A Microfluidic-based Electrochemical Biochip for Label-free DNA Hybridization Analysis

Ben‐Yoav, Hadar; Dykstra, Peter; Gordonov, Tanya; Bentley, William E.; Ghodssi, Reza

doi:10.3791/51797

Cited by 5 publications

(3 citation statements)

References 39 publications

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“…2 These devices employ low sample volumes, make available fast reaction rates because of the smaller diffusion distances, are easy to fabricate, and can include integrated sensors to provide label-free analysis. 3,4 Devices, with channels of the size of tens of microns, are being developed for use in a variety of applications such as enzymatic analysis, 5,6 DNA analysis, 7 proteomics analysis, 8 and nanoparticle fabrication. 9 Rapid advances in nanotechnologies have given thrust to the development and conception of microfluidic biosensors for health-care applications such as immunoassays.…”

Section: ■ Introductionmentioning

confidence: 99%

Numerical Study of the Electrothermal Effect on the Kinetic Reaction of Immunoassays for a Microfluidic Biosensor

2016

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In this work, we simulate the binding reaction of C-reactive protein in a microchannel of a biosensor. A problem that arises in this device concerns the transport of the analyte toward the reaction surface of the biosensor, which is of a very small dimension. The limitation of mass transport causes the formation of a diffusion boundary layer and restrains the whole kinetic reaction. To enhance the performance of the biosensor by improving the transport, an applied AC electric field and flow confinement are used to stir the flow field. The numerical simulation of these mechanisms on the binding reaction is performed using the finite element method. Swirling patterns are generated in the fluid. They enhance the transport of the analyte and confine it near the reaction surface. The location of the electrode pair on the walls of the microchannel for the design of the biosensor has been studied to find out the effects of varying geometric configurations on the binding efficiency. The best performances of the biosensor are obtained when the electrodes are placed on the same wall of the microchannel as the reaction surface. For the best case, under the effect of the applied electric field alone, the enhancement factors raise up to 2.46 and 2.10 for the association and dissociation phases, respectively. By contrast, under the effect of the electric field with flow confinement, the enhancement factors for the association and the dissociation phases jump to 3.43 and 2.97, respectively, for 30:1 flow confinement (ratio of confining to sample flow).

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Section: ■ Introductionmentioning

confidence: 99%

Numerical Study of the Electrothermal Effect on the Kinetic Reaction of Immunoassays for a Microfluidic Biosensor

2016

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“…A detailed video about the fabrication and testing methods of DNA hybridization detection can be seen in [12]. …”

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confidence: 99%

Microfluidic Arrayed Lab-On-A-Chip for Electrochemical Capacitive Detection of DNA Hybridization Events

Ben‐Yoav

Dykstra

Bentley

et al. 2017

Biosensors and Biodetection

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A microfluidic electrochemical lab-on-a-chip (LOC) device for DNA hybridization detection has been developed. The device comprises a 3 × 3 array of microelectrodes integrated with a dual layer microfluidic valved manipulation system that provides controlled and automated capabilities for high throughput analysis of microliter volume samples. The surface of the microelectrodes is functionalized with single-stranded DNA (ssDNA) probes which enable specific detection of complementary ssDNA targets. These targets are detected by a capacitive technique which measures dielectric variation at the microelectrode-electrolyte interface due to DNA hybridization events. A quantitative analysis of the hybridization events is carried out based on a sensing modeling that includes detailed analysis of energy storage and dissipation components. By calculating these components during hybridization events the device is able to demonstrate specific and dose response sensing characteristics. The developed microfluidic LOC for DNA hybridization detection offers a technology for real-time and label-free assessment of genetic markers outside of laboratory settings, such as at the point-of-care or in-field environmental monitoring.

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“…This partial miniaturization can be due to the difficulty in maintaining the functionality of constructed electrodes, especially for the reference electrodes such as silver, during fabrication of the sensor. On the other hand, although the miniaturized systems were well suited for research applications, the majority of them either did not have microchannels to direct the flow of the sample through the electrodes [7], [8], or had microchannels made of materials (e.g., PDMS or polyester foil) that are not compatible with the standard fabrication processes for high-throughput applications [4], [9]. However, utilization of fully integrated microfluidic platforms is especially necessary for the applications of clinical microbiology and homeland security.…”

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confidence: 99%

A Fully Microfabricated Electrochemical Sensor and its Implementation for Detection of Methicillin Resistance in <italic>Staphylococcus Aureus</italic>

et al. 2014

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On-chip detection of biological analytes can enable diagnosis at the point of care. Combining the advantages of microelectromechanical system (MEMS) technology and molecular methods, we present the design of an integrated microfluidic platform, a microelectrochemical sensor (µECS), and its implementation for the detection of methicillin resistance in Staphylococcus aureus. This platform is capable of electrochemically sensing the target analyte in a microfluidic reactor without the usage of bulky electrodes, rendering it useful for in vitro diagnostics. In our experiments, the functionality of the sensor was tested for detecting specific DNA sequences of mecA gene (an indicator of methicillin resistance) over a range of concentrations of DNA (down to 10 pM). Synthetic oligonucleotides and bacterial PCR product were used as a target analyte in Hoechst 33258 marker-based detection and horseradish peroxidase-based detection, respectively. The results revealed that this platform has high sensitivity and selectivity. Also, its compatibility to MEMS processes enables its use with different applications ranging from detecting various types of cancers to endemics. The designed µECS can enable the detection of biological analytes of interest at low cost and high throughput.

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A Microfluidic-based Electrochemical Biochip for Label-free DNA Hybridization Analysis

Cited by 5 publications

References 39 publications

Numerical Study of the Electrothermal Effect on the Kinetic Reaction of Immunoassays for a Microfluidic Biosensor

Numerical Study of the Electrothermal Effect on the Kinetic Reaction of Immunoassays for a Microfluidic Biosensor

Microfluidic Arrayed Lab-On-A-Chip for Electrochemical Capacitive Detection of DNA Hybridization Events

A Fully Microfabricated Electrochemical Sensor and its Implementation for Detection of Methicillin Resistance in <italic>Staphylococcus Aureus</italic>

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