The mechanical properties of porcine aortic valve tissues

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Sauren, A. A. H. J.¹; van Hout, M. C.¹; van Steenhoven, A. A.¹; Veldpaus, F. E.¹; Janssen, J. D.¹

The mechanical properties of porcine aortic valve tissues

J Biomech. 1983;16(5):327-337

Affiliations

¹Department of Mechanical Engineering, Eindhoven University of Technology, Eindhoven, The Netherlands
Abstract

In uniaxial tensile experiments in vitro mechanical properties of the different parts of porcine aortic valves, i.e. the leaflets, the sinus wall and the aortic wall, have been dealt with.

Tissue strips cut in different directions were investigated. The collagen bundles in the leaflets show a stiffening effect and cause a marked anisotropy: within the physiological range of strains the largest slopes of the stress-strain curves of leaflet specimens in the bundle direction are a factor of about 20 larger than those of specimens taken along the perpendicular direction. For the sinus and aortic tissues, these values are 50–200 times smaller than those obtained from the leaflet specimens in the bundle direction.

Two aspects of viscoelastic behaviour were examined: the strain rate sensitivity of the stress-strain curves and the relaxation behaviour. The stress-strain curves of the different valve parts appeared to be rather insensitive to the strain rate: the most pronounced sensitivity observed in our experiments, was a doubling of the stress at the same strain caused by a hundredfold increase of the strain rate. In analyzing the relaxation behaviour, use was made of the relaxation model proposed by Fung (1972, in Biomechanics, its Foundations and Objectives; Fung, Perrone and Anliker. Prentice Hall). In the leaflets, about 45% stress relaxation was found whereas this amounted to 30% in the sinus and aortic walls. Predictions based upon the model indicate that on cyclic loading the larger viscous losses have to be expected in the leaflets.
Links

DOI: 10.1016/0021-9290(83)90016-7

PubMed: 6885834

WoS: A1983RB95200003
History

Received: 1982-03-19

Revised: 1982-10-25

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2001	Provenzano P, Lakes R, Keenan T, Vanderby R Jr. Nonlinear ligament viscoelasticity. Ann Biomed Eng. October 2001;29(10):908-914.
2002	Provenzano PP, Lakes RS, Corr DT, Vanderby R. Application of nonlinear viscoelastic models to describe ligament behavior. Biomech Model Mechanobiol. June 2002;1(1):45-57.
1983	Rousseau EPM, Sauren AAHJ, van Hout MC, van Steenhove AA. Elastic and viscoelastic material behaviour of fresh and glutaraldehyde-treated porcine aortic valve tissue. J Biomech. 1983;16(5):339-348.
1987	Nigul I, Nigul U. On algorithms of evaluation of Fung's relaxation function parameters. J Biomech. 1987;20(4):343-352.
1984	Dortmans LJMG, Sauren AAHJ, Rousseau EPM. Parameter estimation using the quasi-linear viscoelastic model proposed by Fung. J Biomech Eng. August 1984;106(3):198-203.
1996	Johnson GA, Livesay GA, Woo SL-Y, Rajagopal KR. A single integral finite strain viscoelastic model of ligaments and tendons. J Biomech Eng. May 1996;118(2):221-226.
2003	Thomopoulos S, Williams GR, Soslowsky LJ. Tendon to bone healing: differences in biomechanical, structural, and compositional properties due to a range of activity levels. J Biomech Eng. February 2003;125(1):106-113.
2004	Abramowitch SD, Woo SL-Y. An improved method to analyze the stress relaxation of ligaments following a finite ramp time based on the quasi-linear viscoelastic theory. J Biomech Eng. February 2004;126(1):92-97.
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1996	de Jager MKJ. Mathematical Head-Neck Models for Acceleration Impacts [PhD thesis]. Eindhoven, The Netherlands: Eindhoven University of Technology; 1996.
2001	Thomopoulos S. Supraspinatus Tendon to Bone Healing: Differences in Biomechanical, Structural, and Compositional Properties Due to a Range of Activity Levels [PhD thesis]. University of Michigan; 2001.
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1999	Ledoux WR II. A Biomechanical Model of the Human Foot With Emphasis on the Plantar Soft Tissue [PhD thesis]. Philadelphia, PA: University of Pennsylvania; 1999.
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