Shear stress and advanced atherosclerosis in human coronary arteries.

The role of low and oscillating shear stress as a key factor for localizing early atherosclerotic plaques is generally accepted. Once more advanced plaques protrude into the lumen, the shear stress they are exposed to changes. The influence of shear stress on plaque composition in advanced atherosclerosis is not fully understood. In this review, we discuss our recent studies on the relationship between shear stress and plaque composition and the location of plaque rupture in human coronary arteries. We have shown that elevated shear stress levels can be found over plaques inducing only mild luminal narrowing and are not subjected to treatment. Regional exposure of certain plaque regions to high shear stress is therefore a condition that will pertain for a prolonged period of time. We have also shown that in more advanced atherosclerosis the necrotic core experiences higher shear stress. Low shear stress plaque regions can be found downstream of the plaque and are stiffer. High shear stress plaque regions can be found either at the upstream, shoulder or cap region of the plaque and are softer. The plaque regions with the highest strain levels are the regions that are exposed to the highest shear stress. The high shear stress plaque regions are the only plaque regions that get softer over time. Finally, high shear stress is also associated with the location of plaque rupture in non-culprit lesion in human coronary arteries. Combining our findings with data from literature, we can conclude that advanced coronary plaques grow in the distal regions. The distal plaque regions are exposed to low shear stress, are stiffer and have a stable plaque phenotype. The regions exposed to high shear stress are softer, and are associated with vulnerable plaque features.

[1]  R. Abbate,et al.  Role of hemodynamic shear stress in cardiovascular disease. , 2011, Atherosclerosis.

[2]  Theo van Walsum,et al.  3D fusion of intravascular ultrasound and coronary computed tomography for in-vivo wall shear stress analysis: a feasibility study , 2010, The International Journal of Cardiovascular Imaging.

[3]  Michael C. McDaniel,et al.  Coronary Artery Wall Shear Stress Is Associated With Progression and Transformation of Atherosclerotic Plaque and Arterial Remodeling in Patients With Coronary Artery Disease , 2011, Circulation.

[4]  Paolo Pollice,et al.  Noninvasive detection of subclinical coronary atherosclerosis coupled with assessment of changes in plaque characteristic using novel invasive imaging modalities , 2011 .

[5]  Akiko Maehara,et al.  Morphologic and angiographic features of coronary plaque rupture detected by intravascular ultrasound. , 2002, Journal of the American College of Cardiology.

[6]  Milan Sonka,et al.  Regions of low endothelial shear stress are the sites where coronary plaque progresses and vascular remodelling occurs in humans: an in vivo serial study. , 2007, European heart journal.

[7]  S Glagov,et al.  Shear stress regulation of artery lumen diameter in experimental atherogenesis. , 1987, Journal of vascular surgery.

[8]  Akiko Maehara,et al.  A prospective natural-history study of coronary atherosclerosis. , 2011, The New England journal of medicine.

[9]  Juan F Granada,et al.  Unreliable Assessment of Necrotic Core by Virtual Histology Intravascular Ultrasound in Porcine Coronary Artery Disease , 2010, Circulation. Cardiovascular imaging.

[10]  Rob Krams,et al.  Assessment of Unstable Atherosclerosis in Mice , 2007, Arteriosclerosis, thrombosis, and vascular biology.

[11]  C. Yuan,et al.  Plaque Rupture in the Carotid Artery Is Localized at the High Shear Stress Region: A Case Report , 2007, Stroke.

[12]  Shmuel Einav,et al.  A hypothesis for vulnerable plaque rupture due to stress-induced debonding around cellular microcalcifications in thin fibrous caps , 2006, Proceedings of the National Academy of Sciences.

[13]  S. Einav,et al.  Influence of microcalcifications on vulnerable plaque mechanics using FSI modeling. , 2008, Journal of biomechanics.

[14]  N Bom,et al.  Characterization of plaque components with intravascular ultrasound elastography in human femoral and coronary arteries in vitro. , 2000, Circulation.

[15]  Dick M. Goedhart,et al.  A comparison of the distribution of necrotic core in bifurcation and non-bifurcation coronary lesions: an in vivo assessment using intravascular ultrasound radiofrequency data analysis. , 2010, EuroIntervention : journal of EuroPCR in collaboration with the Working Group on Interventional Cardiology of the European Society of Cardiology.

[16]  Frits Mastik,et al.  Noninvasive detection of subclinical coronary atherosclerosis coupled with assessment of changes in plaque characteristics using novel invasive imaging modalities: the Integrated Biomarker and Imaging Study (IBIS). , 2006, Journal of the American College of Cardiology.

[17]  N Bom,et al.  Morphological and mechanical information of coronary arteries obtained with intravascular elastography; feasibility study in vivo. , 2002, European heart journal.

[18]  Brett E Bouma,et al.  Intravascular optical imaging technology for investigating the coronary artery. , 2011, JACC. Cardiovascular imaging.

[19]  Takafumi Hiro,et al.  Localized elevation of shear stress is related to coronary plaque rupture: a 3-dimensional intravascular ultrasound study with in-vivo color mapping of shear stress distribution. , 2008, Journal of the American College of Cardiology.

[20]  P. Serruys,et al.  Characterizing Vulnerable Plaque Features With Intravascular Elastography , 2003, Circulation.

[21]  F. Bamberg,et al.  Reproducibility, Accuracy, and Predictors of Accuracy for the Detection of Coronary Atherosclerotic Plaque Composition by Computed Tomography: An Ex Vivo Comparison to Intravascular Ultrasound , 2010, Investigative radiology.

[22]  F. N. van de Vosse,et al.  The influence of boundary conditions on wall shear stress distribution in patients specific coronary trees. , 2011, Journal of biomechanics.

[23]  C von Birgelen,et al.  Plaque distribution and vascular remodeling of ruptured and nonruptured coronary plaques in the same vessel: an intravascular ultrasound study in vivo. , 2001, Journal of the American College of Cardiology.

[24]  H. Otero,et al.  Initial evaluation of coronary images from 320-detector row computed tomography , 2008, The International Journal of Cardiovascular Imaging.

[25]  E. Falk,et al.  Putative murine models of plaque rupture. , 2007, Arteriosclerosis, thrombosis, and vascular biology.

[26]  C. D. de Korte,et al.  Intravascular ultrasound elastography in human arteries: initial experience in vitro. , 1998, Ultrasound in medicine & biology.

[27]  Michail I. Papafaklis,et al.  Prediction of Progression of Coronary Artery Disease and Clinical Outcomes Using Vascular Profiling of Endothelial Shear Stress and Arterial Plaque Characteristics: The PREDICTION Study , 2012, Circulation.

[28]  Jolanda J. Wentzel,et al.  Strain Distribution Over Plaques in Human Coronary Arteries Relates to Shear Stress , 2007 .

[29]  N. Bruining,et al.  The diagnostic value of intracoronary optical coherence tomography , 2011, Herz.

[30]  P. Serruys,et al.  In vivo assessment of the relationship between shear stress and necrotic core in early and advanced coronary artery disease. , 2013, EuroIntervention : journal of EuroPCR in collaboration with the Working Group on Interventional Cardiology of the European Society of Cardiology.

[31]  R. Virmani,et al.  A mechanistic analysis of the role of microcalcifications in atherosclerotic plaque stability: potential implications for plaque rupture. , 2012, American journal of physiology. Heart and circulatory physiology.

[32]  S. Alper,et al.  Hemodynamic shear stress and its role in atherosclerosis. , 1999, JAMA.

[33]  Renu Virmani,et al.  Pathological findings at bifurcation lesions: the impact of flow distribution on atherosclerosis and arterial healing after stent implantation. , 2010, Journal of the American College of Cardiology.

[34]  E. Tuzcu,et al.  Coronary Plaque Classification With Intravascular Ultrasound Radiofrequency Data Analysis , 2002, Circulation.

[35]  Frits Mastik,et al.  Effects of the Direct Lipoprotein-Associated Phospholipase A2 Inhibitor Darapladib on Human Coronary Atherosclerotic Plaque , 2008, Circulation.

[36]  P. Serruys,et al.  Assessment of coronary atherosclerosis progression and regression at bifurcations using combined IVUS and OCT. , 2011, JACC. Cardiovascular imaging.

[37]  P. Serruys,et al.  The role of shear stress in the generation of rupture-prone vulnerable plaques , 2005, Nature Clinical Practice Cardiovascular Medicine.

[38]  Frits Mastik,et al.  Incidence of High-Strain Patterns in Human Coronary Arteries: Assessment With Three-Dimensional Intravascular Palpography and Correlation With Clinical Presentation , 2004, Circulation.

[39]  Frits Mastik,et al.  High shear stress induces a strain increase in human coronary plaques over a 6-month period. , 2011, EuroIntervention : journal of EuroPCR in collaboration with the Working Group on Interventional Cardiology of the European Society of Cardiology.

[40]  T Togawa,et al.  Adaptive regulation of wall shear stress to flow change in the canine carotid artery. , 1980, The American journal of physiology.

[41]  P. Stone,et al.  Endothelial shear stress in the evolution of coronary atherosclerotic plaque and vascular remodelling: current understanding and remaining questions. , 2012, Cardiovascular research.

[42]  A. Wahle,et al.  Effect of Endothelial Shear Stress on the Progression of Coronary Artery Disease, Vascular Remodeling, and In-Stent Restenosis in Humans: In Vivo 6-Month Follow-Up Study , 2003, Circulation.

[43]  Benjamin J Vakoc,et al.  Three-dimensional coronary artery microscopy by intracoronary optical frequency domain imaging. , 2008, JACC. Cardiovascular imaging.

[44]  Martin Styner,et al.  Standardized evaluation methodology and reference database for evaluating coronary artery centerline extraction algorithms , 2009, Medical Image Anal..

[45]  F. Grosveld,et al.  Atherosclerotic Lesion Size and Vulnerability Are Determined by Patterns of Fluid Shear Stress , 2006, Circulation.

[46]  G. Getz,et al.  Site Specificity of Atherosclerosis: Site-Selective Responses to Atherosclerotic Modulators , 2004, Arteriosclerosis, thrombosis, and vascular biology.

[47]  N Bom,et al.  Intravascular ultrasound elastography: assessment and imaging of elastic properties of diseased arteries and vulnerable plaque. , 1998, European journal of ultrasound : official journal of the European Federation of Societies for Ultrasound in Medicine and Biology.

[48]  P. Serruys,et al.  Extension of Increased Atherosclerotic Wall Thickness Into High Shear Stress Regions Is Associated With Loss of Compensatory Remodeling , 2003, Circulation.

[49]  Stéphane G Carlier,et al.  Intravascular ultrasound profile analysis of ruptured coronary plaques. , 2006, The American journal of cardiology.

[50]  E. Edelman,et al.  Role of endothelial shear stress in the natural history of coronary atherosclerosis and vascular remodeling: molecular, cellular, and vascular behavior. , 2007, Journal of the American College of Cardiology.

[51]  C. Zarins,et al.  Compensatory enlargement of human atherosclerotic coronary arteries. , 1987, The New England journal of medicine.