Fluorescent magnetic bead and cell differentiation/counting using a CMOS SPAD matrix

We present a monolithic silicon chip comprising a matrix of 84 single photon avalanche diodes (SPADs) to detect and discriminate fluorescent beads or fluorescently labeled single cells in a polydimethyl(-siloxane) (PDMS) cartridge that is positioned on top of the chip. Our detection is based on the different photon count when either a fluorescent or non-fluorescent bead or cell is present above a SPAD, due to the additional photons emitted from a fluorescent object. Our technique allows microscope-less fluorescence detection and permits easy exchange of the disposable microfluidic cartridge. We first demonstrate the working principle of our device by counting and discriminating fluorescent from non-fluorescent 3, 6 and 10 μm magnetic beads, which are commonly used as versatile mobile carriers for separating a target analyte from a matrix via magnetic forces in microfluidic lab-on-a-chip systems. We then apply our system to count and discriminate fluorescently-labeled MCF-7 breast cancer cells from unlabeled Jurkat cells mixed in a phosphate buffer saline (PBS) solution. Our device is robust and does not need complex microfluidic handling to achieve cell count without the need of external fluorescence detection bulky equipment.

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Edoardo Charbon, Emile Dupont, Martinus Gijs, Ulrike Lehmann, Caroline Vandevyver
Elsevier, 2012
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https://infoscience.epfl.ch/record/182211?ln=en

About this result

Related concepts (13)

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Related publications (12)

Related publications

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Optofluidic nanoplasmonic biosensor for label-free live cell analysis in real time

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Cell signaling activities play a critical role in physiological and disease processes. The analysis of the tumor microenvironment or the immune system activation is nowadays providing valuable insights towards disease understanding and novel therapies development. Due to the various dynamic profiles, it is essential to implement a continuous monitoring methodology for accurate analysis. The current fluorescent and colorimetric approaches hinder such applications due to their multiple time-consuming steps, molecular labeling, and the ‘snapshot’ endpoint readouts. Photonics technology, and especially nanoplasmonic biosensors offer a unique opportunity to implement lab-on-a-chip systems that provide highly sensitive and label-free analysis of cell signaling events in real time. Here, we will present a microfluidics-integrated nanoplasmonic biosensor for long-term and real-time monitoring of cell secretion activity. The biosensor consists of a gold nanohole array supporting extraordinary optical transmission (EOT), which has been optimized to enable ultra-sensitive and high-throughput biomolecular detection. The nanobiosensor is integrated with a specifically designed microfluidic system that provides well-controlled cell culture conditions for long-term monitoring. We achieved an outstanding sensitivity for the detection of vascular endothelial growth factor (VEGF) directly secreted from microfluidic-cultured cancer cells. We demonstrated real-time monitoring for over 10 hours, preserving good cell viability. The multiplexing capability of our nanobiosensor could enable simultaneous analysis of different cell types and molecules-of-interest. Thus, our innovative approach of probing live cells can be a powerful tool to evaluate cellular activities for diagnostics and novel therapy development.

2018

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Here we present the realization of a novel fluorescence detection method based on the electromigration of fluorescent molecules within a nanocapillary combined with the laser excitation through a platinum (Pt)-coated nanocapillary. By using the Pt nanocapillary assisted focusing of a laser beam, we completely remove the background scattering on the tip of the electrophoretic nanocapillary. In this excitation geometry, we demonstrate a 1000-fold sensitivity enhancement (1.0 nM to 1.0 pM) compared to the detection in microcapillaries with epifluorescence illumination and fluorescence spectrophotometry. Due to a significant electroosmotic flow, we observe a decelerating migration of DNA molecules close to the tip of the electrophoretic nanocapillary. The reduced DNA translocation velocity causes a two-step stacking process of molecules in the tip of the nanocapillary and can be used as a way to locally concentrate molecules. The sensitivity of our method is further improved by a continuous electrokinetic injection of DNA molecules followed by sample zone stacking on the tip of the nanocapillary. Concentrations ranging from 0.1 pM to 1.0 fM can be directly observed on the orifice of the electrophoretic nanocapillary. This is a 1000-fold improvement compared to traditional capillary electrophoresis with laser-induced fluorescence.

2018