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Integrated Microfluidic Optical Manipulation Technique: Towards High Throughput Single Cell AnalysisCharron, Luc 20 August 2012 (has links)
An all-optical micromanipulation technique is presented in the framework of precise cell selection within a cell culture and multiplexed transport capabilities for microfluidic single cell analysis applications. The technique was developed by combining an optical tweezer setup with a novel integrated waveguide cell propulsion method referred to as end-face waveguide propulsion (EFWP). The EFWP technique delivers optical forces to a particle generating thrust. The thesis is divided into two sections: simulation and experimental validation. In the first section a new simulation technique based on ray optics theory (ROT) and the beam propagation method (BPM) is used to predict particle velocity and trajectory along a microfluidic propagation channel. In this work, the ROT-BPM technique is used to analyse and optimize the waveguide geometry to maximize particle velocity. Analysis of the impact of common microchip manufacturing limitations on velocity is performed to determine acceptable fabrication process tolerances. The second section presents experimental results of polymer microspheres and acute myeloid leukemia (AML) cells as biological targets. The experimental results are compared with simulations performed in the first section. Correction factors are added to the simulations to reflect the experimental device parameters. Thermal e_ects due to photon absorption within the fluidic channels are also investigated and corrected for. The final analysis indicates that the ROT-BPM technique developed in this work can be used to adequately predict particle velocity and trajectory path. EFWP currently delivers the fastest particle velocities compared to other optical micromanipulation techniques currently available in microfluidic applications. While the technique is focused on addressing chemical cytometry precise particle selectivity and high throughput needs, EFWP can also be used in many other single cell applications.
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Integrated Microfluidic Optical Manipulation Technique: Towards High Throughput Single Cell AnalysisCharron, Luc 20 August 2012 (has links)
An all-optical micromanipulation technique is presented in the framework of precise cell selection within a cell culture and multiplexed transport capabilities for microfluidic single cell analysis applications. The technique was developed by combining an optical tweezer setup with a novel integrated waveguide cell propulsion method referred to as end-face waveguide propulsion (EFWP). The EFWP technique delivers optical forces to a particle generating thrust. The thesis is divided into two sections: simulation and experimental validation. In the first section a new simulation technique based on ray optics theory (ROT) and the beam propagation method (BPM) is used to predict particle velocity and trajectory along a microfluidic propagation channel. In this work, the ROT-BPM technique is used to analyse and optimize the waveguide geometry to maximize particle velocity. Analysis of the impact of common microchip manufacturing limitations on velocity is performed to determine acceptable fabrication process tolerances. The second section presents experimental results of polymer microspheres and acute myeloid leukemia (AML) cells as biological targets. The experimental results are compared with simulations performed in the first section. Correction factors are added to the simulations to reflect the experimental device parameters. Thermal e_ects due to photon absorption within the fluidic channels are also investigated and corrected for. The final analysis indicates that the ROT-BPM technique developed in this work can be used to adequately predict particle velocity and trajectory path. EFWP currently delivers the fastest particle velocities compared to other optical micromanipulation techniques currently available in microfluidic applications. While the technique is focused on addressing chemical cytometry precise particle selectivity and high throughput needs, EFWP can also be used in many other single cell applications.
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