# Machine learning in cardiovascular flows modeling: Predicting arterial   blood pressure from non-invasive 4D flow MRI data using physics-informed   neural networks

**Authors:** Georgios Kissas, Yibo Yang, Eileen Hwuang, Walter R. Witschey, John A., Detre, Paris Perdikaris

arXiv: 1905.04817 · 2019-09-19

## TL;DR

This paper introduces a physics-informed neural network framework that predicts arterial blood pressure from non-invasive 4D flow MRI data, reducing computational costs and improving clinical applicability in cardiovascular modeling.

## Contribution

It presents a novel machine learning approach that integrates physical principles with neural networks to predict cardiovascular flow and pressure from clinical data without traditional simulation methods.

## Key findings

- Neural networks produce physically consistent flow and pressure predictions.
- The method effectively estimates Windkessel model parameters from clinical data.
- Demonstrated success on both benchmarks and real clinical case.

## Abstract

Advances in computational science offer a principled pipeline for predictive modeling of cardiovascular flows and aspire to provide a valuable tool for monitoring, diagnostics and surgical planning. Such models can be nowadays deployed on large patient-specific topologies of systemic arterial networks and return detailed predictions on flow patterns, wall shear stresses, and pulse wave propagation. However, their success heavily relies on tedious pre-processing and calibration procedures that typically induce a significant computational cost, thus hampering their clinical applicability. In this work we put forth a machine learning framework that enables the seamless synthesis of non-invasive in-vivo measurement techniques and computational flow dynamics models derived from first physical principles. We illustrate this new paradigm by showing how one-dimensional models of pulsatile flow can be used to constrain the output of deep neural networks such that their predictions satisfy the conservation of mass and momentum principles. Once trained on noisy and scattered clinical data of flow and wall displacement, these networks can return physically consistent predictions for velocity, pressure and wall displacement pulse wave propagation, all without the need to employ conventional simulators. A simple post-processing of these outputs can also provide a cheap and effective way for estimating Windkessel model parameters that are required for the calibration of traditional computational models. The effectiveness of the proposed techniques is demonstrated through a series of prototype benchmarks, as well as a realistic clinical case involving in-vivo measurements near the aorta/carotid bifurcation of a healthy human subject.

## Full text

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## Figures

13 figures with captions in the complete paper: https://tomesphere.com/paper/1905.04817/full.md

## References

69 references — full list in the complete paper: https://tomesphere.com/paper/1905.04817/full.md

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Source: https://tomesphere.com/paper/1905.04817