A flexible framework for sequential estimation of model parameters in computational hemodynamics

Christopher J. Arthurs; Nan Xiao; Philippe Moireau; Tobias Schaeffter; C. Alberto Figueroa

doi:10.1186/s40323-020-00186-x

A flexible framework for sequential estimation of model parameters in computational hemodynamics

Christopher J. Arthurs
, Nan Xiao
, Philippe Moireau
, Tobias Schaeffter
, C. Alberto Figueroa

Research output: Contribution to journal › Article › peer-review

Abstract

A major challenge in constructing three dimensional patient specific hemodynamic models is the calibration of model parameters to match patient data on flow, pressure, wall motion, etc. acquired in the clinic. Current workflows are manual and time-consuming. This work presents a flexible computational framework for model parameter estimation in cardiovascular flows that relies on the following fundamental contributions. (i) A Reduced-Order Unscented Kalman Filter (ROUKF) model for data assimilation for wall material and simple lumped parameter network (LPN) boundary condition model parameters. (ii) A constrained least squares augmentation (ROUKF-CLS) for more complex LPNs. (iii) A “Netlist” implementation, supporting easy filtering of parameters in such complex LPNs. The ROUKF algorithm is demonstrated using non-invasive patient-specific data on anatomy, flow and pressure from a healthy volunteer. The ROUKF-CLS algorithm is demonstrated using synthetic data on a coronary LPN. The methods described in this paper have been implemented as part of the CRIMSON hemodynamics software package.

Original language	English
Article number	48
Journal	Advanced Modeling and Simulation in Engineering Sciences
Volume	7
Issue number	1
DOIs	https://doi.org/10.1186/s40323-020-00186-x
Publication status	Published - 1 Dec 2020
Externally published	Yes

Keywords

Boundary conditions
Computational hemodynamics
Data assimilation
Kalman filtering
Parameter estimation
Patient specific modeling
Stiffness

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10.1186/s40323-020-00186-x

Cite this

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title = "A flexible framework for sequential estimation of model parameters in computational hemodynamics",

abstract = "A major challenge in constructing three dimensional patient specific hemodynamic models is the calibration of model parameters to match patient data on flow, pressure, wall motion, etc. acquired in the clinic. Current workflows are manual and time-consuming. This work presents a flexible computational framework for model parameter estimation in cardiovascular flows that relies on the following fundamental contributions. (i) A Reduced-Order Unscented Kalman Filter (ROUKF) model for data assimilation for wall material and simple lumped parameter network (LPN) boundary condition model parameters. (ii) A constrained least squares augmentation (ROUKF-CLS) for more complex LPNs. (iii) A “Netlist” implementation, supporting easy filtering of parameters in such complex LPNs. The ROUKF algorithm is demonstrated using non-invasive patient-specific data on anatomy, flow and pressure from a healthy volunteer. The ROUKF-CLS algorithm is demonstrated using synthetic data on a coronary LPN. The methods described in this paper have been implemented as part of the CRIMSON hemodynamics software package.",

keywords = "Boundary conditions, Computational hemodynamics, Data assimilation, Kalman filtering, Parameter estimation, Patient specific modeling, Stiffness",

author = "Arthurs, \{Christopher J.\} and Nan Xiao and Philippe Moireau and Tobias Schaeffter and Figueroa, \{C. Alberto\}",

note = "Publisher Copyright: {\textcopyright} 2020, The Author(s).",

year = "2020",

month = dec,

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doi = "10.1186/s40323-020-00186-x",

language = "English",

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AU - Arthurs, Christopher J.

AU - Xiao, Nan

AU - Moireau, Philippe

AU - Schaeffter, Tobias

AU - Figueroa, C. Alberto

PY - 2020/12/1

Y1 - 2020/12/1

N2 - A major challenge in constructing three dimensional patient specific hemodynamic models is the calibration of model parameters to match patient data on flow, pressure, wall motion, etc. acquired in the clinic. Current workflows are manual and time-consuming. This work presents a flexible computational framework for model parameter estimation in cardiovascular flows that relies on the following fundamental contributions. (i) A Reduced-Order Unscented Kalman Filter (ROUKF) model for data assimilation for wall material and simple lumped parameter network (LPN) boundary condition model parameters. (ii) A constrained least squares augmentation (ROUKF-CLS) for more complex LPNs. (iii) A “Netlist” implementation, supporting easy filtering of parameters in such complex LPNs. The ROUKF algorithm is demonstrated using non-invasive patient-specific data on anatomy, flow and pressure from a healthy volunteer. The ROUKF-CLS algorithm is demonstrated using synthetic data on a coronary LPN. The methods described in this paper have been implemented as part of the CRIMSON hemodynamics software package.

AB - A major challenge in constructing three dimensional patient specific hemodynamic models is the calibration of model parameters to match patient data on flow, pressure, wall motion, etc. acquired in the clinic. Current workflows are manual and time-consuming. This work presents a flexible computational framework for model parameter estimation in cardiovascular flows that relies on the following fundamental contributions. (i) A Reduced-Order Unscented Kalman Filter (ROUKF) model for data assimilation for wall material and simple lumped parameter network (LPN) boundary condition model parameters. (ii) A constrained least squares augmentation (ROUKF-CLS) for more complex LPNs. (iii) A “Netlist” implementation, supporting easy filtering of parameters in such complex LPNs. The ROUKF algorithm is demonstrated using non-invasive patient-specific data on anatomy, flow and pressure from a healthy volunteer. The ROUKF-CLS algorithm is demonstrated using synthetic data on a coronary LPN. The methods described in this paper have been implemented as part of the CRIMSON hemodynamics software package.

KW - Boundary conditions

KW - Computational hemodynamics

KW - Data assimilation

KW - Kalman filtering

KW - Parameter estimation

KW - Patient specific modeling

KW - Stiffness

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DO - 10.1186/s40323-020-00186-x

M3 - Article

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SN - 2213-7467

VL - 7

JO - Advanced Modeling and Simulation in Engineering Sciences

JF - Advanced Modeling and Simulation in Engineering Sciences

IS - 1

M1 - 48

ER -

A flexible framework for sequential estimation of model parameters in computational hemodynamics

Abstract

Keywords

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