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Myocardial material property determination in the in vivo heart using magnetic resonance imaging (1996)

Moulton, Michael J. ; Creswell, Lawrence L. ; Downing, Stephen W. ; [et al.]

Springer

The international journal of cardiovascular imaging 12 (1996), S. 153-167

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ISSN: 1573-0743

Keywords: finite element analysis (FEA) ; material properties ; magnetic resonance imaging (MRI)

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract Objectives: To determine nonlinear material properties of passive, diastolic myocardium using magnetic resonance imaging (MRI) tissue-tagging, finite element analysis (FEA) and nonlinear optimization.Background: Alterations in the diastolic material properties of myocardium may pre-date the onset of or exist exclusive of systolic ventricular dysfunction in disease states such as hypertrophy and heart failure. Accordingly, significant effort has been expended recently to characterize the material properties of myocardium in diastole. The present study defines a new technique for determining material properties of passive myocardium using finite element (FE) models of the heart, MRI tissue-tagging and nonlinear optimization. This material parameter estimation algorithm is employed to estimate nonlinear material parameters in thein vivo canine heart and provides the necessary framework to study the full complexities of myocardial material behavior in health and disease.Methods and results: Material parameters for a proposed exponential strain energy function were determined by minimizing the least squares difference between FE model-predicted and MRI-measured diastolic strains. Six mongrel dogs underwent MRI imaging with radiofrequency (RF) tissue-tagging. Two-dimensional diastolic strains were measured from the deformations of the MRI tag lines. Finite element models were constructed from early diastolic images and were loaded with the mean early to late left ventricular and right ventricular diastolic change in pressure measured at the time of imaging. A nonlinear optimization algorithm was employed to solve the least squares objective function for the material parameters. Average material parameters for the six dogs wereE=28,722 ± 15,984 dynes/cm2 andc=0.00182 ± 0.00232 cm2/dyne.Conclusion: This parameter estimation algorithm provides the necessary framework for estimating the nonlinear, anisotropic and non-homogeneous material properties of passive myocardium in health and disease in thein vivo beating heart.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF01806218

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Study of Low-energy Atomic Mixing by Means of Auger Depth Profiling, XTEM and TRIM Simulation on Ge/Si Multilayer System (1996)

Barna, A. ; Menyhard, M.

Chichester [u.a.] : Wiley-Blackwell

Surface and Interface Analysis 24 (1996), S. 476-480

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ISSN: 0142-2421

Keywords: Chemistry ; Polymer and Materials Science

Source: Wiley InterScience Backfile Collection 1832-2000

Topics: Physics

Notes: Low-energy atomic mixing is experimentally studied on a Ge/Si amorphous multilayer system by means of Auger depth profiling and XTEM. The ion etching was performed by using Ar ions of energy 500 eV (XTEM) and 618 eV (Auger) and angle of incidence 〉84° and the specimen was rotated during sputtering. Applying these conditions it is believed that the interface broadening occurs mainly because of atomic mixing because the surface roughening is negligible. The Auger depth profile was carried out on a specimen containing Ge/Si strips parallel to the surface. The extent of the atomic mixing was determined by comparing the depth profile to profiles provided by dynamic TRIM simulation. For ion milling another geometry was used; the Ge/Si strips were perpendicular to the surface. A very thin (2 nm) TEM specimen was prepared and the thickness of the completely mixed region could be directly estimated from the TEM image: 1 nm at 500 eV ion energy and 85° angle of incidence. The TEM image also shows that the atomic mixed region is asymmetric.

Additional Material: 5 Ill.

Type of Medium: Electronic Resource

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