Auer, M., R. Stollberger, P. Regitnig, F. Ebner, and G. A. Holzapfel. In vitro angioplasty of atherosclerotic human femoral arteries: analysis of the geometrical changes in the individual tissues using MRI and image processing. Ann. Biomed. Eng. 38:1276–1287, 2010.
Balzani, D., J. Schroder, and D. Gross. Simulation of discontinuous damage incorporating residual stresses in circumferentially overstretched atherosclerotic arteries. Acta Biomater. 2:609–618, 2006.
Barrett, S. R., M. P. Sutcliffe, S. Howarth, Z. Y. Li, and J. H. Gillard. Experimental measurement of the mechanical properties of carotid atherothrombotic plaque fibrous cap. J. Biomech. 41(9):1995–2002, 2009.
Calvo, B., E. Pena, M. A. Martinez, and M. Doblare. An uncoupled directional damage model for fibred biological soft tissues. Formulation and computational aspects. Int. J. Numer. Methods Eng. 69:2037–2057, 2007.
Chua, S. N. D., B. J. MacDonald, and M. S. J. Hashmi. Finite element simulation of slotted tube (stent) with the presence of plaque and artery by balloon expansion. J. Mater. Process. Technol. 155–156:1772–1779, 2004.
Delfino, A., N. Stergiopulos, J. E. Moore, Jr., and J. J. Meister. Residual strain effects on the stress field in a thick wall finite element model of the human carotid bifurcation. J. Biomech. 30:777–786, 1997.
Diani, J., M. Brieu, and J. M. Vacherand. A damage directional constitutive model for Mullins effect with permanent set and induced anisotropy. Eur. J. Mech. A Solids 25:483–496, 2006.
Dorfmann, A., and R. W. Ogden. A constitutive model for the Mullins effect with permanent set in particle-reinforced rubber. Int. J. Solids Struct. 41:1855–1878, 2004.
Early, M., and D. J. Kelly. The role of vessel geometry and material properties on the mechanics of stenting in the coronary and peripheral arteries. Proc. Inst. Mech. Eng. H 224:465–476, 2010.
Early, M., C. Lally, P. J. Prendergast, and D. J. Kelly. Stresses in peripheral arteries following stent placement: a finite element analysis. Comput. Methods Biomech. Biomed. Eng. 12:25–33, 2009.
Ebenstein, D. M., D. Coughlin, J. Chapman, C. Li, and L. A. Pruitt. Nanomechanical properties of calcification, fibrous tissue, and hematoma from atherosclerotic plaques. J. Biomed. Mater. Res. A 91:1028–1037, 2009.
Emery, J. L., J. H. Omens, and A. D. McCulloch. Strain softening in rat left ventricular myocardium. J. Biomech. Eng. 119:6–12, 1997.
Gasser, T. C., and G. A. Holzapfel. A rate-independent elastoplastic model for biological fiber-reinforced composites at finite strains: continuum basis, algorithmic formulation and finite element implementation. Comput. Mech. 29:340–360, 2002.
Gasser, T. C., and G. A. Holzapfel. Finite element modeling of balloon angioplasty by considering overstretch of remnant non-diseased tissues in lesions. Comput. Mech. 40:47–60, 2007.
Gil, R., C. Di Mario, F. Prati, C. von Birgelen, P. Ruygrok, J. R. Roelandt, and P. W. Serruys. Influence of plaque composition on mechanisms of percutaneous transluminal coronary balloon angioplasty assessed by ultrasound imaging. Am. Heart J. 131:591–597, 1996.
Hokanson, J., and S. Yazdani. A constitutive model of the artery with damage. Mech. Res. Commun. 24:151–159, 1997.
Holzapfel, G. A. Nonlinear Solid Mechanics. New York: John Wiley & Sons, 2000.
Holzapfel, G. A., G. Sommer, and P. Regitnig. Anisotropic mechanical properties of tissue components in human atherosclerotic plaques. J. Biomech. Eng. 126:657–665, 2004.
Honye, J., D. J. Mahon, A. Jain, C. J. White, S. R. Ramee, J. B. Wallis, A. al-Zarka, and J. M. Tobis. Morphological effects of coronary balloon angioplasty in vivo assessed by intravascular ultrasound imaging. Circulation 85:1012–1025, 1992.
Kiousis, D. E., T. C. Gasser, and G. A. Holzapfel. A numerical model to study the interaction of vascular stents with human atherosclerotic lesions. Ann. Biomed. Eng. 35:1857–1869, 2007.
Lally, C., F. Dolan, and P. J. Prendergast. Cardiovascular stent design and vessel stresses: a finite element analysis. J. Biomech. 38:1574–1581, 2005.
Lee, R. T., A. J. Grodinsky, and E. H. Frank. Structure-dependent dynamic mechanical behavior of fibrous caps from human atherosclerotic plaques. Circulation 83:1764–1770, 1991.
Lee, R. T., S. G. Richardson, H. M. Loree, A. J. Grodinsky, S. A. Gharib, F. J. Schoen, and N. Pandian. Prediction of mechanical properties of human atherosclerotic tissue by high-frequency intravascular ultrasound imaging. An in vitro study. Arterioscl. Thromb. Vasc. Biol. 12:1–5, 1992.
Li, J., D. Mayau, and V. Lagarrigue. A constitutive model dealing with damage due to cavity growth and the Mullins effect in rubber-like materials under triaxial loading. J. Mech. Phys. Solids 56:933–973, 2008.
Li, D., and A. M. Robertson. A structural multi-mechanism damage model for cerebral arterial tissue. J. Biomech. Eng. 131:101013, 2009.
Liang, D. K., D. Z. Yang, M. Qi, and W. Q. Wang. Finite element analysis of the implantation of a balloon-expandable stent in a stenosed artery. Int. J. Cardiol. 104:314–318, 2005.
Loree, H. M., A. J. Grodinsky, S. Y. Park, L. J. Gibson, and R. T. Lee. Static circumferential tangential modulus of human atherosclerotic tissue. J. Biomech. 27:195–204, 1994.
Maher, E., A. Creane, S. Sultan, N. Hynes, C. Lally, and D. J. Kelly. Tensile and compressive properties of fresh human carotid atherosclerotic plaques. J. Biomech. 42:2760–2767, 2009.
Miehe, C. Discontinuous and continuous damage evolution in Ogden-type large-strain elastic materials. Eur. J. Mech. A Solids 14:697–720, 1995.
Migliavacca, F., L. Petrini, P. Massarotti, S. Schievano, F. Auricchio, and G. Dubini. Stainless and shape memory alloy coronary stents: a computational study on the interaction with the vascular wall. Biomech. Model. Mechanobiol. 2:205–217, 2004.
Mortier, P., G. A. Holzapfel, M. De Beule, D. Van Loo, Y. Taeymans, P. Segers, P. Verdonck, and B. Verhegghe. A novel simulation strategy for stent insertion and deployment in curved coronary bifurcations: comparison of three drug-eluting stents. Ann. Biomed. Eng. 38:88–99, 2010.
Naghdi, P. M., and J. A. Tarpp. The significance of formulating plasticity theory with reference to loading surfaces in strain space. Int. J. Eng. Sci. 13:785–797, 1975.
Nicolaides, A. N., S. K. Kakkos, M. Griffin, G. Geroulakos, and E. Bashardi. Ultrasound plaque characterisation, genetic markers and risks. Pathophysiol. Haemost. Thromb. 32:371–377, 2002.
Ogden, R. W., and D. G. Roxburgh. A pseudo-elastic model for the Mullins effect in filled rubber. Proc. R. Soc. Lond. A 455:2861–2877, 1999.
Pena, E., B. Calvo, M. A. Martinez, and M. Doblare. On finite-strain damage of viscoelastic-fibred materials. Applications to soft biological tissues. Int. J. Numer. Methods Eng. 74:1198–1218, 2008.
Pena, E., and M. Doblare. An anisotropic pseudo-elastic approach for modelling Mullins effect in fibrous biological materials. Mech. Res. Commun. 36:784–790, 2009.
Pericevic, I., C. Lally, D. Toner, and D. J. Kelly. The influence of plaque composition on underlying arterial wall stress during stent expansion: the case for lesion-specific stents. Med. Eng. Phys. 31:428–433, 2009.
Robertson, S. W., C. P. Cheng, and M. K. Razavi. Biomechanical response of stented carotid arteries to swallowing and neck motion. J. Endovasc. Ther. 15:663–671, 2008.
Simo, J. C., and J. W. Ju. Strain- and stress-based continuum damage models—II. Computational aspects. Int. J. Solids Struct. 7:841–869, 1987.
Tanaka, E., and H. Yamada. Inelastic constitutive modeling for blood vessels based on viscoplasticity. Front. Med. Biol. Eng. 2:177–180, 1990.
Tegos, T. J., K. J. Alomiris, M. M. Sabetai, E. Kalodiki, and A. N. Nicolaides. Significance of sonographic tissue and surface characteristics of carotid plaques. Am. J. Neuroradiol. 22:1605–1612, 2001.
Topoleski, L. D., and N. V. Salunke. Mechanical behavior of calcified plaques: a summary of compression and stress-relaxation experiments. Z. Kardiol. 89(Suppl 2):85–91, 2000.
Topoleski, L. D. T., N. V. Salunke, and W. J. Mergner. Composition- and history-dependent radial compressive behavior of human atherosclerotic plaque. J. Biomed. Mater. Res. 35:117–127, 1997.
Volokh, K. Y., and D. A. Vorp. A model of growth and rupture of abdominal aortic aneurysm. J. Biomech. 41:1015–1021, 2008.
Vos, A. W., M. A. Linsen, J. T. Marcus, J. C. van den Berg, J. A. Vos, J. A. Rauwerda, and W. Wisselink. Carotid artery dynamics during head movements: a reason for concern with regard to carotid stenting? J. Endovasc. Ther. 10:862–869, 2003.
Waller, B. F. The eccentric coronary atherosclerotic plaque: morphologic observations and clinical relevance. Clin. Cardiol. 12:14–20, 1989.
Woo, C., W. Kinm, and J. Kwon. A study on the material properties and fatigue life prediction of natural rubber component. Mater. Sci. Eng. A 483–484:376–381, 2008.
Wu, W., M. Qi, X. P. Liu, D. Z. Yang, and W. Q. Wang. Delivery and release of nitinol stent in carotid artery and their interactions: a finite element analysis. J. Biomech. 40:3034–3040, 2007.
Wulandana, R., and A. M. Robertson. An inelastic multi-mechanism constitutive equation for cerebral arterial tissue. Biomech. Model. Mechanobiol. 4:235–248, 2005.
Zahedmanesh, H., D. John Kelly, and C. Lally. Simulation of a balloon expandable stent in a realistic coronary artery—determination of the optimum modelling strategy. J. Biomech. 43:2126–2132, 2010.
RetroSearch is an open source project built by @garambo | Open a GitHub Issue
Search and Browse the WWW like it's 1997 | Search results from DuckDuckGo
HTML:
3.2
| Encoding:
UTF-8
| Version:
0.7.4