ABSTRACT
A recently developed electrophoretic instrumentation based on a real-time image processing system has been applied to electrophoretic fingerprinting and multiparameter analysis of cells and other particles. The comparison between theoretical and experimental electrophoretic fingerprints, completed by the analysis of differences between measured fingerprints, offers a new methodology for better understanding and controlling of the processes at solid/liquid interfaces. Moreover, the multi-parameter analysis including electrophoretic mobility, size, density and shape of cells can complete the diagnosis and prognosis of diseases.
Subject(s)
Electrophoresis/methods , Erythrocytes/cytology , Ascitic Fluid/cytology , Ascitic Fluid/metabolism , Humans , Peritonitis/pathology , Silicon DioxideABSTRACT
The proper design of a left ventricular assist device (LVAD) requires an understanding of the pump's fluid dynamic and biocompatible properties. A hydraulically efficient system minimizes the power required for pumping. Biocompatibility refers to the ability to pump blood with minimal hemolysis and thrombus formation. Typically, shear stresses below a threshold level will not damage blood significantly. A fluid dynamic analysis of a prototype centrifugal pump designed for use as an LVAD was performed to establish flow characteristics. A flow visualization technique using Amberlite particles suspended in a glycerin/water blood analogue was used. The system was illuminated with a 1 mm planar beam strobed helium-neon laser, and the results were recorded photographically. An analysis of photographs revealed laminar and turbulent flows with vortices within an illuminated plane in both the inlet and outlet port areas. From these data, velocity and shear stress profiles were generated that showed possible areas of improvement. It was concluded that the outlet port design could be improved by changing its angle and the continuity of its expansion. The inlet port could also be improved by smoothing the transition area between the inlet tube and the pump body to allow for gradual acceleration of the entering fluid.
