One way to restore physiological blood flow to occluded arteries involves the deformation of plaque using an intravascular balloon and preventing elastic recoil using a stent. Angioplasty and stent implantation cause unphysiological loading of the arterial tissue, which may lead to tissue in-growth and reblockage; termed “restenosis.” In this paper, a computational methodology for predicting the time-course of restenosis is presented. Stress-induced damage, computed using a remaining life approach, stimulates inflammation (production of matrix degrading factors and growth stimuli). This, in turn, induces a change in smooth muscle cell phenotype from contractile (as exists in the quiescent tissue) to synthetic (as exists in the growing tissue). In this paper, smooth muscle cell activity (migration, proliferation, and differentiation) is simulated in a lattice using a stochastic approach to model individual cell activity. The inflammation equations are examined under simplified loading cases. The mechanobiological parameters of the model were estimated by calibrating the model response to the results of a balloon angioplasty study in humans. The simulation method was then used to simulate restenosis in a two dimensional model of a stented artery. Cell activity predictions were similar to those observed during neointimal hyperplasia, culminating in the growth of restenosis. Similar to experiment, the amount of neointima produced increased with the degree of expansion of the stent, and this relationship was found to be highly dependant on the prescribed inflammatory response. It was found that the duration of inflammation affected the amount of restenosis produced, and that this effect was most pronounced with large stent expansions. In conclusion, the paper shows that the arterial tissue response to mechanical stimulation can be predicted using a stochastic cell modeling approach, and that the simulation captures features of restenosis development observed with real stents. The modeling approach is proposed for application in three dimensional models of cardiovascular stenting procedures.
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August 2011
Research Papers
In Silico Prediction of the Mechanobiological Response of Arterial Tissue: Application to Angioplasty and Stenting
Colin J. Boyle,
Colin J. Boyle
Trinity Centre for Bioengineering, School of Engineering,
University of Dublin
, Trinity College, Dublin, Ireland
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Alexander B. Lennon,
Alexander B. Lennon
Trinity Centre for Bioengineering, School of Engineering,
University of Dublin
, Trinity College, Dublin, Ireland
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Patrick J. Prendergast
Patrick J. Prendergast
Trinity Centre for Bioengineering, School of Engineering,
e-mail: pprender@tcd.ie
University of Dublin
, Trinity College, Dublin, Ireland
Search for other works by this author on:
Colin J. Boyle
Trinity Centre for Bioengineering, School of Engineering,
University of Dublin
, Trinity College, Dublin, Ireland
Alexander B. Lennon
Trinity Centre for Bioengineering, School of Engineering,
University of Dublin
, Trinity College, Dublin, Ireland
Patrick J. Prendergast
Trinity Centre for Bioengineering, School of Engineering,
University of Dublin
, Trinity College, Dublin, Ireland
e-mail: pprender@tcd.ie
J Biomech Eng. Aug 2011, 133(8): 081001 (10 pages)
Published Online: August 26, 2011
Article history
Received:
February 8, 2011
Revised:
June 3, 2011
Posted:
June 30, 2011
Published:
August 26, 2011
Online:
August 26, 2011
Citation
Boyle, C. J., Lennon, A. B., and Prendergast, P. J. (August 26, 2011). "In Silico Prediction of the Mechanobiological Response of Arterial Tissue: Application to Angioplasty and Stenting." ASME. J Biomech Eng. August 2011; 133(8): 081001. https://doi.org/10.1115/1.4004492
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