Bovendeerd / Clarysse / Croisille | Biomechanics of the Heart | Buch | 978-0-443-32846-6 | www.sack.de

Buch, Englisch, 500 Seiten, Format (B × H): 191 mm x 235 mm

Bovendeerd / Clarysse / Croisille

Biomechanics of the Heart

From Model to Patient
Erscheinungsjahr 2026
ISBN: 978-0-443-32846-6
Verlag: Elsevier Science

From Model to Patient

Buch, Englisch, 500 Seiten, Format (B × H): 191 mm x 235 mm

ISBN: 978-0-443-32846-6
Verlag: Elsevier Science

Biomechanics of the Heart: From Model to Patient offers a thorough exploration of the principles and applications of heart biomechanics, guiding readers from foundational physiological concepts to advanced modeling techniques. The book examines both healthy and diseased cardiac function, delving into imaging methods that capture the heart’s complex geometry and dynamics. By presenting the latest methods for modeling myocardial tissue in passive and active states, it equips readers with knowledge essential for understanding and simulating the mechanical behavior of the heart. Case studies further illustrate how these models are applied in computer-aided diagnosis and treatment, making the content practical and relevant.

In addition to detailed coverage of the heart’s anatomical and muscular structure, the book reviews cutting-edge imaging technologies and their role in analyzing cardiac properties. Chapters highlight the importance of biomechanical finite element simulations and patient-specific modeling approaches, enhancing the ability to tailor diagnosis and therapies. Readers gain insights into the exploitation of computational models for monitoring heart conditions, reinforcing the book’s value to those interested in both research and clinical practice.

Bovendeerd / Clarysse / Croisille Biomechanics of the Heart jetzt bestellen!

Autoren/Hrsg.

Bovendeerd, Peter
Clarysse, Patrick
Croisille, Pierre
Nash, Martyn

Fachgebiete

Weitere Infos & Material

Part I: The Normal and Diseased Heart
1. Anatomy, physiology, and hemodynamics of the healthy human heart
2. Heart pathologies affecting the myocardium

Part II: Imaging cardiac structures, strains, flow, and tissue properties
3. Echocardiography
4. Cardiac MRI: motion quantification
5. Cardiac MRI: DTI
6. Myocardial microstructure imaging
7. Pressure/volume measurements and hemodynamic measurements
8. Heart modeling combined with image simulation

Part III: Myocardial Tissue Modeling
9. Subcellular/molecular mechanics
10. Myocardial energetics
11. Passive myocardial properties and material laws
12. Myocardial poro-elastic models
13. Modeling myocardial scars and oedema

Part IV: Heart and Cardiovascular Modeling (Organ Level)
14. Cardia anatomy, shape modeling, cardiac atlases
15. Whole heart modeling coupled with cardiovascular system
16. Generic modeling of pathologies

Part V: Heart and Myocardial growth
17. Modeling myocardial growth and development
18. Tissue growth and engineering

Part VI: Translation of models to the clinic
19. Patient-specific cardiovascular modeling for diagnosis and prognosis
20. Patient-specific heart modeling and ML
21. 4-chamber heart modeling
22. Congenital heart modeling
23. Advanced therapies, surgical interventions

Croisille, Pierre
Pierre Croisille is Professor of Radiology, Chairman of Nuclear Medicine and Radiology, Chief of Radiology, University Hospital Saint-Etienne. He is also Deputy Directory, CREATIS Research Lab, CNRS, INSERM, Université de Lyon, Université Jean Monnet, INSA Lyon. Pierre is leading the IDM4 transversal project at CREATIS.

Nash, Martyn
Martyn Nash is a Professor of Biomedical Engineering, and Deputy Director of the Auckland Bioengineering Institute, at the University of Auckland, New Zealand. The primary focus of his research career has been on bioengineering analyses of the heart in order to understand mechanisms underlying electromechanical cardiac muscle activity in health and disease. Dr. Nash is also engaged in the design and refinement of experimental techniques, bioinstrumentation and medical devices, and model-based approaches to medical image analysis to deepen understanding of biological systems. He strives to improve diagnostic techniques, and aid in the discovery and monitoring of therapies for prevention and treatment of disease, to ultimately improve patient management and care. Dr. Nash is an elected Fellow of the American Institute for Medical and Biological Engineering, and Senior Member of IEEE and EMBS. He also serves on the Board of Directors for Functional Imaging and Modelling of the Heart (FIMH) biannual international conference, and editorial boards of the international journals Biomechanics and Modeling in Mechanobiology, and Computer Methods in Biomechanics and Biomedical Engineering. Dr. Nash has supervised 34 PhD, 16 Masters and 64 Honours dissertation students, and has authored more than 150 international journals articles and 40 book chapters, which have collectively attracted more than 8000 Google Scholar citations to-date.

Bovendeerd, Peter
Peter Bovendeerd is an assistant professor in the Department of Biomedical Engineering, research group Cardiovascular Biomechanics. Peter Bovendeerd studied Applied Physics at Eindhoven University of Technology (TU/e), where he obtained his MSc degree in 1985 with the distinction cum laude. In 1985 and

1986, he was employed at Philips Industrial & Electro Acoustic Systems. In 1986, he started PhD research at Maastricht University where he obtained his PhD in 1990 for his numerical and experimental study of the mechanical behavior of the left ventricle, both normal and ischemic. He then returned to Eindhoven, where he joined the Department of Mechanical Engineering. In 2002, he moved to the Department of Biomedical Engineering. His research focuses on improving the interpretation of clinical patient data by using mathematical models. The models are based on fundamental physical and physiological principles, and can be used to predict how (pathologic) tissue or organ properties are manifested in patient data.

When used in an inverse mode, the models provide a tool to transform these patient data back into an estimate of the underlying pathology. This model assisted diagnosis may be complemented by model assisted treatment selection and long-term prognosis.

Clarysse, Patrick
Patrick Clarysse is research director at CNRS (French National Centre for Scientific Research) and Deputy Director of CREATIS Lab, Lyon France. His primary research interests are in the bioengineering and medical image analysis fields, including medical image processing workflows, multidimensional/multimodal image segmentation and registration, motion estimation and biomechanical modeling with applications to the 3D analysis and modeling of the heart function and thoracic structures. Dr. Clarysse is one of the contributors to the inTag plugin for the integrated analysis of cardiac tagged Magnetic Resonance Images (Tagged-MRI), and further of a suite of tools within the Osirix DICOM viewer for analyzing cardiac MR images. Dr. Clarysse has coauthored more than 150 papers in international journals and conferences and three books. He has been involved in several national and European projects (notably joint projects with Finland, the VPH NoE, EGEE grid related programs, Marie-Curie Programs) and has collaborated with several European and international groups. He supervised many engineering and clinical PhD students and acted as a regular reviewer for several international journals in the field. He is one of the initiators of the Functional Imaging and Modeling of the Heart (FIMH) biannual international conference. He is a member of IEEE, EMBS and of the French Society of BioEngineering (SFGBM).

Ihre Fragen, Wünsche oder Anmerkungen
Vorname*
Nachname*
Ihre E-Mail-Adresse*
Kundennr.
Ihre Nachricht*
Lediglich mit * gekennzeichnete Felder sind Pflichtfelder.
Wenn Sie die im Kontaktformular eingegebenen Daten durch Klick auf den nachfolgenden Button übersenden, erklären Sie sich damit einverstanden, dass wir Ihr Angaben für die Beantwortung Ihrer Anfrage verwenden. Selbstverständlich werden Ihre Daten vertraulich behandelt und nicht an Dritte weitergegeben. Sie können der Verwendung Ihrer Daten jederzeit widersprechen. Das Datenhandling bei Sack Fachmedien erklären wir Ihnen in unserer Datenschutzerklärung.