfluidics with logic-based modeling to generate patientspecific dynamic models of extrinsic and intrinsic apoptosis signaling pathways. We used the resulting models to investigate heterogeneity in pancreatic cancer patients, showing dissimilarities especially in the PI3K-Akt pathway. Our results suggest that our combination of microfluidic experiments and mathematical model can be a novel tool toward cancer precision medicine
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