Your search keyword '"Watanabe, Sansuke M."' showing total 8 results

1. On the anatomical definition of arterial networks in blood flow simulations: comparison of detailed and simplified models

Author

Blanco, Pablo J., Müller, Lucas O., Watanabe, Sansuke M., and Feijóo, Raúl A.

Published

2020

2. An Anatomically Detailed Arterial-Venous Network Model. Cerebral and Coronary Circulation

Author

Muller, Lucas O., Watanabe, Sansuke M., Toro, Eleuterio F., Feijóo, Raúl A., and Blanco, Pablo J.

Subjects

haemodynamics, brain circulation, coronary circulation, wave propagation, arterial-venous system, haemodynamics, wave propagation, arterial-venous system, cardiovascular diseases, brain circulation, coronary circulation, cardiovascular diseases

Published

2023

3. Blood flow distribution in an anatomically detailed arterial network model: criteria and algorithms

Author

Blanco, Pablo J., Watanabe, Sansuke M., Dari, Enzo A., Passos, Marco Aurélio R. F., and Feijóo, Raúl A.

Published

2014

4. Roadmap for cardiovascular circulation model

Author

Safaei, Soroush, Bradley, Christopher P., Suresh, Vinod, Mithraratne, Kumar, Muller, Alexandre, Ho, Harvey, Ladd, David, Hellevik, Leif R., Omholt, Stig W., Chase, J. Geoffrey, Müller, Lucas O., Watanabe, Sansuke M., Blanco, Pablo J., de Bono, Bernard, and Hunter, Peter J.

Subjects

Cardiovascular Physiological Phenomena, Special section reviews: The Cardiac Physiome Project, Blood Circulation, Hemodynamics, Models, Cardiovascular, Humans, Software

Abstract

Computational models of many aspects of the mammalian cardiovascular circulation have been developed. Indeed, along with orthopaedics, this area of physiology is one that has attracted much interest from engineers, presumably because the equations governing blood flow in the vascular system are well understood and can be solved with well-established numerical techniques. Unfortunately, there have been only a few attempts to create a comprehensive public domain resource for cardiovascular researchers. In this paper we propose a roadmap for developing an open source cardiovascular circulation model. The model should be registered to the musculo-skeletal system. The computational infrastructure for the cardiovascular model should provide for near real-time computation of blood flow and pressure in all parts of the body. The model should deal with vascular beds in all tissues, and the computational infrastructure for the model should provide links into CellML models of cell function and tissue function. In this work we review the literature associated with 1D blood flow modelling in the cardiovascular system, discuss model encoding standards, software and a model repository. We then describe the coordinate systems used to define the vascular geometry, derive the equations and discuss the implementation of these coupled equations in the open source computational software OpenCMISS. Finally, some preliminary results are presented and plans outlined for the next steps in the development of the model, the computational software and the graphical user interface for accessing the model.

Published

2016

5. A high-order local time stepping finite volume solver for one-dimensional blood flow simulations: application to the ADAN model.

Author

Müller, Lucas O., Blanco, Pablo J., Watanabe, Sansuke M., and Feijóo, Raúl A.

Subjects

BLOOD flow, FINITE volume method, BLOOD vessels, PARAMETER estimation, SIMULATION methods & models, VISCOELASTICITY, ANATOMY

Abstract

In recent years, the complexity of vessel networks for one-dimensional blood flow models has significantly increased, because of enhanced anatomical detail or automatic peripheral vasculature generation, for example. This fact, along with the application of these models in uncertainty quantification and parameter estimation poses the need for extremely efficient numerical solvers. The aim of this work is to present a finite volume solver for one-dimensional blood flow simulations in networks of elastic and viscoelastic vessels, featuring high-order space-time accuracy and local time stepping (LTS). The solver is built on (i) a high-order finite volume type numerical scheme, (ii) a high-order treatment of the numerical solution at internal vertexes of the network, often called junctions, and (iii) an accurate LTS strategy. The accuracy of the proposed methodology is verified by empirical convergence tests. Then, the resulting LTS scheme is applied to arterial networks of increasing complexity and spatial scale heterogeneity, with a number of one-dimensional segments ranging from a few tens up to several thousands and vessel lengths ranging from less than a millimeter up to tens of centimeters, in order to evaluate its computational cost efficiency. The proposed methodology can be extended to any other hyperbolic system for which network applications are relevant. Copyright © 2016 John Wiley & Sons, Ltd. [ABSTRACT FROM AUTHOR]

Published

2016

6. An Anatomically Detailed Arterial Network Model for One-Dimensional Computational Hemodynamics.

Author

Blanco, Pablo J., Watanabe, Sansuke M., Passos, Marco Aurelio R. F., Lemos, Pedro A., and Feijoo, Raul A.

Subjects

*CARDIOVASCULAR system, *THEORY of wave motion, *BLOOD flow, *COMPUTATIONAL fluid dynamics, *MATHEMATICAL models

Abstract

Simulation platforms are increasingly becoming complementary tools for cutting-edge cardiovascular research. The interplay among structural properties of the arterial wall, morphometry, anatomy, wave propagation phenomena, and ultimately, cardiovascular diseases continues to be poorly understood. Accurate models are powerful tools to shed light on these open problems. We developed an anatomically detailed computational model of the arterial vasculature to conduct 1-D blood flow simulations to serve as simulation infrastructure to aid cardiovascular research. An average arterial vasculature of a man was outlined in 3-D space to serve as geometrical substrate for the mathematical model. The architecture of this model comprises almost every arterial vessel acknowledged in the medical/anatomical literature, with a resolution down to the luminal area of perforator arteries. Over 2000 arterial vessels compose the model. Anatomical, physiological, and mechanical considerations were employed for the set up of model parameters and to determine criteria for blood flow distribution. Computational fluid dynamics was used to simulate blood flow and wave propagation phenomena in such arterial network. A sensitivity analysis was developed to unveil the contributions of model parameters to the conformation of the pressure waveforms. In addition, parameters were modified to target model to a patient-specific scenario. On the light of the knowledge domain, we conclude that the present model features excellent descriptive and predictive capabilities in both patient-generic and patient-specific cases, presenting a new step toward integrating an unprecedented anatomical description, morphometric, and simulations data to help in understanding complex arterial blood flow phenomena and related cardiovascular diseases. [ABSTRACT FROM PUBLISHER]

Published

2015

7. An anatomically detailed arterial-venous network model. Cerebral and coronary circulation.

Author

Müller LO, Watanabe SM, Toro EF, Feijóo RA, and Blanco PJ

Abstract

In recent years, several works have addressed the problem of modeling blood flow phenomena in veins, as a response to increasing interest in modeling pathological conditions occurring in the venous network and their connection with the rest of the circulatory system. In this context, one-dimensional models have proven to be extremely efficient in delivering predictions in agreement with in-vivo observations. Pursuing the increase of anatomical accuracy and its connection to physiological principles in haemodynamics simulations, the main aim of this work is to describe a novel closed-loop Anatomically-Detailed Arterial-Venous Network (ADAVN) model. An extremely refined description of the arterial network consisting of 2,185 arterial vessels is coupled to a novel venous network featuring high level of anatomical detail in cerebral and coronary vascular territories. The entire venous network comprises 189 venous vessels, 79 of which drain the brain and 14 are coronary veins. Fundamental physiological mechanisms accounting for the interaction of brain blood flow with the cerebro-spinal fluid and of the coronary circulation with the cardiac mechanics are considered. Several issues related to the coupling of arterial and venous vessels at the microcirculation level are discussed in detail. Numerical simulations are compared to patient records published in the literature to show the descriptive capabilities of the model. Furthermore, a local sensitivity analysis is performed, evidencing the high impact of the venous circulation on main cardiovascular variables., Competing Interests: The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2023 Müller, Watanabe, Toro, Feijóo and Blanco.)

Published

2023

8. Roadmap for cardiovascular circulation model.

Author

Safaei S, Bradley CP, Suresh V, Mithraratne K, Muller A, Ho H, Ladd D, Hellevik LR, Omholt SW, Chase JG, Müller LO, Watanabe SM, Blanco PJ, de Bono B, and Hunter PJ

Subjects

Cardiovascular Physiological Phenomena, Hemodynamics, Humans, Software, Blood Circulation, Models, Cardiovascular

Abstract

Computational models of many aspects of the mammalian cardiovascular circulation have been developed. Indeed, along with orthopaedics, this area of physiology is one that has attracted much interest from engineers, presumably because the equations governing blood flow in the vascular system are well understood and can be solved with well-established numerical techniques. Unfortunately, there have been only a few attempts to create a comprehensive public domain resource for cardiovascular researchers. In this paper we propose a roadmap for developing an open source cardiovascular circulation model. The model should be registered to the musculo-skeletal system. The computational infrastructure for the cardiovascular model should provide for near real-time computation of blood flow and pressure in all parts of the body. The model should deal with vascular beds in all tissues, and the computational infrastructure for the model should provide links into CellML models of cell function and tissue function. In this work we review the literature associated with 1D blood flow modelling in the cardiovascular system, discuss model encoding standards, software and a model repository. We then describe the coordinate systems used to define the vascular geometry, derive the equations and discuss the implementation of these coupled equations in the open source computational software OpenCMISS. Finally, some preliminary results are presented and plans outlined for the next steps in the development of the model, the computational software and the graphical user interface for accessing the model., (© 2016 The Authors. The Journal of Physiology © 2016 The Physiological Society.)

Published

2016