Vascular endothelium, hemodynamic forces, and atherogenesis.

Intimal lipid accumulation, hyperplasia, and scarring are stigmata of atherosclerotic vascular disease, whose major complications—myocardial and cerebral ischemia and infarction—continue to be major health problems in developed nations. 1 This insidiously progressive disease typically spans decades, but can reach a clinical horizon in a matter of minutes due to critical changes in a given atherosclerotic plaque that result in localized but life-threatening thrombosis. Epidemiological studies have established that hypercholesterolemia is an important risk factor in this disease process, and lipid-lowering drugs have been proven to have clinical efficacy. Experimental animals that are fed lipid-rich diets to elevate their plasma cholesterol levels also can develop atherosclerotic-like lesions, as do animals with naturally occurring or genetically engineered mutations that result in altered cholesterol metabolism. However, regardless of a given patient’s risk factor profile, species of animal model, or type of natural or engineered genetic alteration, the early, lipid-rich lesions of atherosclerosis show a markedly nonrandom pattern of distribution within the arterial vasculature. Atherosclerotic lesions typically develop in the vicinity of branch points and areas of major curvature. These arterial geometries are associated with blood flow disturbances such as nonuniform laminar flow with boundary layer separation, complex secondary flows with flow reversal and dynamic stagnation points, and resultant temporal and spatial gradients in wall shear stresses. In contrast to these atherosclerosis-prone areas, unbranched, tubular arterial geometries, which are associated with a more uniformly laminar flow profile, characteristically are relatively atherosclerosis-resistant, at least in the early phases of the disease. This strikingly localized pattern of lesion formation, even in the face of systemic risk factors such as elevated plasma cholesterol, has intrigued experimental pathologists and fluid mechanical engineers alike for decades, and has motivated the search for a mechanistic link between hemodynamic forces and atherogenesis.

[1]  Kenneth A. Barbee,et al.  A mechanism for heterogeneous endothelial responses to flow in vivo and in vitro. , 1995 .

[2]  G. Garcı́a-Cardeña,et al.  Distinct Mechanical Stimuli Differentially Regulate the PI3K/Akt Survival Pathway in Endothelial Cells , 2000, Annals of the New York Academy of Sciences.

[3]  J. Frangos,et al.  Pulsatile and steady flow induces c‐fos expression in human endothelial cells , 1993, Journal of cellular physiology.

[4]  James N.Topper and Michael A.Gimbrone Hemodynamics and Endothelial Phenotype: New Insights into the Modulation of Vascular Gene Expression by Fluid Mechanical Stimuli , 1999 .

[5]  S. Izumo,et al.  Molecular aspects of signal transduction of shear stress in the endothelial cell. , 1994, Journal of hypertension.

[6]  R M Nerem,et al.  Oscillatory shear stress stimulates adhesion molecule expression in cultured human endothelium. , 1998, Circulation research.

[7]  M. Gimbrone,et al.  Biomechanical activation: an emerging paradigm in endothelial adhesion biology. , 1997, The Journal of clinical investigation.

[8]  C F Dewey,et al.  The dynamic response of vascular endothelial cells to fluid shear stress. , 1981, Journal of biomechanical engineering.

[9]  C F Dewey,et al.  Platelet-derived growth factor B chain promoter contains a cis-acting fluid shear-stress-responsive element. , 1993, Proceedings of the National Academy of Sciences of the United States of America.

[10]  B L Langille,et al.  Reductions in arterial diameter produced by chronic decreases in blood flow are endothelium-dependent. , 1986, Science.

[11]  T. Collins,et al.  Nuclear factor-kappa B interacts functionally with the platelet-derived growth factor B-chain shear-stress response element in vascular endothelial cells exposed to fluid shear stress. , 1995, The Journal of clinical investigation.

[12]  C F Dewey,et al.  The distribution of fluid forces on model arterial endothelium using computational fluid dynamics. , 1992, Journal of biomechanical engineering.

[13]  M. Reidy,et al.  Scanning electron microscopy of arteries. The morphology of aortic endothelium in haemodynamically stressed areas associated with branches. , 1977, Atherosclerosis.

[14]  R. Ross,et al.  Atherosclerosis is an inflammatory disease. , 1998, American heart journal.

[15]  M. Gimbrone,et al.  Shear stress selectively upregulates intercellular adhesion molecule-1 expression in cultured human vascular endothelial cells. , 1994, The Journal of clinical investigation.

[16]  C F Dewey,et al.  Shear stress gradients remodel endothelial monolayers in vitro via a cell proliferation-migration-loss cycle. , 1997, Arteriosclerosis, thrombosis, and vascular biology.

[17]  N. Resnick,et al.  Hemodynamic forces are complex regulators of endothelial gene expression , 1995, FASEB journal : official publication of the Federation of American Societies for Experimental Biology.

[18]  J. Cooke,et al.  Fluid shear stress induces endothelial transforming growth factor beta-1 transcription and production. Modulation by potassium channel blockade. , 1995, The Journal of clinical investigation.

[19]  D. Paul,et al.  Connexin43 is highly localized to sites of disturbed flow in rat aortic endothelium but connexin37 and connexin40 are more uniformly distributed. , 1998, Circulation research.

[20]  P. Davies,et al.  Flow-mediated endothelial mechanotransduction. , 1995, Physiological reviews.

[21]  M. Gimbrone,et al.  Blood flow and vascular gene expression: fluid shear stress as a modulator of endothelial phenotype. , 1999, Molecular medicine today.

[22]  R M Nerem,et al.  Correlation of Endothelial Cell Shape and Wall Shear Stress in a Stenosed Dog Aorta , 1986, Arteriosclerosis.

[23]  N Harbeck,et al.  Spatial and temporal regulation of gap junction connexin43 in vascular endothelial cells exposed to controlled disturbed flows in vitro. , 1999, Proceedings of the National Academy of Sciences of the United States of America.

[24]  M. Gimbrone,et al.  Vascular endothelium responds to fluid shear stress gradients. , 1992, Arteriosclerosis and thrombosis : a journal of vascular biology.

[25]  J. Ando,et al.  Negative transcriptional regulation of the VCAM-1 gene by fluid shear stress in murine endothelial cells. , 1997, The American journal of physiology.

[26]  R. Schroter,et al.  Arterial Wall Shear and Distribution of Early Atheroma in Man , 1969, Nature.

[27]  C F Dewey,et al.  Turbulent fluid shear stress induces vascular endothelial cell turnover in vitro. , 1986, Proceedings of the National Academy of Sciences of the United States of America.

[28]  R M Nerem,et al.  The elongation and orientation of cultured endothelial cells in response to shear stress. , 1985, Journal of biomechanical engineering.

[29]  T Zand,et al.  Lipid deposition in rat aortas with intraluminal hemispherical plug stenosis. A morphological and biophysical study. , 1999, The American journal of pathology.

[30]  C F Dewey,et al.  Vascular endothelial cells respond to spatial gradients in fluid shear stress by enhanced activation of transcription factors. , 1999, Arteriosclerosis, thrombosis, and vascular biology.

[31]  C F Dewey,et al.  Orientation of endothelial cells in shear fields in vitro. , 1984, Biorheology.

[32]  M. Gimbrone,et al.  Identification of vascular endothelial genes differentially responsive to fluid mechanical stimuli: cyclooxygenase-2, manganese superoxide dismutase, and endothelial cell nitric oxide synthase are selectively up-regulated by steady laminar shear stress. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[33]  B. Berk,et al.  Laminar shear stress: mechanisms by which endothelial cells transduce an atheroprotective force. , 1998, Arteriosclerosis, thrombosis, and vascular biology.

[34]  D E Ingber,et al.  Cellular control lies in the balance of forces. , 1998, Current opinion in cell biology.

[35]  M. Nehls,et al.  Shear stress inhibits apoptosis of human endothelial cells , 1996, FEBS letters.