Home - News ( United States | United Kingdom | Italy | Germany ) - Football scores

Showing content from https://link.springer.com/article/10.1007/s10439-020-02655-1 below:

Evaluating the Impact of Calcification on Plaque Vulnerability from the Aspect of Mechanical Interaction Between Blood Flow and Artery Based on MRI

1. AnsysInc. ANSYS Coupled-Field Analysis Guide, 2009.

2. Barrett, H. E., K. Van der Heiden, E. Farrell, F. J. H. Gijsen, and A. C. Akyildiz. Calcifications in atherosclerotic plaques and impact on plaque biomechanics. J. Biomech. 87:1–12, 2019.

   Article  Google Scholar 

3. Brown, A. J., Z. Teng, P. A. Calvert, N. K. Rajani, O. Hennessy, N. Nerlekar, D. R. Obaid, C. Costopoulos, Y. Huang, S. P. Hoole, M. Goddard, N. E. J. West, J. H. Gillard, and M. R. Bennett. Plaque structural stress estimations improve prediction of future major adverse cardiovascular events after intracoronary imaging. Circ. Cardiovasc. Imaging 9:1–9, 2016.

   Article  Google Scholar 

4. Buffinton, C. M., and D. M. Ebenstein. Effect of calcification modulus and geometry on stress in models of calcified atherosclerotic plaque. Cardiovasc. Eng. Technol. 5:244–260, 2014.

   Article  Google Scholar 

5. Daemen, M. J., M. S. Ferguson, F. J. Gijsen, D. S. Hippe, M. E. Kooi, K. Demarco, A. C. van der Wal, C. Yuan, and T. S. Hatsukami. Carotid plaque fissure: an underestimated source of intraplaque hemorrhage. Atherosclerosis 254:102–108, 2016.

   Article  CAS  Google Scholar 

6. Fung, Y. C. Biomechanics : Mechanical Properties of Living Tissues. New York: Springer, 1993.

   Book  Google Scholar 

7. Fung, Y. C., and S. Q. Liu. Changes of zero-stress state of rat pulmonary arteries in hypoxic hypertension. J. Appl. Physiol. 70:2455–2470, 1991.

   Article  CAS  Google Scholar 

8. Gallo, D., D. A. Steinman, and U. Morbiducci. An insight into the mechanistic role of the common carotid artery on the hemodynamics at the carotid bifurcation. Ann. Biomed. Eng. 43:68–81, 2014.

   Article  Google Scholar 

9. Gao, H., Q. Long, M. Graves, J. H. Gillard, and Z. Y. Li. Carotid arterial plaque stress analysis using fluid-structure interactive simulation based on in-vivo magnetic resonance images of four patients. J. Biomech. 42:1416–1423, 2009.

   Article  Google Scholar 

10. Heart, stroke and vascular diseases: Australian facts 2004 . Canberra: Australian Institute of Health and Welfare, 2004.

11. Hoshino, T., L. A. Chow, J. J. Hsu, A. A. Perlowski, M. Abedin, J. Tobis, Y. Tintut, A. K. Mal, W. S. Klug, and L. L. Demer. Mechanical stress analysis of a rigid inclusion in distensible material: a model of atherosclerotic calcification and plaque vulnerability. Am. J. Physiol. 297:802–810, 2009.

    Article  Google Scholar 

12. Huang, H., R. Virmani, H. Younis, A. P. Burke, R. D. Kamm, and R. T. Lee. The impact of calcification on the biomechanical stability of atherosclerotic plaques. Circulation 103:1051–1056, 2001.

    Article  CAS  Google Scholar 

13. Huang, X., C. Yang, C. Yuan, F. Liu, G. Canton, J. Zheng, P. K. Woodard, G. A. Sicard, and D. Tang. Patient-specific artery shrinkage and 3D zero-stress state in multi-component 3D FSI models for carotid atherosclerotic plaques based on in vivo MRI data. Mol. Cell. Biomech. 6:121–134, 2009.

    PubMed  PubMed Central  Google Scholar 

14. Imoto, K., T. Hiro, T. Fujii, A. Murashige, Y. Fukumoto, G. Hashimoto, T. Okamura, J. Yamada, K. Mori, and M. Matsuzaki. Longitudinal structural determinants of atherosclerotic plaque vulnerability: a computational analysis of stress distribution using vessel models and three-dimensional intravascular ultrasound imaging. J. Am. Coll. Cardiol. 46:1507–1515, 2005.

    Article  Google Scholar 

15. Kiousis, D. E., S. F. Rubinigg, M. Auer, and G. A. Holzapfel. A methodology to analyze changes in lipid core and calcification onto fibrous cap vulnerability: the human atherosclerotic carotid bifurcation as an illustratory example. J. Biomech. Eng. 131:1–9, 2009.

    Article  Google Scholar 

16. Kwee, R. M. Systematic review on the association between calcification in carotid plaques and clinical ischemic symptoms. J. Vasc. Surg. 51:1015–1025, 2010.

    Article  Google Scholar 

17. Li, Z. Y., S. Howarth, T. Tang, M. Graves, J. U-King-Im, and J. H. Gillard. Does calcium deposition play a role in the stability of atheroma? Location may be the key. Cerebrovasc. Dis. 24:452–459, 2007.

    Article  Google Scholar 

18. Liu, F., C. Yuan, D. Tang, C. Yang, G. Canton, S. Mondal, and T. S. Hatsukami. A negative correlation between human carotid atherosclerotic plaque progression and plaque wall stress: in vivo MRI-based 2D/3D FSI models. J. Biomech. 41:727–736, 2008.

    Article  CAS  Google Scholar 

19. Mendieta, J. B., D. Fontanarosa, J. Wang, P. K. Paritala, T. McGahan, T. Lloyd, and Z. Li. The importance of blood rheology in patient-specific computational fluid dynamics simulation of stenotic carotid arteries. Biomech. Model. Mechanobiol. 2020. https://doi.org/10.1007/s10237-019-01282-7.

    Article  PubMed  Google Scholar 

20. Morbiducci, U., D. Gallo, D. Massai, R. Ponzini, M. A. Deriu, L. Antiga, A. Redaelli, and F. M. Montevecchi. On the importance of blood rheology for bulk flow in hemodynamic models of the carotid bifurcation. J. Biomech. 44:2427–2438, 2011.

    Article  Google Scholar 

21. Paritala, P. K., P. K. D. V. Yarlagadda, J. Wang, Y. T. Gu, and Z. Li. Numerical investigation of atherosclerotic plaque rupture using optical coherence tomography imaging and XFEM. Eng. Fract. Mech. 204:531–541, 2018.

    Article  Google Scholar 

22. Richardson, P. D. Biomechanics of plaque rupture: progress, problems, and new frontiers. Ann. Biomed. Eng. 30:524–536, 2002.

    Article  Google Scholar 

23. Stary, H. C. Natural history of calcium deposits in atherosclerosis progression and regression. Z. Kardiol. 89:28–35, 2000.

    Article  Google Scholar 

24. Tang, D., C. Yang, S. Huang, V. Mani, J. Zheng, P. K. Woodard, P. Robson, Z. Teng, M. Dweck, and Z. A. Fayad. Cap inflammation leads to higher plaque cap strain and lower cap stress: an MRI-PET/CT-based FSI modeling approach. J. Biomech. 50:121–129, 2017.

    Article  Google Scholar 

25. Teng, Z., A. J. Brown, P. A. Calvert, R. A. Parker, D. R. Obaid, Y. Huang, S. P. Hoole, N. E. J. West, J. H. Gillard, and M. R. Bennett. Coronary plaque structural stress is associated with plaque composition and subtype and higher in acute coronary syndrome: the BEACON i (Biomechanical Evaluation of Atheromatous Coronary Arteries) study. Circ. Cardiovasc. Imaging 7:461–470, 2014.

    Article  Google Scholar 

26. Teng, Z., J. He, U. Sadat, J. R. Mercer, X. Wang, N. S. Bahaei, O. M. Thomas, and J. H. Gillard. How does juxtaluminal calcium affect critical mechanical conditions in carotid atherosclerotic plaque? An exploratory study. IEEE Trans. Biomed. Eng. 61:35–40, 2014.

    Article  Google Scholar 

27. Vengrenyuk, Y., L. Cardoso, and S. Weinbaum. Micro-CT based analysis of a new paradigm for vulnerable plaque rupture: cellular microcalcifications in fibrous caps. MCB Mol. Cell. Biomech. 5:37–47, 2008.

    PubMed  Google Scholar 

28. Virmani, R., A. P. Burke, A. Farb, and F. D. Kolodgie. Pathology of the vulnerable plaque. J. Am. Coll. Cardiol. 47:1–5, 2006.

    Article  Google Scholar 

29. Wang, J., P. K. Paritala, J. B. Mendieta, Y. Komori, O. C. Raffel, Y. Gu, and Z. Li. Optical coherence tomography-based patient-specific coronary artery reconstruction and fluid–structure interaction simulation. Biomech. Model. Mechanobiol. 2019. https://doi.org/10.1007/s10237-019-01191-9.

    Article  PubMed  Google Scholar 

30. Wong, K. K. L., P. Thavornpattanapong, S. C. P. Cheung, Z. Sun, and J. Tu. Effect of calcification on the mechanical stability of plaque based on a three-dimensional carotid bifurcation model. BMC Cardiovasc. Disord. 12:7, 2012.

    Article  CAS  Google Scholar 

Download references

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