Calcific aortic valve disease (CAVD) is a progressive disease in which minerals accumulate in the tissue of the aortic valve cusps, stiffening them and preventing valve opening and closing. The process of valve calcification was found to be similar to that of bone formation including cell differentiation to osteoblast-like cells. Studies have shown the contribution of high strains to calcification initiation and growth process acceleration. In this paper, a new strain-based calcification growth model is proposed. The model aims to explain the unique shape of the calcification and other disease characteristics. The calcification process was divided into two stages: Calcification initiation and calcification growth. The initiation locations were based on previously published findings and a reverse calcification technique (RCT), which uses computed tomography (CT) scans of patients to reveal the calcification initiation point. The calcification growth process was simulated by a finite element model of one aortic valve cusp loaded with cyclic loading. Similar to Wolff's law, describing bone response to stress, our model uses strains to drive calcification formation. The simulation grows calcification from its initiation point to its full typical stenotic shape. Study results showed that the model was able to reproduce the typical calcification growth pattern and shape, suggesting that strain is the main driving force behind calcification progression. The simulation also sheds light on other disease characteristics, such as calcification growth acceleration as the disease progresses, as well as sensitivity to hypertension.
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October 2018
Research-Article
A New Growth Model for Aortic Valve Calcification
Rotem Halevi,
Rotem Halevi
School of Mechanical Engineering,
Tel-Aviv University,
Tel Aviv 69978, Israel
Tel-Aviv University,
Tel Aviv 69978, Israel
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Ashraf Hamdan,
Ashraf Hamdan
Department of Cardiology,
Rabin Medical Center,
Petach Tikva 4941492, Israel
Rabin Medical Center,
Petach Tikva 4941492, Israel
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Gil Marom,
Gil Marom
School of Mechanical Engineering,
Tel-Aviv University,
Tel Aviv 69978, Israel;
Tel-Aviv University,
Tel Aviv 69978, Israel;
Department of Biomedical Engineering,
Stony Brook University,
Stony Brook, NY 11794
Stony Brook University,
Stony Brook, NY 11794
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Karin Lavon,
Karin Lavon
School of Mechanical Engineering,
Tel-Aviv University,
Tel Aviv 69978, Israel
Tel-Aviv University,
Tel Aviv 69978, Israel
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Sagit Ben-Zekry,
Sagit Ben-Zekry
Echocardiography Laboratory,
Chaim Sheba Medical Center,
Tel Hashomer 52621, Israel
Chaim Sheba Medical Center,
Tel Hashomer 52621, Israel
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Ehud Raanani,
Ehud Raanani
Cardiothoracic Surgery Department,
Chaim Sheba Medical Center,
Tel Hashomer 52621, Israel
Chaim Sheba Medical Center,
Tel Hashomer 52621, Israel
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Rami Haj-Ali
Rami Haj-Ali
School of Mechanical Engineering,
The Nathan Cummings Chair in Mechanics,
The Fleischman Faculty of Engineering,
Tel-Aviv University,
Tel Aviv 69978, Israel
e-mail: rami98@eng.tau.ac.il
The Nathan Cummings Chair in Mechanics,
The Fleischman Faculty of Engineering,
Tel-Aviv University,
Tel Aviv 69978, Israel
e-mail: rami98@eng.tau.ac.il
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Rotem Halevi
School of Mechanical Engineering,
Tel-Aviv University,
Tel Aviv 69978, Israel
Tel-Aviv University,
Tel Aviv 69978, Israel
Ashraf Hamdan
Department of Cardiology,
Rabin Medical Center,
Petach Tikva 4941492, Israel
Rabin Medical Center,
Petach Tikva 4941492, Israel
Gil Marom
School of Mechanical Engineering,
Tel-Aviv University,
Tel Aviv 69978, Israel;
Tel-Aviv University,
Tel Aviv 69978, Israel;
Department of Biomedical Engineering,
Stony Brook University,
Stony Brook, NY 11794
Stony Brook University,
Stony Brook, NY 11794
Karin Lavon
School of Mechanical Engineering,
Tel-Aviv University,
Tel Aviv 69978, Israel
Tel-Aviv University,
Tel Aviv 69978, Israel
Sagit Ben-Zekry
Echocardiography Laboratory,
Chaim Sheba Medical Center,
Tel Hashomer 52621, Israel
Chaim Sheba Medical Center,
Tel Hashomer 52621, Israel
Ehud Raanani
Cardiothoracic Surgery Department,
Chaim Sheba Medical Center,
Tel Hashomer 52621, Israel
Chaim Sheba Medical Center,
Tel Hashomer 52621, Israel
Rami Haj-Ali
School of Mechanical Engineering,
The Nathan Cummings Chair in Mechanics,
The Fleischman Faculty of Engineering,
Tel-Aviv University,
Tel Aviv 69978, Israel
e-mail: rami98@eng.tau.ac.il
The Nathan Cummings Chair in Mechanics,
The Fleischman Faculty of Engineering,
Tel-Aviv University,
Tel Aviv 69978, Israel
e-mail: rami98@eng.tau.ac.il
1Corresponding author.
Manuscript received December 28, 2017; final manuscript received May 16, 2018; published online June 21, 2018. Assoc. Editor: Seungik Baek.
J Biomech Eng. Oct 2018, 140(10): 101008 (8 pages)
Published Online: June 21, 2018
Article history
Received:
December 28, 2017
Revised:
May 16, 2018
Citation
Halevi, R., Hamdan, A., Marom, G., Lavon, K., Ben-Zekry, S., Raanani, E., and Haj-Ali, R. (June 21, 2018). "A New Growth Model for Aortic Valve Calcification." ASME. J Biomech Eng. October 2018; 140(10): 101008. https://doi.org/10.1115/1.4040338
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