Your search keyword '"Timmel T"' showing total 2 results

1. Characterization of an artificial valve flow using the numerical dye washout visualization technique: application to the monoleaflet valve with purged flow.

Author

Goubergrits L, Timmel T, Affeld K, Petz C, Stalling D, and Hege HC

Subjects

Prosthesis Design methods, Dye Dilution Technique, Heart Valve Prosthesis

Abstract

Until today, no ideal heart valve prosthesis for the replacement of a diseased natural valve or for use in ventricular assist devices exists. Valves still cause thromboembolic complications originating from thrombus formations in the valve's stagnant zones. Optimization of valve design involves avoiding stagnation zones and zones of high shear stresses. This requires detailed flow field investigations. Usually, the regions which are more prone to thrombus formation can be estimated using a dye washout experiment. The method allows an assessment of regions with a high or low residence time that may in turn predict regions with a corresponding thrombus risk. This successful experimental method was simulated using numerical methods with a combination of the computational fluid dynamics program FLUENT (Fluent Inc., Lebanon, NH, USA) and of the visualization tool AMIRA (TGS Inc., San Diego, CA, USA). The numerical dye washout visualization was applied to four monoleaflet valves with varying valve housing geometries. The results show a significant difference in the washout processes of the examined valves. The dye washout was characterized by a time course of the gray value averaged over a defined region of interest. Finally, these curves were quantified by a half dye time. The half dye time in the best optimized valve was only 0.2753 s. The same time in the original valve was 0.6834 s. This study shows that the proposed numerical method of dye washout visualization can be used as an additional tool of the flow characterization in artificial organs.

Published

2006

2. Optimization and investigation of a novel cardiac assist valve with a purge flow.

Author

Timmel T, Goubergrits L, and Affeld K

Subjects

Computer Simulation, Humans, Coronary Circulation, Heart Valve Prosthesis standards, Prosthesis Design methods

Abstract

Clinical applications of cardiac assist systems still suffer from thromboembolic complications due to thrombus formation behind the valve's leaflets. Wherever the flow is stagnant such as in the sinus, a thrombus is likely to form. The valve design in this study avoids stagnation zones behind the leaflets by a purge flow during systole. This purge flow is separated from the valve's main flow by a flow divider directing a part of the main flow into the sinus behind the leaflet. The optimization was performed on a monoleaflet valve because of its simple geometry. Relevant geometric parameters were systematically varied. Thirty-two models were designed and numerically investigated. The models with the best results were preselected and investigated in a computer-controlled valve tester. The washout of a dye filled in the sinus was digitally recorded and quantified. The results show that a sinus purge flow minimizes stagnation areas in the sinus and thus may avoid thrombus formation.

Published

2001