Mechanical properties of native and ex vivo remodeled porcine saphenous veins.

When grafted into an arterial environment in vivo, veins remodel in response to the new mechanical environment, thereby changing their mechanical properties and potentially impacting their patency as bypass grafts. Porcine saphenous veins were subjected for one week to four different ex vivo hemodynamic environments in which pressure and shear stress were varied independently, as well as an environment that mimicked that of an arterial bypass graft. After one week of ex vivo culture, the mechanical properties of intact saphenous veins were evaluated to relate specific aspects of the mechanical environment to vein remodeling and corresponding changes in mechanics. The compliance of all cultured veins tended to be less than that of fresh veins; however, this trend was more due to changes in medial and luminal areas than changes in the intrinsic properties of the vein wall. A combination of medial hypertrophy and eutrophic remodeling leads to significantly smaller (p<0.05) wall stresses measured in all cultured veins except those subjected to bypass graft conditions relative to stresses measured in fresh veins at corresponding pressures. Our results suggest that the mechanical environment effects changes in vessel size, as well as the nature of the remodeling, which contribute to altering vein mechanical properties.

[1]  M. Hart,et al.  Mechanics of Cerebral Arterioles in Hypertensive Rats , 1988, Circulation research.

[2]  M. Safar,et al.  Opposite effects of remodeling and hypertrophy on arterial compliance in hypertension. , 1998, Hypertension.

[3]  P. Kirshbom,et al.  Mechanical Environment, Donor Age, and Presence of Endothelium Interact to Modulate Porcine Artery Viability Ex Vivo , 2004, Annals of Biomedical Engineering.

[4]  D. Ku,et al.  Early effects of arterial hemodynamic conditions on human saphenous veins perfused ex vivo. , 2000, Arteriosclerosis, thrombosis, and vascular biology.

[5]  K. Gooch,et al.  Noninvasive determination of perfused artery dimensions ex vivo using a pressure-diameter relationship. , 2003, Biorheology.

[6]  J. Meister,et al.  Model of geometrical and smooth muscle tone adaptation of carotid artery subject to step change in pressure. , 2001, American journal of physiology. Heart and circulatory physiology.

[7]  N. Brister,et al.  Effects of stretch or distention on phenylephrine-induced constriction of human coronary artery bypass grafts. , 2001, Journal of cardiothoracic and vascular anesthesia.

[8]  N. Stergiopulos,et al.  Differences in the mechanical properties of the rat carotid artery in vivo, in situ, and in vitro. , 1998, Hypertension.

[9]  C C Canver,et al.  Conduit options in coronary artery bypass surgery. , 1995, Chest.

[10]  G L'Italien,et al.  Effect of compliance mismatch on vascular graft patency. , 1987, Journal of vascular surgery.

[11]  S. Shroff,et al.  Smooth muscle relaxation and local hydraulic impedance properties of the aorta. , 2001, Journal of applied physiology.

[12]  E. Schiffrin,et al.  Structure and Mechanical Properties of Resistance Arteries in Hypertension: Role of Adhesion Molecules and Extracellular Matrix Determinants , 2000, Hypertension.

[13]  D. Ku,et al.  Transmural pressure induces matrix-degrading activity in porcine arteries ex vivo. , 1999, American journal of physiology. Heart and circulatory physiology.

[14]  A. Davies,et al.  Vein compliance: A preoperative indicator of vein morphology and of veins at risk of vascular graft stenosis , 1992, The British journal of surgery.

[15]  J. Gaynor,et al.  Hemodynamic Conditions Alter Axial and Circumferential Remodeling of Arteries Engineered Ex Vivo , 2005, Annals of Biomedical Engineering.

[16]  R H Cox,et al.  Comparison of carotid artery mechanics in the rat, rabbit, and dog. , 1978, The American journal of physiology.

[17]  Jason W Nichol,et al.  Tissue engineering of arteries by directed remodeling of intact arterial segments. , 2003, Tissue engineering.

[18]  J. Fareed,et al.  Mechanical and histologic changes in canine vein grafts. , 1988, The Journal of surgical research.

[19]  A Rachev,et al.  A model for geometric and mechanical adaptation of arteries to sustained hypertension. , 1998, Journal of biomechanical engineering.

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

[21]  S. Bund Spontaneously hypertensive rat resistance artery structure related to myogenic and mechanical properties. , 2001, Clinical science.

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