Droplet-based Biosensing for Lab-on-a-Chip, Open Microfluidics Platforms

Dak, Piyush; Ebrahimi, Aida; Swaminathan, Vikhram V.; Duarte-Guevara, Carlos; Bashir, Rashid; Alam, Muhammad Ashraful

doi:10.3390/bios6020014

Cited by 47 publications

(25 citation statements)

References 96 publications

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“…The model allows us to associate effective kinetic parameters of permeabilization in wildtype (WT) and heat-resistant (HR) cells and to demonstrate that the latter have a larger effective activation energy and consequently, a stronger cell envelope. The dropletbased impedance sensor is label-free (i.e., it does not use radioactive isotopes or fluorescent dyes) and can be miniaturized and integrated onto lab-on-a-chip platforms (20)(21)(22). In addition, supported by a physics-based quantitative model for the droplet impedance (23), we are able to tune the working frequency for optimum performance and characterize cells in the growth medium.…”

Section: Introductionmentioning

confidence: 99%

Analyzing Thermal Stability of Cell Membrane of Salmonella Using Time-Multiplexed Impedance Sensing

Ebrahimi

Csonka

Alam

2018

Biophysical Journal

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Heat treatment is one of the most widely used methods for inactivation of bacteria in food products. Heat-induced loss of bacterial viability has been variously attributed to protein denaturation, oxidative stress, or membrane leakage; indeed, it is likely to involve a combination of these processes. We examine the effect of mild heat stress (50-55°C for ≤12 min) on cell permeability by directly measuring the electrical conductance of samples of Salmonella enterica serovar Typhimurium to answer a fundamental biophysical question, namely, how bacteria die under mild heat stress. Our results show that when exposed to heat shock, the cell membrane is damaged and cells die mainly due to the leakage of small cytoplasmic species to the surrounding media without lysis (confirmed by fluorescent imaging). We measured the conductance change, ΔY, of wild-type versus genetically modified heat-resistant (HR) cells in response to pulse and ramp heating profiles with different thermal time constants. In addition, we developed a phenomenological model to correlate the membrane damage, cytoplasmic leakage, and cell viability. This model traces the differential viability and ΔY of wild-type and HR cells to the difference in the effective activation energies needed to permeabilize the cells, implying that HR cells are characterized by stronger lateral interactions between molecules, such as lipids, in their cell envelope.

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Section: Introductionmentioning

confidence: 99%

Analyzing Thermal Stability of Cell Membrane of Salmonella Using Time-Multiplexed Impedance Sensing

Ebrahimi

Csonka

Alam

2018

Biophysical Journal

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“…Droplet-based microfluidics are also an ideal integration platform for applications requiring high-throughput analysis [64]. These systems offer the unique advantages of automated Another multiplexed integrated label-free DNA detection platform was proposed by including two functional modules, i.e., a multiplexed PCR module for amplification of nucleic acid targets, and a multiplexed silicon nanowire (SiNW) module for sequence determination [61].…”

Section: Higher Integration Platformsmentioning

confidence: 99%

“…The introduction of solid state nanopores also allowed more versatility in their fabrication, enabling variable but controlled diameters and geometries, even in sub-nanometer resolutions. Droplet-based microfluidics are also an ideal integration platform for applications requiring high-throughput analysis [64]. These systems offer the unique advantages of automated compartmentalization of reagents in multiple picoliter volume drops, along with the possibility to perform in a programmable way, multiple combinations of reagents rapidly.…”

Section: Nanopore Technology For Label-free Dna Sequencingmentioning

confidence: 99%

Microfluidic Devices for Label-Free DNA Detection

et al. 2018

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Sensitive and specific DNA biomarker detection is critical for accurately diagnosing a broad range of clinical conditions. However, the incorporation of such biosensing structures in integrated microfluidic devices is often complicated by the need for an additional labelling step to be implemented on the device. In this review we focused on presenting recent advances in label-free DNA biosensor technology, with a particular focus on microfluidic integrated devices. The key biosensing approaches miniaturized in flow-cell structures were presented, followed by more sophisticated microfluidic devices and higher integration examples in the literature. The option of full DNA sequencing on microfluidic chips via nanopore technology was highlighted, along with current developments in the commercialization of microfluidic, label-free DNA detection devices.

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“…Many lab-on-a-chip (LoC) applications have become possible thanks to the ability to control mixing of different droplet contents, which enabled the sequencing of many complex bio-chemical and biological reactions with a high level of control and flexibility over the last decade; see for a review [1][2][3][4][5][6][7]. Hence, among all manipulation schemes allowed by droplet-based microfluidics technology [8][9][10][11][12][13][14][15][16], active merging of microdroplets (AMD) is probably one of the most important. It is generally achieved using a high alternating current (AC) voltage [17], or using a direct current (DC) voltage [18].…”

Section: Introductionmentioning

confidence: 99%

Fast Active Merging of Microdroplets in Microfluidic Chambers Driven by Photo-Isomerisation of Azobenzene Based Surfactants

et al. 2019

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In this work, we report on the development of a newly synthesized photoactive reversible azobenzene derived surfactant polymer, which enables active and fast control of the merging of microdroplets in microfluidic chambers, driven by a pulsed UV laser optical stimulus and the well known cis-trans photo-isomerisation of azobenzene groups. We show for the first time that merging of microdroplets can be achieved optically based on a photo-isomerization process with a high spatio-temporal resolution. Our results show that the physical process lying behind the merging of microdroplets is not driven by a change in surface activity of the droplet stabilizing surfactant under UV illumination (as originally expected), and they suggest an original mechanism for the merging of droplets based on the well-known opto-mechanical motion of azobenzene molecules triggered by light irradiation.

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Droplet-based Biosensing for Lab-on-a-Chip, Open Microfluidics Platforms

Cited by 47 publications

References 96 publications

Analyzing Thermal Stability of Cell Membrane of Salmonella Using Time-Multiplexed Impedance Sensing

Analyzing Thermal Stability of Cell Membrane of Salmonella Using Time-Multiplexed Impedance Sensing

Microfluidic Devices for Label-Free DNA Detection

Fast Active Merging of Microdroplets in Microfluidic Chambers Driven by Photo-Isomerisation of Azobenzene Based Surfactants

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