Abstract: Personalized whole-body circulation calculation is provided. In one embodiment, a combination of models at different scales and machine learning may be used to personalize and calculate the circulation for a particular patient. In another embodiment, imaging, ECG, and pressure data are used to personalize a multi-scale whole body circulation model. Different parameters, such as (but not limited to) time-varying flow rate for the heart, pressure variation for the heart, cardiovascular systemic impedance, and cardiovascular pulmonary impedance, are determined for the patient and used to personalize the model. The model is then used to determine, visualize, or report a diagnostically or therapeutically useful circulation metric for that patient.

Abstract: A method and system for estimating tissue parameters of a computational model of organ function and their uncertainty due to model assumptions, data noise and optimization limitations is disclosed. As applied to a cardiac use-case, a patient-specific anatomical heart model is generated from medical image data of a patient. A patient-specific computational heart model is generated based on the patient-specific anatomical heart model. Patient-specific parameters and corresponding uncertainty values are estimated for at least a subset of parameters of the patient-specific computational heart model. A surrogate model is estimated for a forward model of cardiac function, and the surrogate model is applied within Bayesian inference to estimate the posterior probability density function of the parameter space of the forward model. Cardiac function for the patient is simulated using the patient-specific computational heart model.