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- All Subjects: Microfabrication
- Creators: Meldrum, Deirdre R
Description
Within the last decade there has been remarkable interest in single-cell metabolic analysis as a key technology for understanding cellular heterogeneity, disease initiation, progression, and drug resistance. Technologies have been developed for oxygen consumption rate (OCR) measurements using various configurations of microfluidic devices. The technical challenges of current approaches include: (1) deposition of multiple sensors for multi-parameter metabolic measurements, e.g. oxygen, pH, etc.; (2) tedious and labor-intensive microwell array fabrication processes; (3) low yield of hermetic sealing between two rigid fused silica parts, even with a compliance layer of PDMS or Parylene-C. In this thesis, several improved microfabrication technologies are developed and demonstrated for analyzing multiple metabolic parameters from single cells, including (1) a modified "lid-on-top" configuration with a multiple sensor trapping (MST) lid which spatially confines multiple sensors to micro-pockets enclosed by lips for hermetic sealing of wells; (2) a multiple step photo-polymerization method for patterning three optical sensors (oxygen, pH and reference) on fused silica and on a polyethylene terephthalate (PET) surface; (3) a photo-polymerization method for patterning tri-color (oxygen, pH and reference) optical sensors on both fused silica and on the PET surface; (4) improved KMPR/SU-8 microfabrication protocols for fabricating microwell arrays that can withstand cell culture conditions. Implementation of these improved microfabrication methods should address the aforementioned challenges and provide a high throughput and multi-parameter single cell metabolic analysis platform.
ContributorsSong, Ganquan (Author) / Meldrum, Deirdre R (Thesis advisor) / Goryll, Michael (Committee member) / Wang, Hong (Committee member) / Tian, Yanqing (Committee member) / Arizona State University (Publisher)
Created2014
Description
Volumetric cell imaging using 3D optical Computed Tomography (cell CT) is advantageous for identification and characterization of cancer cells. Many diseases arise from genomic changes, some of which are manifest at the cellular level in cytostructural and protein expression (functional) features which can be resolved, captured and quantified in 3D far more sensitively and specifically than in traditional 2D microscopy. Live single cells were rotated about an axis perpendicular to the optical axis to facilitate data acquisition for functional live cell CT imaging. The goal of this thesis research was to optimize and characterize the microvortex rotation chip. Initial efforts concentrated on optimizing the microfabrication process in terms of time (6-8 hours v/s 12-16 hours), yield (100% v/s 40-60%) and ease of repeatability. This was done using a tilted exposure lithography technique, as opposed to the backside diffuser photolithography (BDPL) method used previously (Myers 2012) (Chang and Yoon 2004). The fabrication parameters for the earlier BDPL technique were also optimized so as to improve its reliability. A new, PDMS to PDMS demolding process (soft lithography) was implemented, greatly improving flexibility in terms of demolding and improving the yield to 100%, up from 20-40%. A new pump and flow sensor assembly was specified, tested, procured and set up, allowing for both pressure-control and flow-control (feedback-control) modes; all the while retaining the best features of a previous, purpose-built pump assembly. Pilot experiments were performed to obtain the flow rate regime required for cell rotation. These experiments also allowed for the determination of optimal trapezoidal neck widths (opening to the main flow channel) to be used for cell rotation characterization. The optimal optical trap forces were experimentally estimated in order to minimize the required optical power incident on the cell. Finally, the relationships between (main channel) flow rates and cell rotation rates were quantified for different trapezoidal chamber dimensions, and at predetermined constant values of laser trapping strengths, allowing for parametric characterization of the system.
ContributorsShetty, Rishabh M (Author) / Meldrum, Deirdre R (Thesis advisor) / Johnson, Roger H (Committee member) / Tillery, Stephen H (Committee member) / Arizona State University (Publisher)
Created2013