Biomechanical modeling of the cardiovascular system / Ricardo L. Armentano, Edmundo I. Cabrera Fischer, Leandro J. Cymberknop.

By: Armentano, Ricardo [author.]Contributor(s): Cabrera Fischer, Edmundo I [author.] | Cymberknop, Leandro J [author.] | Institute of Physics (Great Britain) [publisher.]Material type: TextTextSeries: IOP (Series)Release 6 | IOP expanding physics | IPEM-IOP series in physics and engineering in medicine and biologyPublisher: Bristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) : IOP Publishing, [2019]Description: 1 online resource (various pagings) : illustrationsContent type: text Media type: electronic Carrier type: online resourceISBN: 9780750312813 ebookSubject(s): Cardiovascular system -- Computer simulation | Cardiovascular system -- Mechanical properties | Biomechanics -- Computer simulation | Cardiovascular System | Computer Simulation | Biomechanical Phenomena | Biomedical engineering | TECHNOLOGY & ENGINEERING / BiomedicalAdditional physical formats: Print version:: No titleDDC classification: 612.1 LOC classification: QP101 .A763 2019ebNLM classification: WG 100Online resources: e-book Full-text access Also available in print.
Contents:
1. Structural basis of the circulatory system -- 1.1. Introduction -- 1.2. Cardiac structure -- 1.3. Vessel structure -- 1.4. The circulatory system -- 1.5. Human blood -- 1.6. Microcirculation
2. Human circulatory function -- 2.1. Hemodynamics -- 2.2. The left ventricular function -- 2.3. Vessel function -- 2.4. Blood rheology -- 2.5. Venous return to right atrium
3. Mathematical background for mechanical vessel analysis -- 3.1. Biomechanics -- 3.2. The constitutive equation -- 3.3. Physics of the equilibrium of blood vessels -- 3.4. Viscoelasticity -- 3.5. Frequency dependence of the elastic modulus E([o
4. Modeling of the cardiovascular function -- 4.1. In vitro models -- 4.2. Isolated perfused animal heart -- 4.3. In vivo animal model -- 4.4. Ex vivo animal model -- 4.5. Steady and transient states -- 4.6. Final comments
5. Modeling of cardiovascular dysfunction -- 5.1. Characteristics of human cardiovascular failure -- 5.2. Anatomy and physiology of animals used to model human cardiovascular diseases -- 5.3. Models of cardiac disease -- 5.4. Models of vascular
6. Hemodynamic modelization during therapeutical interventions : counterpulsation -- 6.1. Aortic counterpulsation -- 6.2. Left ventricular changes during aortic counterpulsation -- 6.3. Effects of aortic counterpulsation on blood circulation --
7. Arterial wall modelization in the time and frequency domain -- 7.1. Linear elastic theory -- 7.2. Implementation of models in arterial mechanics -- 7.3. Elastic passive behavior -- 7.4. Active elastic behavior -- 7.5. Dynamic behavior
8. Pulse propagation in arteries -- 8.1. Introduction
9. Damping in the vascular wall -- 9.1. Physiological bases of wall damping and filtering -- 9.2. Methodological approach -- 9.3. Experimental applications
10. Modeling of biological prostheses -- 10.1. Introduction -- 10.2. Biomechanical evaluation on electrospun vascular grafts
11. Arterial hypertension, chaos and fractals -- 11.1. Complexity, health and disease -- 11.2. Fractal dimension : a holistic index -- 11.3. Conclusion
12. Mathematical blood flow models : numerical computing and applications -- 12.1. Towards a patient-specific modeling for clinical applications -- 12.2. Interaction between blood flow and the arterial wall : fluid-structure coupling -- 12.3. Im
Abstract: Modeling has provided not only answers to questions related to normal or pathological function but also predicted multiple adaptations of the total and individual dynamic structures that are included in cardiovascular research. The original idea
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IOP Science eBook - EBA QP101 .A763 2019eb (Browse shelf (Opens below)) Available IOP_20210083

"Version: 20190401"--Title page verso.

Includes bibliographical references.

1. Structural basis of the circulatory system -- 1.1. Introduction -- 1.2. Cardiac structure -- 1.3. Vessel structure -- 1.4. The circulatory system -- 1.5. Human blood -- 1.6. Microcirculation

2. Human circulatory function -- 2.1. Hemodynamics -- 2.2. The left ventricular function -- 2.3. Vessel function -- 2.4. Blood rheology -- 2.5. Venous return to right atrium

3. Mathematical background for mechanical vessel analysis -- 3.1. Biomechanics -- 3.2. The constitutive equation -- 3.3. Physics of the equilibrium of blood vessels -- 3.4. Viscoelasticity -- 3.5. Frequency dependence of the elastic modulus E([o

4. Modeling of the cardiovascular function -- 4.1. In vitro models -- 4.2. Isolated perfused animal heart -- 4.3. In vivo animal model -- 4.4. Ex vivo animal model -- 4.5. Steady and transient states -- 4.6. Final comments

5. Modeling of cardiovascular dysfunction -- 5.1. Characteristics of human cardiovascular failure -- 5.2. Anatomy and physiology of animals used to model human cardiovascular diseases -- 5.3. Models of cardiac disease -- 5.4. Models of vascular

6. Hemodynamic modelization during therapeutical interventions : counterpulsation -- 6.1. Aortic counterpulsation -- 6.2. Left ventricular changes during aortic counterpulsation -- 6.3. Effects of aortic counterpulsation on blood circulation --

7. Arterial wall modelization in the time and frequency domain -- 7.1. Linear elastic theory -- 7.2. Implementation of models in arterial mechanics -- 7.3. Elastic passive behavior -- 7.4. Active elastic behavior -- 7.5. Dynamic behavior

8. Pulse propagation in arteries -- 8.1. Introduction

9. Damping in the vascular wall -- 9.1. Physiological bases of wall damping and filtering -- 9.2. Methodological approach -- 9.3. Experimental applications

10. Modeling of biological prostheses -- 10.1. Introduction -- 10.2. Biomechanical evaluation on electrospun vascular grafts

11. Arterial hypertension, chaos and fractals -- 11.1. Complexity, health and disease -- 11.2. Fractal dimension : a holistic index -- 11.3. Conclusion

12. Mathematical blood flow models : numerical computing and applications -- 12.1. Towards a patient-specific modeling for clinical applications -- 12.2. Interaction between blood flow and the arterial wall : fluid-structure coupling -- 12.3. Im

Modeling has provided not only answers to questions related to normal or pathological function but also predicted multiple adaptations of the total and individual dynamic structures that are included in cardiovascular research. The original idea

Biomedical engineering graduate and undergraduate students, clinical engineers, electrical engineers, biomedical technicians and cardiologists.

Also available in print.

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Ricardo L. Armentano is a Uruguayan professor and researcher who has worked in biomedical engineering and cardiovascular systems. He currently serves as the director of the GIBIO research group at the National Technological University--Buenos Ai

Title from PDF title page (viewed on May 6, 2019).