Tracking Cancer Cells with Microfluidic High Frequency DEP Cytometer Implemented on BiCMOS Lab-on-Chip Platform

Cell motility is the brilliant result of cell status and its interaction with close environments. Its detection is now possible, thanks to the synergy of high-resolution camera sensors, time-lapse microscopy devices, and dedicated software tools for video and data analysis. In this scenario, we formulated a novel paradigm in which we considered the individual cells as a sort of sensitive element of a sensor, which exploits the camera as a transducer returning the movement of the cell as an output signal. In this way, cell movement allows us to retrieve information about the chemical composition of the close environment. To optimally exploit this information, in this work, we introduce a new setting, in which a cell trajectory is divided into sub-tracks, each one characterized by a specific motion kind. Hence, we considered all the sub-tracks of the single-cell trajectory as the signals of a virtual array of cell motility-based sensors. The kinematics of each sub-track is quantified and used for a classification task. To investigate the potential of the proposed approach, we have compared the achieved performances with those obtained by using a single-trajectory paradigm with the scope to evaluate the chemotherapy treatment effects on prostate cancer cells. Novel pattern recognition algorithms have been applied to the descriptors extracted at a sub-track level by implementing features, as well as samples selection (a good teacher learning approach) for model construction. The experimental results have put in evidence that the performances are higher when a further cluster majority role has been considered, by emulating a sort of sensor fusion procedure. All of these results highlighted the high strength of the proposed approach, and straightforwardly prefigure its use in lab-on-chip or organ-on-chip applications, where the cell motility analysis can be massively applied using time-lapse microscopy images.

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Optimization of high Frequency 45̊ Acoustic Mirrors for Lab on Chip Applications

Physics Procedia ◽

10.1016/j.phpro.2015.08.190 ◽

2015 ◽

Vol 70 ◽

pp. 918-922 ◽

Cited By ~ 1

Author(s):

S. Li ◽

J. Carlier ◽

F. Lefebvre ◽

P. Campistron ◽

D. Callens ◽

...

Keyword(s):

High Frequency ◽

Lab On Chip ◽

On Chip

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Lab-on-Chip Platform for Culturing and Dynamic Evaluation of Cells Development

Micromachines ◽

10.3390/mi11020196 ◽

2020 ◽

Vol 11 (2) ◽

pp. 196

Author(s):

Agnieszka Podwin ◽

Danylo Lizanets ◽

Dawid Przystupski ◽

Wojciech Kubicki ◽

Patrycja Śniadek ◽

...

Keyword(s):

Population Growth ◽

Cancer Cells ◽

High Mobility ◽

Fold Increase ◽

Behavioral Analysis ◽

Aquatic Habitats ◽

Migration Activity ◽

Lab On Chip ◽

On Chip

This paper presents a full-featured microfluidic platform ensuring long-term culturing and behavioral analysis of the radically different biological micro-objects. The platform uses all-glass lab-chips and MEMS-based components providing dedicated micro-aquatic habitats for the cells, as well as their intentional disturbances on-chip. Specially developed software was implemented to characterize the micro-objects metrologically in terms of population growth and cells’ size, shape, or migration activity. To date, the platform has been successfully applied for the culturing of freshwater microorganisms, fungi, cancer cells, and animal oocytes, showing their notable population growth, high mobility, and taxis mechanisms. For instance, circa 100% expansion of porcine oocytes cells, as well as nearly five-fold increase in E. gracilis population, has been achieved. These results are a good base to conduct further research on the platform versatile applications.

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Micro-Drop Mixer Driven by Standing Surface Acoustic Waves (SSAW)

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.629.521 ◽

2012 ◽

Vol 629 ◽

pp. 521-523

Author(s):

Bao Gang Miao ◽

Chao Hui Wang ◽

Teng Fei Zheng ◽

Qun Ming Zhang ◽

Zhuang De Jiang

Keyword(s):

Lithium Niobate ◽

Single Crystal ◽

Surface Waves ◽

Acoustic Waves ◽

High Frequency ◽

Surface Acoustic Waves ◽

Mixing Process ◽

Lab On Chip ◽

Digital Transducers ◽

On Chip

High-frequency surface acoustic waves (SAW) were generated and transmitted along single-crystal lithium niobate (LiNbO3). The standing surface waves (SSAW) formed between two parallel inter-digital transducers (IDTs) on a LiNbO3 substrate, were employed to drive the micro-drop mixer. An SSAW device was designed, micro-machined and tested. When an AC signal with the frequency of 61.4MHz was applied to the IDTs, vortex appeared in the drop consisted of two incompatible liquid (ink and glycerol). The evolution of the vortex was recorded in this work. With the evolution of the vortex, mixing process of two incompatible liquid has been demonstrated. The mixer is of significant relevance for many bio-technological applications and in particular for lab-on-chip. While the experimental liquids were mutually incompatible, the ink could only be divided into smaller drops.

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Salt Precipitation During Injection of CO2 into Saline Aquifers: Lab-on-Chip Experiments on Glass and Geomaterial Microfluidic Specimens

SSRN Electronic Journal ◽

10.2139/ssrn.3365553 ◽

2019 ◽

Author(s):

Mohammad Nooraiepour ◽

Hossein Fazeli ◽

Rohaldin Miri ◽

Helge Hellevang

Keyword(s):

Saline Aquifers ◽

Salt Precipitation ◽

Lab On Chip ◽

On Chip

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A Lab‐On‐chip Tool for Rapid, Quantitative, and Stage‐selective Diagnosis of Malaria

Advanced Science ◽

10.1002/advs.202004101 ◽

2021 ◽

pp. 2004101

Author(s):

Marco Giacometti ◽

Francesca Milesi ◽

Pietro Lorenzo Coppadoro ◽

Alberto Rizzo ◽

Federico Fagiani ◽

...

Keyword(s):

Lab On Chip ◽

On Chip

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Integrated Magnetohydrodynamic Pump with Magnetic Composite Substrate and Laser-Induced Graphene Electrodes

Polymers ◽

10.3390/polym13071113 ◽

2021 ◽

Vol 13 (7) ◽

pp. 1113

Author(s):

Mohammed Asadullah Khan ◽

Jürgen Kosel

Keyword(s):

Magnetic Flux ◽

Flow Rate ◽

Magnetic Composite ◽

Propulsive Force ◽

Closed Channel ◽

Lab On Chip ◽

Composite Substrate ◽

On Chip ◽

High Level ◽

Moving Parts

An integrated polymer-based magnetohydrodynamic (MHD) pump that can actuate saline fluids in closed-channel devices is presented. MHD pumps are attractive for lab-on-chip applications, due to their ability to provide high propulsive force without any moving parts. Unlike other MHD devices, a high level of integration is demonstrated by incorporating both laser-induced graphene (LIG) electrodes as well as a NdFeB magnetic-flux source in the NdFeB-polydimethylsiloxane permanent magnetic composite substrate. The effects of transferring the LIG film from polyimide to the magnetic composite substrate were studied. Operation of the integrated magneto hydrodynamic pump without disruptive bubbles was achieved. In the studied case, the pump produces a flow rate of 28.1 µL/min. while consuming ~1 mW power.

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Towards lab-on-chip ultrasensitive ethanol detection using photonic crystal waveguide operating in the mid infrared

Nanophotonics ◽

10.1515/nanoph-2020-0576 ◽

2021 ◽

Vol 0 (0) ◽

Author(s):

Ali Rostamian ◽

Ehsan Madadi-Kandjani ◽

Hamed Dalir ◽

Volker J. Sorger ◽

Ray T. Chen

Keyword(s):

Photonic Crystal ◽

Slow Light ◽

High Sensitivity ◽

Guided Wave ◽

Silicon On Insulator ◽

Group Index ◽

Photonic Crystal Waveguide ◽

Mid Infrared ◽

Lab On Chip ◽

On Chip

Abstract Thanks to the unique molecular fingerprints in the mid-infrared spectral region, absorption spectroscopy in this regime has attracted widespread attention in recent years. Contrary to commercially available infrared spectrometers, which are limited by being bulky and cost-intensive, laboratory-on-chip infrared spectrometers can offer sensor advancements including raw sensing performance in addition to use such as enhanced portability. Several platforms have been proposed in the past for on-chip ethanol detection. However, selective sensing with high sensitivity at room temperature has remained a challenge. Here, we experimentally demonstrate an on-chip ethyl alcohol sensor based on a holey photonic crystal waveguide on silicon on insulator-based photonics sensing platform offering an enhanced photoabsorption thus improving sensitivity. This is achieved by designing and engineering an optical slow-light mode with a high group-index of n g = 73 and a strong localization of modal power in analyte, enabled by the photonic crystal waveguide structure. This approach includes a codesign paradigm that uniquely features an increased effective path length traversed by the guided wave through the to-be-sensed gas analyte. This PIC-based lab-on-chip sensor is exemplary, spectrally designed to operate at the center wavelength of 3.4 μm to match the peak absorbance for ethanol. However, the slow-light enhancement concept is universal offering to cover a wide design-window and spectral ranges towards sensing a plurality of gas species. Using the holey photonic crystal waveguide, we demonstrate the capability of achieving parts per billion levels of gas detection precision. High sensitivity combined with tailorable spectral range along with a compact form-factor enables a new class of portable photonic sensor platforms when combined with integrated with quantum cascade laser and detectors.

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