Title :
Arterial viscoelasticity: a fractional derivative model
Author :
Craiem, Damian O. ; Armentano, Ricardo L.
Author_Institution :
Favaloro Univ., Buenos Aires
fDate :
Aug. 30 2006-Sept. 3 2006
Abstract :
Arteries are viscoelastic materials. Viscoelastic laws are fully characterized by measuring a complex modulus. Arterial mechanics can be described using stress-strain dynamic measurements applied to the particular cylindrical geometry. Most materials show an energy loss per cycle that increases steadily with frequency. By contrast, the frequency modulus response in arteries presents a frequency independence describing a plateau above a corner frequency near 4Hz. Traditional methods to fit this response include several spring and dashpot elements to model integer order differential equations in time domain. Recently, fractional derivative models proved to be efficient to describe rheological tissues, reducing the number of parameters and showing a natural power-law response. In this work a fractional derivative model with 4-parameter was selected to describe the arterial wall mechanics in-vivo. Strain and stress were measured simultaneously in an anaesthetized sheep. A fractional model was applied. The order resulted alpha=0.12, confirming the manifest elastic response of the aorta. The fractional derivative model proved to naturally mimic the elastic modulus spectrum with only 4 parameters and a reasonable small computational effort
Keywords :
biomechanics; biomedical measurement; cardiovascular system; differential equations; elastic moduli; physiological models; stress-strain relations; viscoelasticity; arterial viscoelasticity; arterial wall mechanics; cylindrical geometry; elastic modulus spectrum; fractional derivative model; frequency modulus response; integer order differential equations; power-law response; rheological tissues; stress-strain dynamic measurements; Arteries; Elasticity; Energy loss; Frequency; Geometry; Mechanical variables measurement; Particle measurements; Strain measurement; Stress measurement; Viscosity; arteries; complex modulus; fractional models; viscoelasticity;
Conference_Titel :
Engineering in Medicine and Biology Society, 2006. EMBS '06. 28th Annual International Conference of the IEEE
Conference_Location :
New York, NY
Print_ISBN :
1-4244-0032-5
Electronic_ISBN :
1557-170X
DOI :
10.1109/IEMBS.2006.259709