Related papers: Joint data imputation and mechanistic modelling for simulating heart-brain interactions in incomplete datasets

Joint data imputation and mechanistic modelling for simulating heart-brain interactions in incomplete datasets

URL: http://arxiv.org/abs/2010.01052v3
Date: Thu, 8 Oct 2020 12:36:31 GMT
Title: Joint data imputation and mechanistic modelling for simulating heart-brain interactions in incomplete datasets
Authors: Jaume Banus and Maxime Sermesant and Oscar Camara and Marco Lorenzi
Abstract summary: We introduce a probabilistic framework for joint cardiac data imputation and personalisation of cardiovascular mechanistic models. Our approach is based on a variational framework for the joint inference of an imputation model of cardiac information from the available features. We show that our model allows accurate imputation of missing cardiac features in datasets containing minimal heart information.
Score: 5.178090215294132
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: The use of mechanistic models in clinical studies is limited by the lack of multi-modal patients data representing different anatomical and physiological processes. For example, neuroimaging datasets do not provide a sufficient representation of heart features for the modeling of cardiovascular factors in brain disorders. To tackle this problem we introduce a probabilistic framework for joint cardiac data imputation and personalisation of cardiovascular mechanistic models, with application to brain studies with incomplete heart data. Our approach is based on a variational framework for the joint inference of an imputation model of cardiac information from the available features, along with a Gaussian Process emulator that can faithfully reproduce personalised cardiovascular dynamics. Experimental results on UK Biobank show that our model allows accurate imputation of missing cardiac features in datasets containing minimal heart information, e.g. systolic and diastolic blood pressures only, while jointly estimating the emulated parameters of the lumped model. This allows a novel exploration of the heart-brain joint relationship through simulation of realistic cardiac dynamics corresponding to different conditions of brain anatomy.

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