Ex vivo and in silico study of human Common Carotid Arteries pressure response in physiological and inverted state

Piechna, A.; Cieślicki, K.; Lombarski, L.; Ciszek, B.

doi:10.1515/ijame-2015-0015

Artykuł - szczegóły

Tytuł artykułu

Ex vivo and in silico study of human Common Carotid Arteries pressure response in physiological and inverted state

Autorzy

Piechna A. , Cieślicki K. , Lombarski L. , Ciszek B.

Treść / Zawartość

Pełne teksty:

15_piechna_cieslicki_lombarski_ex_vivo_and_in_silico_study_2015_1.pdf

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Identyfikatory

DOI

10.1515/ijame-2015-0015

Warianty tytułu

Języki publikacji

Abstrakty

Arterial walls are a multilayer structures with nonlinear material characteristics. Furthermore, residua stresses exist in unloaded state (zero-pressure condition) and they affect arterial behavior. To investigate these phenomena a number of theoretical and numerical studies were performed, however no experimental validation was proposed and realized yet. We cannot get rid of residual stresses without damaging the arterial segment. In this paper we propose a novel experiment to validate a numerical model of artery with residual stresses. The inspiration for our study originates from experiments made by Dobrin on dogs’ arteries (1999). We applied the idea of turning the artery inside out. After such an operation the sequence of layer is reversed and the residual stresses are re-ordered. We performed several pressure-inflation tests on human Common Carotid Arteries (CCA) in normal and inverted configurations. The nonlinear responses of arterial behavior were obtained and compared to the numerical model. Computer simulations were carried out using the commercial software which applied the finite element method (FEM). Then, these results were discussed.

Słowa kluczowe

artery mechanics residual stress pressure-inflation test common carotid artery

tętnica szyjna metoda elementów skończonych symulacja komputerowa

Wydawca

Oficyna Wydawnicza Uniwersytetu Zielonogórskiego

Czasopismo

International Journal of Applied Mechanics and Engineering

Rocznik

2015

Tom

Vol. 20, no. 1

Strony

209--214

Opis fizyczny

Bibliogr. 15 poz., rys., wykr.

Twórcy

autor

Piechna A.

adam.piechna@gmail.com

Institute of Automatic Control and Robotics Warsaw University of Technology ul. św. A. Boboli 8 02-525 Warszawa, POLAND

autor

Cieślicki K.

k.cieslicki@mchtr.pw.edu.pl

Institute of Automatic Control and Robotics Warsaw University of Technology ul. św. A. Boboli 8 02-525 Warszawa, POLAND

autor

Lombarski L.

leszek.lombarski.jr@gmail.com

Department of Descriptive and Clinical Anatomy Warsaw Medical University Chałubińskiego 5 Warszawa 02-004, POLAND

autor

Ciszek B.

bciszek@ib.amwaw.edu.pl

Department of Descriptive and Clinical Anatomy Warsaw Medical University Chałubińskiego 5 Warszawa 02-004, POLAND

Bibliografia

[1] Bergel D.H. (1960): The viscoelastic properties of the arterial wall. – Ph.D., 1960, University of London.
[2] Chuong C.J. and Fung Y.C. (1986): On residual stress in arteries. – J. Biomech. Eng., vol.108, pp.189-92.
[3] Ciszek B., Cieślicki K., Krajewski P. and Piechnik S.K. (2013): Critical pressure for arterial wall rupture in major human cerebral arteries. – Stroke, vol.44, No.11, pp.3226-3228.
[4] Delfino A., Stergiopulos N., Moore Jr J.E. and Meister J-J. (1997): Residual strain effects on the stress field in a thick wall finite element model of the human carotid bifurcation. – Journal of Biomechanics, vol.30, No.8, pp.777-786.
[5] Dobrin P.B. (1999): Distribution of Lamellar Deformations: Implications for Properties of the Arterial Media. – Hypertension, vol.33, pp.806-810.
[6] Fung Y.C. (1991): What are the residual stresses doing in our blood vessels? – Annals of Biomedical Engineering, vol.19, No.3, pp.237-249.
[7] Gasser T.C., Ogden R.W. and Holzapfel G.A. (2006): Hyperelastic modelling of arterial layers with distributed collagen fibre orientations. – Journal of the Royal Society Interface, vol.3, No.6, pp.15-35.
[8] Holzapfel G.A. and Gasser T.C. (2007): Computational stress-deformation analysis of arterial walls including highpressure response. – Int. J. Cardiology, vol.116, pp.78-85.
[9] Piechna A. and Cieślicki K. (2013): Numerical Analysis of Residual Stress Effects on the Stress Field in a Model of Common Carotid Artery at Wide Range of Transmural Pressure. – Insbruck, From Proceeding: (791) Biomedical EngineeringRachev A. and Greenwald S.E. (2003): Residual strains in conduit arteries. – J. Biomech., vol.36, No.5, pp.661-70.
[10] Rachev A. (1997): Theoretical study of the effect of stress-dependent remodeling on arterial geometry under hypertensive conditions. – Journal of Biomechanics, vol.30, No.8, pp.819-827.
[11] Sommer G. and Holzapfel G.A. (2012): 3D constitutive modeling of the biaxial mechanical response of intact and layer-dissected human carotid arteries. – Journal of the Mechanical Behavior of Biomedical Materials, vol.5, No.1, pp.116-128.
[12] Sommer G., Regitnig P., Koltringer L. and Holzapfel G.A. (2010): Biaxial mechanical properties of intact and layerdissected human carotid arteries at physiological and supraphysiological loadings. – Am. J. Physiol. Heart Circ. Physiol., vol.298, pp.898-912.
[13] Standring S. (2008): Gray’s Anatomy: The Anatomical Basis of Clinical Practice. Gray’s Anatomy Series. – Churchill Livingstone/Elsevier.
[14] Waffenschmidt T. and Menzel A. (2014): Extremal states of energy of adouble-layered thick-walled tube–application to residually stressed arteries. – Journal of the Mechanical Behavior of Biomedical Materials, vol.29, pp.635-654.
[15] Wuyts F.L., Vanhuyse V.J., Langewouters G.J., Decraemer W.F., Raman E.R. and Buyle S. (1995): Elastic properties of human aortas in relation to age and atherosclerosis: a structural model. – Physics in Medicine and Biology, vol.40, No.10, 1577.

Typ dokumentu

Bibliografia

Identyfikator YADDA

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