Stented artery biomechanics and device design optimization

Timmins, Lucas H.; Moreno, Michael R.; Meyer, Clark A.; Criscione, John C.; Rachev, Alexander; Moore, James E.

doi:10.1007/s11517-007-0180-3

Cited by 77 publications

(49 citation statements)

References 26 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…These computational methods of analysis employ sophisticated numerical techniques, such as the finite element and finite volume methods, to obtain approximate numerical solutions to complex physical problems. To date, a large number of studies have carried out computational structural (CS) analyses 1,4,5,14,15,19,[25][26][27][28][29]37,44,53,54,57,59,[62][63][64]72,73,78,80,85,87,[90][91][92] and computational fluid dynamics (CFD) analyses 3,8,9,12,30,31,33,42,[47][48][49][50][51]65,66,69,[74][75][76]83,89 ...…”

Section: Introductionmentioning

confidence: 99%

Sequential Structural and Fluid Dynamics Analysis of Balloon-Expandable Coronary Stents: A Multivariable Statistical Analysis

Martín¹,

Boyle²

2015

Cardiovasc Eng Tech

View full text Add to dashboard Cite

Abstract-Several clinical studies have identified a strong correlation between neointimal hyperplasia following coronary stent deployment and both stent-induced arterial injury and altered vessel hemodynamics. As such, the sequential structural and fluid dynamics analysis of balloon-expandable stent deployment should provide a comprehensive indication of stent performance. Despite this observation, very few numerical studies of balloon-expandable coronary stents have considered both the mechanical and hemodynamic impact of stent deployment. Furthermore, in the few studies that have considered both phenomena, only a small number of stents have been considered. In this study, a sequential structural and fluid dynamics analysis methodology was employed to compare both the mechanical and hemodynamic impact of six balloon-expandable coronary stents. To investigate the relationship between stent design and performance, several common stent design properties were then identified and the dependence between these properties and both the mechanical and hemodynamic variables of interest was evaluated using statistical measures of correlation. Following the completion of the numerical analyses, stent strut thickness was identified as the only common design property that demonstrated a strong dependence with either the mean equivalent stress predicted in the artery wall or the mean relative residence time predicted on the luminal surface of the artery. These results corroborate the findings of the large-scale ISAR-STEREO clinical studies and highlight the crucial role of strut thickness in coronary stent design. The sequential structural and fluid dynamics analysis methodology and the multivariable statistical treatment of the results described in this study should prove useful in the design of future balloon-expandable coronary stents.

show abstract

Section: Introductionmentioning

confidence: 99%

Sequential Structural and Fluid Dynamics Analysis of Balloon-Expandable Coronary Stents: A Multivariable Statistical Analysis

Martín¹,

Boyle²

2015

Cardiovasc Eng Tech

View full text Add to dashboard Cite

show abstract

“…Bedoya et al (2006) and Timmins et al (2007) optimised stent designs by minimising the volume of tissue stressed above a critical threshold. This approach attempts to capture restenosis by predicting the regions where adverse biological reactions are likely to occur.…”

Section: Introductionmentioning

confidence: 99%

Application of a mechanobiological simulation technique to stents used clinically

Boyle

Lennon

Prendergast

2013

Journal of Biomechanics

View full text Add to dashboard Cite

“…Two main approaches have been adopted to reduce instent restenosis; (1) optimising the stent design to reduce vascular injury and hence subsequent neointimal hyperplasia [17,26], and (2) using anti-proliferative drug eluting stents to inhibit the growth of neointimal hyperplasia [8]. The delivery of an anti-proliferative drug to surrounding tissue is also significantly influenced by the stent design [11].…”

Section: Introductionmentioning

confidence: 99%

Determination of the influence of stent strut thickness using the finite element method: implications for vascular injury and in-stent restenosis

Zahedmanesh

Lally

2009

Med Biol Eng Comput

120

View full text Add to dashboard Cite

Many clinical studies, including the ISAR-STEREO trial, have identified stent strut thickness as an independent predictor of in-stent restenosis where thinner struts result in lower restenosis than thicker struts. The aim of this study was to more conclusively identify the mechanical stimulus for in-stent restenosis using results from such clinical trials as the ISAR-STEREO trial. The mechanical environment in arteries stented with thin and thicker strut stents was investigated using numerical modelling techniques. Finite element models of the stents used in the ISAR-STEREO clinical trial were developed and the stents were deployed in idealised stenosed vessel geometries in order to compare the mechanical environment of the vessel for each stent. The stresses induced within the stented vessels by these stents were compared to determine the level of vascular injury caused to the artery by the stents with different strut thickness. The study found that when both stents were expanded to achieve the same initial maximum stent diameter that the thinner strut stent recoiled to a greater extent resulting in lower luminal gain but also lower stresses in the vessel wall, which is hypothesised to be responsible for the lower restenosis outcome. This study supports the hypothesis that arteries develop restenosis in response to injury, where high vessel stresses are a good measure of that injury. This study points to a critical stress level in arteries, above which an aggressive healing response leads to in-stent restenosis in stented vessels. Stents can be designed to reduce stresses in this range in arteries using preclinical tools such as numerical modelling.

show abstract

Stented artery biomechanics and device design optimization

Cited by 77 publications

References 26 publications

Sequential Structural and Fluid Dynamics Analysis of Balloon-Expandable Coronary Stents: A Multivariable Statistical Analysis

Sequential Structural and Fluid Dynamics Analysis of Balloon-Expandable Coronary Stents: A Multivariable Statistical Analysis

Application of a mechanobiological simulation technique to stents used clinically

Determination of the influence of stent strut thickness using the finite element method: implications for vascular injury and in-stent restenosis

Contact Info

Product

Resources

About