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342 results on '"Rausch, Manuel K."'

1. A universal material model subroutine for soft matter systems

Author

Peirlinck, Mathias, Hurtado, Juan A., Rausch, Manuel K., Tepole, Adrian Buganza, and Kuhl, Ellen

Subjects
Computer Science - Computational Engineering, Finance, and Science, Condensed Matter - Materials Science, Condensed Matter - Soft Condensed Matter
Abstract

Soft materials play an integral part in many aspects of modern life including autonomy, sustainability, and human health, and their accurate modeling is critical to understand their unique properties and functions. Today's finite element analysis packages come with a set of pre-programmed material models, which may exhibit restricted validity in capturing the intricate mechanical behavior of these materials. Regrettably, incorporating a modified or novel material model in a finite element analysis package requires non-trivial in-depth knowledge of tensor algebra, continuum mechanics, and computer programming, making it a complex task that is prone to human error. Here we design a universal material subroutine, which automates the integration of novel constitutive models of varying complexity in non-linear finite element packages, with no additional analytical derivations and algorithmic implementations. We demonstrate the versatility of our approach to seamlessly integrate innovative constituent models from the material point to the structural level through a variety of soft matter case studies: a frontal impact to the brain; reconstructive surgery of the scalp; diastolic loading of arteries and the human heart; and the dynamic closing of the tricuspid valve. Our universal material subroutine empowers all users, not solely experts, to conduct reliable engineering analysis of soft matter systems. We envision that this framework will become an indispensable instrument for continued innovation and discovery within the soft matter community at large.

Published
2024
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2. Generative Hyperelasticity with Physics-Informed Probabilistic Diffusion Fields

Author

Tac, Vahidullah, Rausch, Manuel K, Bilionis, Ilias, Costabal, Francisco Sahli, and Tepole, Adrian Buganza

Subjects
Computer Science - Computational Engineering, Finance, and Science, Computer Science - Machine Learning
Abstract

Many natural materials exhibit highly complex, nonlinear, anisotropic, and heterogeneous mechanical properties. Recently, it has been demonstrated that data-driven strain energy functions possess the flexibility to capture the behavior of these complex materials with high accuracy while satisfying physics-based constraints. However, most of these approaches disregard the uncertainty in the estimates and the spatial heterogeneity of these materials. In this work, we leverage recent advances in generative models to address these issues. We use as building block neural ordinary equations (NODE) that -- by construction -- create polyconvex strain energy functions, a key property of realistic hyperelastic material models. We combine this approach with probabilistic diffusion models to generate new samples of strain energy functions. This technique allows us to sample a vector of Gaussian white noise and translate it to NODE parameters thereby representing plausible strain energy functions. We extend our approach to spatially correlated diffusion resulting in heterogeneous material properties for arbitrary geometries. We extensively test our method with synthetic and experimental data on biological tissues and run finite element simulations with various degrees of spatial heterogeneity. We believe this approach is a major step forward including uncertainty in predictive, data-driven models of hyperelasticity, Comment: 22 pages, 11 figures

Published
2023

7. Data-driven anisotropic finite viscoelasticity using neural ordinary differential equations

Author

Tac, Vahidullah, Rausch, Manuel K., Sahli-Costabal, Francisco, and Tepole, Adrian B.

Subjects
Condensed Matter - Soft Condensed Matter, Computer Science - Machine Learning
Abstract

We develop a fully data-driven model of anisotropic finite viscoelasticity using neural ordinary differential equations as building blocks. We replace the Helmholtz free energy function and the dissipation potential with data-driven functions that a priori satisfy physics-based constraints such as objectivity and the second law of thermodynamics. Our approach enables modeling viscoelastic behavior of materials under arbitrary loads in three-dimensions even with large deformations and large deviations from the thermodynamic equilibrium. The data-driven nature of the governing potentials endows the model with much needed flexibility in modeling the viscoelastic behavior of a wide class of materials. We train the model using stress-strain data from biological and synthetic materials including humain brain tissue, blood clots, natural rubber and human myocardium and show that the data-driven method outperforms traditional, closed-form models of viscoelasticity.

Published
2023
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8. A Brief Note on Building Augmented Reality Models for Scientific Visualization

Author

Mathur, Mrudang, Brozovich, Josef M., and Rausch, Manuel K.

Subjects
Computer Science - Graphics, Computer Science - Human-Computer Interaction
Abstract

Augmented reality (AR) has revolutionized the video game industry by providing interactive, three-dimensional visualization. Interestingly, AR technology has only been sparsely used in scientific visualization. This is, at least in part, due to the significant technical challenges previously associated with creating and accessing such models. To ease access to AR for the scientific community, we introduce a novel visualization pipeline with which they can create and render AR models. We demonstrate our pipeline by means of finite element results, but note that our pipeline is generally applicable to data that may be represented through meshed surfaces. Specifically, we use two open-source software packages, ParaView and Blender. The models are then rendered through the platform, which we access through Android and iOS smartphones. To demonstrate our pipeline, we build AR models from static and time-series results of finite element simulations discretized with continuum, shell, and beam elements. Moreover, we openly provide python scripts to automate this process. Thus, others may use our framework to create and render AR models for their own research and teaching activities.

Published
2022

12. Data-driven Modeling of the Mechanical Behavior of Anisotropic Soft Biological Tissue

Author

Tac, Vahidullah, Sree, Vivek D., Rausch, Manuel K., and Tepole, Adrian B.

Subjects
Quantitative Biology - Quantitative Methods, Condensed Matter - Soft Condensed Matter, Computer Science - Computational Engineering, Finance, and Science
Abstract

Constitutive models that describe the mechanical behavior of soft tissues have advanced greatly over the past few decades. These expert models are generalizable and require the calibration of a number of parameters to fit experimental data. However, inherent pitfalls stemming from the restriction to a specific functional form include poor fits to the data, non-uniqueness of fit, and high sensitivity to parameters. In this study we design and train fully connected neural networks as material models to replace or augment expert models. To guarantee objectivity, the neural network takes isochoric strain invariants as inputs, and outputs the value of strain energy and its derivatives with respect to the invariants. Convexity of the material model is enforced through the loss function. Direct prediction of the derivative functions -- rather than just predicting the energy -- serves two purposes: it provides flexibility during training, and it enables the calculation of the elasticity tensor through back-propagation. We showcase the ability of the neural network to learn the mechanical behavior of porcine and murine skin from biaxial test data. Crucially, we show that a multi-fidelity scheme which combines high fidelity experimental data with low fidelity analytical data yields the best performance. The neural network material model can then be interpreted as the best extension of an expert model: it learns the features that an expert has encoded in the analytical model while fitting the experimental data better. Finally, we implemented a general user material subroutine (UMAT) for the finite element software Abaqus and thereby make our advances available to the broader computational community. We expect that the methods and software generated in this work will broaden the use of data-driven constitutive models in biomedical applications., Comment: 19 pages, 10 figures

Published
2021

26. Ovine tricuspid annular dynamics and three-dimensional geometry during acute atrial fibrillation.

Author

Kania-Olejnik, Paulina, Malinowski, Marcin, Rausch, Manuel K., and Timek, Tomasz A.

Subjects
RIGHT heart atrium, RIGHT ventricular dysfunction, TRICUSPID valve insufficiency, ATRIAL fibrillation, PRESSURE transducers
Abstract

Objectives: Long-standing atrial fibrillation (AF) may lead to tricuspid regurgitation (TR) and right ventricular dysfunction. However, the effect of acute AF on tricuspid annular (TA) dynamics and three-dimensional geometry is unknown. Methods: In eight adult sheep, sonomicrometry crystals were implanted around the tricuspid annulus and right ventricular free wall. Pressure transducers were placed in the right ventricle, left ventricle, and right atrium. After weaning from cardiopulmonary bypass and a period of hemodynamic stabilization, simultaneous sonomicrometry and hemodynamic data were collected in sinus rhythm (SR) and during experimental AF (400b/min right atrial pacing). Annular area, perimeter, dimensions, height, global and regional annular contraction, and strain were calculated based on cubic spline fits to crystal 3D locations. Results: Maximal TA area increased from 1084.9±273.9mm2 in SR to 1207.5±322.1mm2 during AF (p = 0.002). Anteroposterior diameter increased from 36.5±5.0mm to 38.4±5.5mm (p = 0.05). TA contraction decreased from 7±2% in SR to 2±1% in AF (p = 0.001). Anterior, posterior, and septal regional annular contraction decreased from 10±4%, 8±3% and 6±2% to 4±2%, 3±1% and 2±1% for SR and AF, respectively (p<0.05). AF perturbed systolic global annular strain (from -6.52±1.74% to -2.78±1.79%; p = 0.003) and caused annular stretch. Annular height marginally decreased with AF from 5.8±1.9mm to 5.7±2.0mm; p = 0.039. Conclusions: Acute experimental AF in healthy sheep was associated with TA dilation, flattening, and decreased total and regional annular contractility. These data may help elucidate the pathophysiology of functional TR associated with AF. [ABSTRACT FROM AUTHOR]

Published
2024
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31. Differential gene expression of leaflet tissue in chronic ovine functional tricuspid regurgitation.

Author

Gaweda, Boguslaw, Goodyke, Austin, Prokop, Jeremy, Arora, Sanjana, Iwasieczko, Artur, Piekarska, Magda, Zagorski, Joseph, Widenka, Kazimierz, Rausch, Manuel K, Aguirre, Aitor, and Timek, Tomasz A

Subjects
TRICUSPID valve insufficiency, GENE expression, PAMPHLETS, PULMONARY artery, TISSUE remodeling
Abstract

OBJECTIVES Severe functional tricuspid regurgitation (FTR) is associated with subvalvular remodelling, but leaflet tissue alterations may also contribute. We set out to investigate molecular mechanisms driving leaflet remodelling in chronic ovine FTR. METHODS Thirteen adult sheep (55 ± 4 kg) underwent left thoracotomy, epicardial echocardiography and pulmonary artery banding to induce right heart failure and FTR. After 16 weeks, 13 banded (FTR) and 12 control animals underwent median sternotomy for epicardial echocardiography and were subsequently sacrificed with each tricuspid leaflet tissue harvested for RNA-seq and histology. RESULTS After 16 weeks, 7 animals developed severe, 2 moderate and 4 mild tricuspid regurgitation. Relative to control, FTR animals had increased pulmonary artery pressure, tricuspid regurgitation, tricuspid annular diameter and right atrial volume, while tricuspid annular plane systolic excursion and right ventricle fractional area change decreased. FTR leaflets exhibited altered constituents and an increase in cellularity. RNA-seq identified 85 significantly differentially expressed genes with 17, 53 and 127 within the anterior, posterior and septal leaflets, respectively. RRM2 , PRG4 and CXCL8 (IL-8) were identified as differentially expressed genes across all leaflets and CXCL8 was differentially expressed between FTR severity grades. RRM2 , PRG4 and CXCL8 significantly correlated with tricuspid annular plane systolic excursion, and this correlation was consistent regardless of the anatomical location of the leaflet. CONCLUSIONS Pulmonary artery banding in our ovine model resulted in right ventricle failure and FTR. Leaflet RNA-seq identified several differentially expressed genes, specifically RRM2 , PRG4 and CXCL8 , with known roles in tissue remodelling. These data, along with an overall increase in leaflet cellularity, suggest tricuspid leaflets actively remodel in FTR. [ABSTRACT FROM AUTHOR]

Published
2024
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37. Human Cardiac Function Simulator for the Optimal Design of a Novel Annuloplasty Ring with a Sub-valvular Element for Correction of Ischemic Mitral Regurgitation

Author

Baillargeon, Brian, Costa, Ivan, Leach, Joseph R, Lee, Lik Chuan, Genet, Martin, Toutain, Arnaud, Wenk, Jonathan F, Rausch, Manuel K, Rebelo, Nuno, Acevedo-Bolton, Gabriel, Kuhl, Ellen, Navia, Jose L, and Guccione, Julius M

Subjects
Biomedical and Clinical Sciences, Engineering, Biomedical Engineering, Heart Disease - Coronary Heart Disease, Bioengineering, Cardiovascular, Clinical Research, Heart Disease, Animals, Computer Simulation, Humans, Male, Mitral Valve, Mitral Valve Annuloplasty, Mitral Valve Insufficiency, Models, Anatomic, Models, Cardiovascular, Myocardial Infarction, Software, Swine, Tricuspid Valve, Ventricular Dysfunction, Left, Ventricular Remodeling, Finite element method, Realistic simulation, Myocardial infarction, Ventricular function, Ischemic mitral regurgitation, Mitral annuloplasty, Cardiovascular medicine and haematology, Biomedical engineering
Abstract

Ischemic mitral regurgitation is associated with substantial risk of death. We sought to: (1) detail significant recent improvements to the Dassault Systèmes human cardiac function simulator (HCFS); (2) use the HCFS to simulate normal cardiac function as well as pathologic function in the setting of posterior left ventricular (LV) papillary muscle infarction; and (3) debut our novel device for correction of ischemic mitral regurgitation. We synthesized two recent studies of human myocardial mechanics. The first study presented the robust and integrative finite element HCFS. Its primary limitation was its poor diastolic performance with an LV ejection fraction below 20% caused by overly stiff ex vivo porcine tissue parameters. The second study derived improved diastolic myocardial material parameters using in vivo MRI data from five normal human subjects. We combined these models to simulate ischemic mitral regurgitation by computationally infarcting an LV region including the posterior papillary muscle. Contact between our novel device and the mitral valve apparatus was simulated using Dassault Systèmes SIMULIA software. Incorporating improved cardiac geometry and diastolic myocardial material properties in the HCFS resulted in a realistic LV ejection fraction of 55%. Simulating infarction of posterior papillary muscle caused regurgitant mitral valve mechanics. Implementation of our novel device corrected valve dysfunction. Improvements in the current study to the HCFS permit increasingly accurate study of myocardial mechanics. The first application of this simulator to abnormal human cardiac function suggests that our novel annuloplasty ring with a sub-valvular element will correct ischemic mitral regurgitation.

Published
2015

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