Abstract:
Reversible mechanical dysfunction of the myocardium after a single or multiple episode(s) of coronary artery occlusion has been observed in previous studies and is termed...Show MoreMetadata
Abstract:
Reversible mechanical dysfunction of the myocardium after a single or multiple episode(s) of coronary artery occlusion has been observed in previous studies and is termed myocardial stunning. The hypothesis that stunning could be represented by a decrease in maximum available muscle force in the stunned region was examined by means of a mathematical model that incorporates series viscoelastic elements. A canine experimental model was also employed to demonstrate depressed contractility and a consistent delay of shortening in the stunned region. The mechanical model of the left ventricle was designed to include a normal and stunned region, for which the stunned region was allowed to have variable size. Each region consisted of a volume and time dependent force generator in parallel with a passive elastic force element. The passive elastic element was placed in series with a constant viscosity component and a series elastic component. The model was solved by means of a computer. Passive and active properties of each region could be altered independently. The typical regional measures of muscle performance such as percent shortening, percent bulge, percent thickening, delay of shortening, percent increase in end-diastolic length and other hemodynamic measures were computed. These results were similar to those observed in animal models of stunning. In addition, a nearly linear relationship with end-diastolic length and delay of shortening was predicted by the model. It was concluded that a decrease in the peak isovolumic elastance and augmentation of viscosity effect of creep during stunning can explain mechanical abnormalities of stunned myocardium.
Published in: IEEE Transactions on Biomedical Engineering ( Volume: 43, Issue: 12, December 1996)
DOI: 10.1109/10.544339
Citations are not available for this document.
Cites in Papers - |
Cites in Papers - IEEE (8)
Select All
1.
Trung Q. Le, Satish T.S. Bukkapatnam, Akkarapol Sangasoongsong, Ranga Komanduri, "Towards virtual instruments for cardiovascular healthcare: Real-time modeling of cardiovascular dynamics using ECG signals", 2010 IEEE International Conference on Automation Science and Engineering, pp.903-910, 2010.
2.
J.K.-J. Li, G. Drzewiecki, Ying Zhu, Xiaoming Guan, J. Kedem, "Cardiac Force and Muscle Shortening in Regional Ischemia: Asynchronization and Possible Uncoupling", 2005 IEEE Engineering in Medicine and Biology 27th Annual Conference, pp.5716-5718, 2005.
3.
John K.-J. Li, Ying Zhu, K. Khaw, J. Kedem, "Cardiac Parametric Variations in Post-Ischemic Myocardium", The 26th Annual International Conference of the IEEE Engineering in Medicine and Biology Society, vol.2, pp.3639-3641, 2004.
4.
J.K.-J. Li, G. Drzewiecki, T. Barton, K. Khaw, J. Kedem, "Myocardial stunning analyzed by a single muscle fiber model", Proceedings of the 25th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (IEEE Cat. No.03CH37439), vol.1, pp.100-102 Vol.1, 2003.
5.
J.K.-J. Li, J. Xiao, G. Drzewiecki, J. Kedem, K. Khaw, "Ventricular relaxation in myocardial ischemia: a computer model-based analysis", 2001 Conference Proceedings of the 23rd Annual International Conference of the IEEE Engineering in Medicine and Biology Society, vol.1, pp.98-99 vol.1, 2001.
6.
Jianhong Xiao, J.K.-J. Li, G. Drzewiecki, J. Kedem, K. Khaw, J. Agarwal, "Ventricular relaxation phase in myocardial ischemia: model-based global and regional assessments", Proceedings of the IEEE 26th Annual Northeast Bioengineering Conference (Cat. No.00CH37114), pp.129-130, 2000.
7.
Jia-Jung Wang, R.L.-C. Pan, J.K.-J. Li, G. Drzewiecki, "Contraction augmentation in left ventricular nonischemic region during ischemia", Proceedings of the 20th Annual International Conference of the IEEE Engineering in Medicine and Biology Society. Vol.20 Biomedical Engineering Towards the Year 2000 and Beyond (Cat. No.98CH36286), pp.411-414 vol.1, 1998.
8.
M. Yoshizawa, K. Abe, H. Takedu, T. Yambe, S. Nitta, "Classical but effective techniques for estimating cardiovascular dynamics", IEEE Engineering in Medicine and Biology Magazine, vol.16, no.5, pp.106-112, 1997.
Cites in Papers - Other Publishers (12)
1.
John K-J. Li, Mehmet Kaya, Peter L.M. Kerkhof, "Quantitative cardiology and computer modeling analysis of heart failure in systole and in diastole", Computers in Biology and Medicine, 2018.
2.
Yawei Wang, Hongdai Sun, Jianan Wei, Xuesong Liu, Tianya Liu, Yubo Fan, "A mathematical model of human heart including the effects of heart contractility varying with heart rate changes", Journal of Biomechanics, 2018.
3.
Seyyed M. H. Haddad, Abbas Samani, "A finite element model of myocardial infarction using a composite material approach", Computer Methods in Biomechanics and Biomedical Engineering, pp.1, 2017.
4.
Seyyed M.H. Haddad, Abbas Samani, "A computational model of the left ventricle biomechanics using a composite material approach", International Journal of Engineering Science, vol.111, pp.61, 2017.
5.
Aymen Laadhari, Alfio Quarteroni, "Numerical modeling of heart valves using resistive Eulerian surfaces", International Journal for Numerical Methods in Biomedical Engineering, pp.n/a, 2015.
6.
John K-J. Li, Glen Atlas, "Left Ventricle–Arterial System Interaction in Heart Failure", Clinical Medicine Insights: Cardiology, vol.9s1, pp.CMC.S18742, 2015.
7.
Yubing Shi, Patricia Lawford, Rodney Hose, "Review of Zero-D and 1-D Models of Blood Flow in the Cardiovascular System", BioMedical Engineering OnLine, vol.10, no.1, 2011.
8.
Alejandro N. Mazzadi, Xavier André-Fouët, Nicolas Costes, Pierre Croisille, Didier Revel, Marc F. Janier, "Mechanisms leading to reversible mechanical dysfunction in severe CAD: alternatives to myocardial stunning", American Journal of Physiology-Heart and Circulatory Physiology, vol.291, no.6, pp.H2570, 2006.
9.
Theodosios Korakianitis, Yubing Shi, "A concentrated parameter model for the human cardiovascular system including heart valve dynamics and atrioventricular interaction", Medical Engineering & Physics, vol.28, no.7, pp.613, 2006.
10.
Theodosios Korakianitis, Yubing Shi, "Effects of atrial contraction, atrioventricular interaction and heart valve dynamics on human cardiovascular system response", Medical Engineering & Physics, vol.28, no.8, pp.762, 2006.
11.
Theodosios Korakianitis, Yubing Shi, "Numerical simulation of cardiovascular dynamics with healthy and diseased heart valves", Journal of Biomechanics, vol.39, no.11, pp.1964, 2006.
12.
Jia-Jung Wang, Gary M. Drzewiecki, Analysis and Assessment of Cardiovascular Function, pp.70, 1998.
