Microfluidic array cytometer based on refractive optical tweezers for parallel trapping, imaging and sorting of individual cells

Analysis of genetic and functional variability in populations of living cells requires experimental techniques capable of monitoring cellular processes such as cell signaling of many single cells in parallel while offering the possibility to sort interesting cell phenotypes for further investigations. Although flow cytometry is able to sequentially probe and sort thousands of cells per second, dynamic processes cannot be experimentally accessed on single cells due to the sub-second sampling time. Cellular dynamics can be measured by image cytometry of surface-immobilized cells, however, cell sorting is complicated under these conditions due to cell attachment. We here developed a cytometric tool based on refractive multiple optical tweezers combined with microfluidics and optical microscopy. We demonstrate contact-free immobilization of more than 200 yeast cells into a high-density array of optical traps in a microfluidic chip. The cell array could be moved to specific locations of the chip enabling us to expose in a controlled manner the cells to reagents and to analyze the responses of individual cells in a highly parallel format using fluorescence microscopy. We further established a method to sort single cells within the microfluidic device using an additional steerable optical trap. Ratiometric fluorescence imaging of intracellular pH of trapped yeast cells allowed us on the one hand to measure the effect of the trapping laser on the cells' viability and on the other hand to probe the dynamic response of the cells upon glucose sensing.

Optical Trapping in Microfluidic Channels for Functional and Chemical Analysis of Single Cells

Michael Werner

The physiological properties of cells are typically investigated in ensembles yielding averaged data that mask heterogeneities present in any cell population. Single-cell analysis techniques based on microfluidic "lab on a chip" (LOC) devices have recently led to new insights into cellular physiology revealing the biological importance of cell variability. However, we are only at the beginning of understanding the complex nature of cellular constitution and function. Similarly is the study of individual cells in LOC devices a new field requiring further development. The aim of this thesis is to develop novel methods for functional and chemical single-cell analysis in controlled microfluidic environments using optical trapping for cell manipulation. Investigation of cellular function requires experimental techniques allowing us to monitor cell-to-cell variability of the response of a cell population to external stimuli and to sort out interesting cell phenotypes for further investigation. Although flow cytometry is able to sequentially probe and sort thousands of cells per second, dynamic processes cannot be experimentally accessed on single cells due to the sub-second sampling time. Cellular dynamics can be measured by image cytometry of surface-immobilized cells, however, cell sorting is complicated under these conditions. Here, we developed a cytometric tool based on refractive multiple optical tweezers combined with microfluidics and optical microscopy. We demonstrate contact-free immobilization of more than 200 yeast cells into a high-density array of optical traps in a microfluidic chip. The cell array could be moved to specific locations of the chip enabling us to expose in a controlled manner the cells to reagents and to analyze the responses of individual cells in a highly parallel format using fluorescence microscopy. We further established a method to sort single cells within the microfluidic device using an additional steerable optical trap. Observed dose-dependent cytotoxic effects of the trapping laser on the cells' viability imposed an upper limit to the time periods during which optically trapped cells could be studied. For assays involving monitoring of cellular dynamics over several hours or days, we immobilized cell arrays formed by refractive optical tweezers in a hydrogel-matrix confined to a microfluidic chamber of 15 nL volume. We demonstrated multiplexing of this concept by integrating several chambers adjacent to each other in the same microfluidic device. In fluidic contact, each chamber could be exposed to a different reagent. Chemical single-cell analysis deals with identification and quantification of intracellular chemical species. Here, we report an alternative method for chemical cytometry using micro-beads functionalised with capture agents as intracellular affinity probe. Cell internalization of the beads followed by induced endosomal escape leads to binding of the target analyte to the surface of the beads. Using optical trapping with microfluidics, we demonstrate fast extraction of the beads from the cells and detection of bound target analyte under preservation of the single-cell analytics. In contrast to classical chemical cytometry, our method has the potential to reach high analytical sensitivity at simultaneously reasonable throughput.

EPFL2011

Micro-optics for multiple laser trapping in microfluidics

Fabrice Merenda

Optical trapping allows manipulating very small objects – varying from Angstöms to micron size particles – without physical contact by taking advantage of laser light. This technique, relying on light momentum transfer, allows manipulating biological matter (such as cells, organelles, vesicles or chemically functionalized artificial particles, etc.) and offers promising potentialities for research in biotechnology and biochemistry. Individually confining a large number of microscopic objects opens new ways for the downscaling of analysis tools for drug screening, particles sorting and the assessment of statistical data. In particular, the combination of optical trapping with microfluidics greatly enlarges the possibilities offered by both techniques. This PhD work takes place in a research aiming at developing novel bio-analytical instrumentation relying on large arrays of optical traps compatible with microfluidic systems. The dissertation focuses on the use of micro-optics for generating extended matrices of three-dimensional optical traps capable of capturing a large number of particles within microfluidic environments. The stability of optical traps is first studied with special emphasis on the conditions present in microfluidic flows, both from a theoretical and an experimental point of view, and trapping forces achievable on biological cells are investigated. A multiple optical trapping system relying on microlens arrays, adapted to work on commercial microscopes, is shown to be capable of generating arrays of more than 500 three-dimensional traps. Simultaneously trapping in multiple planes is also evidenced using matrices of microlenses, thanks to a self-imaging effect of the array of traps. Furthermore, possibilities offered by multiple optical trapping within microfluidic environments are explored. Polystyrene spheres as well as biological particles, such as native vesicles, can be trapped in arrays, manipulated inside microfluidic devices and analyzed in parallel through fluorescence microscopy while extremely small quantities of chemical reagents are flown past the array. Finally, for the sake of system miniaturization and further extension of the number of traps, multiple three-dimensional optical trapping based on arrays of miniaturized high numerical aperture parabolic mirrors is proposed, allowing the optics necessary for optical trapping, fluorescence excitation and collection to be integrated at the level of a microfluidic chip. Such miniaturized mirror matrices did not even exist before this thesis; their fabrication and characterization are detailed in this dissertation.

EPFL2008

Miniaturized bioanalytics to probe the function of membrane proteins

Pedro Pascoal

G-protein coupled receptors (GPCRs) are the most abundant class of proteins in the cell body. Such receptors are of major interest as potential therapeutic targets. Downscaling and parallelization of bioanalytics opens novel routes to rapidly screen and identify potential drugs with a decrease in regard to the costs, and elucidate novel functions of signaling networks under physiological conditions. Native vesicles are small autonomous biological containers, which are efficiently produced from all cell lines. They are composed of their mother cell plasma membrane and enclose part of their cytoplasm. Membrane receptors are then exposed at their surface and already demonstrate to induce cellular signaling when exposed to receptor ligands. Native vesicles were investigated in this present work, as novel possibilities to downscale receptor investigation in live cells, using neurokinin 1 receptor (NK1R) as a representative model. Here native vesicle production and purification was optimized. The influence of the cell cycle on the production efficiency was demonstrated. Biological proteins were downregulated in order to produce blebbing cells. Native vesicle characterization was achieved. The receptors also demonstrate to be efficiently labeled by agonist and antagonist, allowing to access information about the binding kinetics as well as KD values. The results are in agreement with those obtained in live cells. Native vesicles also demonstrate to internalize agonist after application, demonstrating receptor desensitization and signaling performance similar as live cells. Confocal microscopy shows that cells expressing the NK1R-CFP have two binding affinities for their main agonist, substance P. Similar results could be observed with flow cytometry. The high affinity binding is related to cholesterol content in the cell membrane and was abolished by cholesterol depletion with methyl-β-cyclodextrin. Micro-contact printing (µCP) was used to (bio)functionalize surfaces with proteins, polymers or functionalized nanoparticles. Precise sample positioning by micro-contact printing shows improves nuclear magnetic resonance excitation and detection, when performed with a planar microcoil probe. µCP was used to produce native vesicle arrays by two procedures, and fluorescent binding assay shows the binding of fluorescent ligands to the receptor. Laser tweezers allow manipulating cell membranes without requiring the use of polystyrene beads. From pulled membranes, native vesicles were produced. In addition from pulled membranes, large tethers were produced and artificial connections were established with neighboring cells. Intercellular communication was investigated by whole-cell patch clamp in dissociated primary dorsal root ganglion neurons after optical induced connection, as well as in HEK cells expressing Cx36. The lab-on-chip assay development demonstrates: the high production of native vesicles in microchannels; the efficient purification obtained by negative dielectrophoresis depletion in MEMS chips; perfect trapping and thus immobilization of native vesicles in a new optical multi-tweezer array. Fluorescence labeling was performed with native vesicles trapped in a multi-tweezer array inside microfluidic channel in the presence of two laminar flows. Optical multi-tweezer array setup shows to be the fastest and more efficient technique in order to perform immobilization and labeling of native vesicles in the microfluidic channel. It is presently the only technique to perform fluorescence measurements when maintaining objects trapped.

EPFL2008

Optical Trapping in Microfluidic Channels for Functional and Chemical Analysis of Single Cells

Michael Werner

EPFL2011

Micro-optics for multiple laser trapping in microfluidics

Fabrice Merenda

EPFL2008

Miniaturized bioanalytics to probe the function of membrane proteins

Pedro Pascoal

EPFL2008