Hemodynamic Influence on Smooth Muscle Cell Kinetics and Phenotype During Early Vein Graft Adaptation

Pathologic vascular adaptation following local injury is the primary driver for accelerated intimal hyperplasia and an occlusive phenotype. Smooth muscle cell (SMC) proliferation within the wall, and migration into the developing intima, is a major component of this remodeling response. The primary objective in the current study was to investigate the effect of the local biomechanical forces on early vein graft adaptation, specifically focusing on the spatial and temporal response of SMC proliferation and conversion from a contractile to synthetic architecture. Taking advantage of the differential adaptation that occurs during exposure to divergent flow environments, vein grafts were implanted in rabbits to create two distinct flow environments and harvested at times ranging from 2 h to 28 days. Using an algorithm for the virtual reconstruction of unfixed, histologic specimens, immunohistochemical tracking of DNA synthesis, and high-throughput transcriptional analysis, the spatial and temporal changes in graft morphology, cell proliferation, and SMC phenotype were catalogued. Notable findings include a burst of cell proliferation at 7 days post-implantation, which was significantly augmented by exposure to a reduced flow environment. Compared to the adjacent media, proliferation rates were 3-fold greater in the intima, and a specific spatial distribution of these proliferating cells was identified, with a major peak in the sub-endothelial region and a second peak centering on the internal elastic lamina. Genomic markers of a contractile SMC phenotype were reduced as early as 2 h post-implantation and reached a nadir at 7 days. Network analysis of upstream regulatory pathways identified GATA6 and KLF5 as important transcription factors that regulate this shift in SMC phenotype.

[1]  M. Adams,et al.  Kinetics of vein graft hyperplasia: association with tangential stress. , 1987, Journal of vascular surgery.

[2]  A. Chott,et al.  Effect of formalin tissue fixation and processing on immunohistochemistry. , 2000, The American journal of surgical pathology.

[3]  W. Edwards,et al.  Differential histopathology of primary atherosclerotic and restenotic lesions in coronary arteries and saphenous vein bypass grafts: analysis of tissue obtained from 73 patients by directional atherectomy. , 1991, Journal of the American College of Cardiology.

[4]  Tony P. Pridmore,et al.  Smooth 3-D Reconstruction for 2-D Histological Images , 2009, IPMI.

[5]  F. Kudo,et al.  Sustained orbital shear stress stimulates smooth muscle cell proliferation via the extracellular signal-regulated protein kinase 1/2 pathway. , 2005, Journal of vascular surgery.

[6]  Marc Garbey,et al.  Rule-Based Model of Vein Graft Remodeling , 2013, PloS one.

[7]  Tao Ju,et al.  3D volume reconstruction of a mouse brain from histological sections using warp filtering , 2006, Journal of Neuroscience Methods.

[8]  R. Ogden,et al.  A New Constitutive Framework for Arterial Wall Mechanics and a Comparative Study of Material Models , 2000 .

[9]  Lysle H. Peterson,et al.  Mechanical Properties of Arteries in Vivo , 1960 .

[10]  P. Hagen,et al.  Myointimal thickening in experimental vein grafts is dependent on wall tension. , 1992, Journal of vascular surgery.

[11]  J. Tarbell,et al.  Interstitial flow through the internal elastic lamina affects shear stress on arterial smooth muscle cells. , 2000, American journal of physiology. Heart and circulatory physiology.

[12]  Gerhard Sommer,et al.  Determination of layer-specific mechanical properties of human coronary arteries with nonatherosclerotic intimal thickening and related constitutive modeling. , 2005, American journal of physiology. Heart and circulatory physiology.

[13]  Darin R. Goldman,et al.  A novel vein graft model: adaptation to differential flow environments. , 2004, American journal of physiology. Heart and circulatory physiology.

[14]  Darin R. Goldman,et al.  Impact of Shear Stress on Early Vein Graft Remodeling: A Biomechanical Analysis , 2004, Annals of Biomedical Engineering.

[15]  Stéphane Laurent,et al.  Structural and Genetic Bases of Arterial Stiffness , 2005, Hypertension.

[16]  Arrate Muñoz-Barrutia,et al.  3D reconstruction of histological sections: Application to mammary gland tissue , 2010, Microscopy research and technique.

[17]  G. Meyer,et al.  The modulation of smooth muscle cell phenotype is an early event in human aorto-coronary saphenous vein grafts , 2006, Virchows Archiv A.

[18]  Marc Garbey,et al.  A dynamical system that describes vein graft adaptation and failure. , 2013, Journal of theoretical biology.

[19]  P. Dobrin,et al.  Mechanical factors predisposing to intimal hyperplasia and medial thickening in autogenous vein grafts. , 1989, Surgery.

[20]  J. Tarbell,et al.  Flow through internal elastic lamina affects shear stress on smooth muscle cells (3D simulations). , 2002, American journal of physiology. Heart and circulatory physiology.

[21]  B. Sumpio,et al.  Oscillatory shear stress increases smooth muscle cell proliferation and Akt phosphorylation. , 2003, Journal of vascular surgery.

[22]  Marc Garbey,et al.  The dynamics of vein graft remodeling induced by hemodynamic forces: a mathematical model , 2011, Biomechanics and Modeling in Mechanobiology.

[23]  Franco Nardini,et al.  The Dynamical System , 2001 .

[24]  W. Gasper,et al.  Vein graft failure. , 2015, Journal of vascular surgery.

[25]  A. Zalewski,et al.  Remodeling of autologous saphenous vein grafts. The role of perivascular myofibroblasts. , 1997, Circulation.

[26]  Marc Garbey,et al.  Hemodynamically Driven Vein Graft Remodeling: A Systems Biology Approach , 2009, Vascular.

[27]  Marc Garbey,et al.  Rule-Based Simulation of Multi-Cellular Biological Systems—A Review of Modeling Techniques , 2009, Cellular and molecular bioengineering.

[28]  K. Martin,et al.  Regulation of vascular smooth muscle cell differentiation. , 2007, Journal of vascular surgery.

[29]  Li Bai,et al.  Automatic Best Reference Slice Selection for Smooth Volume Reconstruction of a Mouse Brain From Histological Images , 2010, IEEE Transactions on Medical Imaging.

[30]  Scott A Berceli,et al.  Results of PREVENT III: a multicenter, randomized trial of edifoligide for the prevention of vein graft failure in lower extremity bypass surgery. , 2006, Journal of vascular surgery.

[31]  A. Banes,et al.  Mechanical stress stimulates aortic endothelial cells to proliferate. , 1987, Journal of vascular surgery.

[32]  S Glagov,et al.  The effects of extremely low shear stress on cellular proliferation and neointimal thickening in the failing bypass graft. , 2001, Journal of vascular surgery.

[33]  G. Owens,et al.  Molecular regulation of vascular smooth muscle cell differentiation in development and disease. , 2004, Physiological reviews.