Biomechanical Modeling to Improve Coronary Artery Bifurcation Stenting: Expert Review Document on Techniques and Clinical Implementation

Antonios P. Antoniadis; Peter Mortier; Ghassan Kassab; Gabriele Dubini; Nicolas Foin; Yoshinobu Murasato; Andreas A. Giannopoulos; Shengxian Tu; Kiyotaka Iwasaki; Yutaka Hikichi; Francesco Migliavacca; Claudio Chiastra; Jolanda J. Wentzel; Frank Gijsen; Johan H.C. Reiber; Peter Barlis; Patrick W. Serruys; Deepak L. Bhatt; Goran Stankovic; Elazer R. Edelman; George D. Giannoglou; Yves Louvard; Yiannis S. Chatzizisis

doi:10.1016/j.jcin.2015.06.015

Biomechanical Modeling to Improve Coronary Artery Bifurcation Stenting: Expert Review Document on Techniques and Clinical Implementation

Antonios P. Antoniadis, Peter Mortier, Ghassan Kassab, Gabriele Dubini, Nicolas Foin, Yoshinobu Murasato, Andreas A. Giannopoulos, Shengxian Tu, Kiyotaka Iwasaki, Yutaka Hikichi, Francesco Migliavacca, Claudio Chiastra, Jolanda J. Wentzel, Frank Gijsen, Johan H.C. Reiber, Peter Barlis, Patrick W. Serruys, Deepak L. Bhatt, Goran Stankovic, Elazer R. EdelmanGeorge D. Giannoglou, Yves Louvard, Yiannis S. Chatzizisis^*

^*この研究の対応する著者

大学院先進理工学研究科

研究成果: Review article › 査読

82 被引用数 (Scopus)

抄録

Treatment of coronary bifurcation lesions remains an ongoing challenge for interventional cardiologists. Stenting of coronary bifurcations carries higher risk for in-stent restenosis, stent thrombosis, and recurrent clinical events. This review summarizes the current evidence regarding application and use of biomechanical modeling in the study of stent properties, local flow dynamics, and outcomes after percutaneous coronary interventions in bifurcation lesions. Biomechanical modeling of bifurcation stenting involves computational simulations and in vitro bench testing using subject-specific arterial geometries obtained from in vivo imaging. Biomechanical modeling has the potential to optimize stenting strategies and stent design, thereby reducing adverse outcomes. Large-scale clinical studies are needed to establish the translation of pre-clinical findings to the clinical arena.

本文言語	English
論文番号	2103
ページ（範囲）	1281-1296
ページ数	16
ジャーナル	JACC: Cardiovascular Interventions
巻	8
号	10
DOI	https://doi.org/10.1016/j.jcin.2015.06.015
出版ステータス	Published - 2015 8月 24

ASJC Scopus subject areas

循環器および心血管医学

文献へのアクセス

10.1016/j.jcin.2015.06.015

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引用スタイル

Antoniadis, A. P., Mortier, P., Kassab, G., Dubini, G., Foin, N., Murasato, Y., Giannopoulos, A. A., Tu, S., Iwasaki, K., Hikichi, Y., Migliavacca, F., Chiastra, C., Wentzel, J. J., Gijsen, F., Reiber, J. H. C., Barlis, P., Serruys, P. W., Bhatt, D. L., Stankovic, G., ... Chatzizisis, Y. S. (2015). Biomechanical Modeling to Improve Coronary Artery Bifurcation Stenting: Expert Review Document on Techniques and Clinical Implementation. JACC: Cardiovascular Interventions, 8(10), 1281-1296. Article 2103. https://doi.org/10.1016/j.jcin.2015.06.015

Antoniadis, AP, Mortier, P, Kassab, G, Dubini, G, Foin, N, Murasato, Y, Giannopoulos, AA, Tu, S, Iwasaki, K, Hikichi, Y, Migliavacca, F, Chiastra, C, Wentzel, JJ, Gijsen, F, Reiber, JHC, Barlis, P, Serruys, PW, Bhatt, DL, Stankovic, G, Edelman, ER, Giannoglou, GD, Louvard, Y & Chatzizisis, YS 2015, 'Biomechanical Modeling to Improve Coronary Artery Bifurcation Stenting: Expert Review Document on Techniques and Clinical Implementation', JACC: Cardiovascular Interventions, vol. 8, no. 10, 2103, pp. 1281-1296. https://doi.org/10.1016/j.jcin.2015.06.015

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abstract = "Treatment of coronary bifurcation lesions remains an ongoing challenge for interventional cardiologists. Stenting of coronary bifurcations carries higher risk for in-stent restenosis, stent thrombosis, and recurrent clinical events. This review summarizes the current evidence regarding application and use of biomechanical modeling in the study of stent properties, local flow dynamics, and outcomes after percutaneous coronary interventions in bifurcation lesions. Biomechanical modeling of bifurcation stenting involves computational simulations and in vitro bench testing using subject-specific arterial geometries obtained from in vivo imaging. Biomechanical modeling has the potential to optimize stenting strategies and stent design, thereby reducing adverse outcomes. Large-scale clinical studies are needed to establish the translation of pre-clinical findings to the clinical arena.",

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AU - Dubini, Gabriele

AU - Foin, Nicolas

AU - Murasato, Yoshinobu

AU - Giannopoulos, Andreas A.

AU - Tu, Shengxian

AU - Iwasaki, Kiyotaka

AU - Hikichi, Yutaka

AU - Migliavacca, Francesco

AU - Chiastra, Claudio

AU - Wentzel, Jolanda J.

AU - Gijsen, Frank

AU - Reiber, Johan H.C.

AU - Barlis, Peter

AU - Serruys, Patrick W.

AU - Bhatt, Deepak L.

AU - Stankovic, Goran

AU - Edelman, Elazer R.

AU - Giannoglou, George D.

AU - Louvard, Yves

AU - Chatzizisis, Yiannis S.

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N2 - Treatment of coronary bifurcation lesions remains an ongoing challenge for interventional cardiologists. Stenting of coronary bifurcations carries higher risk for in-stent restenosis, stent thrombosis, and recurrent clinical events. This review summarizes the current evidence regarding application and use of biomechanical modeling in the study of stent properties, local flow dynamics, and outcomes after percutaneous coronary interventions in bifurcation lesions. Biomechanical modeling of bifurcation stenting involves computational simulations and in vitro bench testing using subject-specific arterial geometries obtained from in vivo imaging. Biomechanical modeling has the potential to optimize stenting strategies and stent design, thereby reducing adverse outcomes. Large-scale clinical studies are needed to establish the translation of pre-clinical findings to the clinical arena.

AB - Treatment of coronary bifurcation lesions remains an ongoing challenge for interventional cardiologists. Stenting of coronary bifurcations carries higher risk for in-stent restenosis, stent thrombosis, and recurrent clinical events. This review summarizes the current evidence regarding application and use of biomechanical modeling in the study of stent properties, local flow dynamics, and outcomes after percutaneous coronary interventions in bifurcation lesions. Biomechanical modeling of bifurcation stenting involves computational simulations and in vitro bench testing using subject-specific arterial geometries obtained from in vivo imaging. Biomechanical modeling has the potential to optimize stenting strategies and stent design, thereby reducing adverse outcomes. Large-scale clinical studies are needed to establish the translation of pre-clinical findings to the clinical arena.

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