(143b) Computationally Derived Points Of Fragility Of A Human Cascade Are Consistent With Current Therapeutic Strategies
AIChE Annual Meeting
2007
2007 Annual Meeting
Computing and Systems Technology Division
Recent Developments in Systems and Process Control Poster Session
Monday, November 5, 2007 - 4:30pm to 6:30pm
The role that mechanistic mathematical modeling and systems biology will play in molecular medicine and clinical development remains uncertain. In this study, mathematical modeling and sensitivity analysis was used to explore the working hypothesis that mechanistic models of human cascades, despite model uncertainty, can be computationally screened for points of fragility, and that these sensitive mechanisms could serve as therapeutic targets. We tested our working hypothesis by screening a model of the well-studied coagulation cascade, developed and validated from literature. The predicted sensitive mechanisms were then compared with the treatment literature. The model, composed of 92 proteins and 148 protein-protein interactions, was validated using 21 published data sets generated from two different quiescent in-vitro coagulation models. Simulated platelet activation and thrombin generation profiles in the presence and absence of natural anticoagulants were consistent with measured values with a mean correlation of 0.87 across all trials. Overall State Sensitivity Coefficients (OSSC), which measure the robustness or fragility of a given mechanism, were calculated using a monte-carlo strategy. In the absence of anticoagulants, fluid and surface phase fX/FXa activity and thrombin mediated platelet activation were found to be fragile while fIX/FIXa and fVIII/FVIIIa activation and activity were robust. Both anti-fX/FXa and Direct Thrombin Inhibitors (DTIs) are important classes of anticoagulants, for example, anti-fX/FXa inhibitors have Food and Drug Administration (FDA) approval for the prevention of venous thromboembolism following surgical intervention and as an initial treatment for Deep Venous Thrombosis (DVT) and Pulmonary Embolism (PE). Both in-vitro and in-vivo experimental evidence is reviewed supporting the prediction that fIX/FIXa activity is robust. When taken together, these results support our working hypothesis that computationally derived points of fragility of human relevant cascades could be used as a rational basis for target selection despite model uncertainty.