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Abstract #4449

Stress-Strain Characterization of a Dynamically-Controlled Cardiac Phantom with Fluid and Structural Dynamics

Nicolas Charalambous1, Kristis Michaelides1, Elias Psimolofitis2, Vasilis Tzangarakis3, Demos Michaelides3, Stelios Angeli4, Christakis Constantinides4

1Hydrus Ltd, Limassol, Cyprus; 2CNE Limited, Nicosia, Cyprus; 3α-Evresis Diagnostic Center, Nicosia, Cyprus; 4U. of Cyprus, Nicosia, Cyprus

Myocardial tissue characterization, pre- and post-implantation or following therapy, has becoming an elusive and active research area in clinical practice and basic science work. Prior efforts have focused on the invasive [Stuyvers 1997] and non-invasive MRI characterization of the left ventricular (LV) muscle elasticity [Kolinpaka 2010] to document energetic status, rates and extent of filling and relaxation [Aletras 1999, Wen 2005]. Diastolic filling, in particular, is regarded as the dynamic outcome of myocardial re-lengthening post-contraction and ventricular flow. The pressure fields developed within the intra-ventricular cavity are the determinants of wall stress and the transmural strain gradients. The temporal evolution of such gradients is ultimately dependent on tissue viscoelasticity and its mechanical material properties. Transmural stress and strain, are therefore, direct manifestations of structure-function, the muscles material properties, and the active and passive fiber force generation, as a result of sarcomeric contraction-relaxation, intra-cavity blood pressure changes, and their effects on the endocardial wall [Hu 2003]. This work develops a comprehensive noninvasive imaging protocol for computational modeling, and estimation of global cardiac stress and strain fields of an elastomeric heart of a dynamically controlled cardiac phantom using ex-vivo testing, functional MRI and computational fluid dynamics (CFD). The elicited results are validated based on the computational solutions of the Navier-Stokes (NS) equations for the elastomer and flow velocity fields, in comparison with bench experimentation and phase contrast (PC) MRI.

Keywords

according acetate achieved acquisition active activity allowed apex apical association assumption atlas axis basal become bench binary boundary camera cardiac catheter cavity chamber characterization clinical coil composed computational computations conditions conducted constructed contrast control controlled cycle cycles developed development diastolic direct distributions document dynamically dynamics elasticity elastomer electrical elements energetic equations estimation estimations evolution extension extent extraction fields final flow flows fluid force foundation frame gating generated generation global gradients heart human hydrostatic imported in vivo indicated inflow initial inlet instruments intra invasive locations long longitudinal loop machine masks matched material medical mesh meshes methodology mode model modeling module morphology motion muscle myocardial omens outflow outlet phantom pneumatic pneumatics polyvinyl pool ports pressure pressures principle properties pulse reached recorded recordings requiring resolution respectively sample scanner segmentation settings short simulation slice software solutions stokes strain stress structural surface synchronize system tabulated temporal tensor throughout tracking tubing universal unstructured validation velocities velocity ventricular wall water