D. Brassard scite author profile

Single-phase vanadium dioxide (VO2) thin films have been grown on Si3N4∕Si substrates by means of a well-controlled magnetron sputtering process. The deposited VO2 films were found to exhibit a semiconductor-to-metal transition (SMT) at ∼69°C with a resistivity change as high as 3.2 decades. A direct and clear-cut correlation is established between the SMT characteristics (both amplitude and abruptness of the transition) of the VO2 films and their crystallite size.

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Phase diagram of the ultrafast photoinduced insulator-metal transition in vanadium dioxide

Cocker

et al. 2012

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Integration and detection of biochemical assays in digital microfluidic LOC devices

et al. 2010

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The ambition of lab-on-a-chip (LOC) systems to achieve chip-level integration of a complete analytical process capable of performing a complex set of biomedical protocols is hindered by the absence of standard fluidic components able to be assembled. As a result, most microfluidic platforms built to date are highly specialized and designed to fulfill the requirements of a single particular application within a limited set of operations. Electrowetting-on-dielectric (EWOD) digital microfluidic technology has been recently introduced as a new methodology in the quest for LOC systems. Herein, unit volume droplets are manipulated along electrode arrays, allowing a microfluidic function to be reduced to a set of basic operations. The highly reprogrammable architecture of these systems can satisfy the needs of a diverse set of biochemical assays and ensure reconfigurability, flexibility and portability between different categories of applications and requirements. While important progress was made over past years in the fabrication, miniaturization and function programming of the basic EWOD fluidic operations, the success of this technology will in great part depend on the ability of researchers to couple or integrate digital microfluidics to detection approaches that can make the system competitive for LOC applications. The detection techniques should be able to circumvent the limitations of hydrophobic surfaces and exploit the advantages of the array format, high droplet transport speeds and rapid mixing schemes. This review provides an in-depth look at recent developments for the coupling and integration of detection techniques with digital microfluidic platforms for bio-chemical applications.

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Enhanced Photosusceptibility nearTcfor the Light-Induced Insulator-to-Metal Phase Transition in Vanadium Dioxide

et al. 2007

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We use optical-pump terahertz-probe spectroscopy to investigate the near-threshold behavior of the photoinduced insulator-to-metal (IM) transition in vanadium dioxide thin films. Upon approaching Tc a reduction in the fluence required to drive the IM transition is observed, consistent with a softening of the insulating state due to an increasing metallic volume fraction (below the percolation limit). This phase coexistence facilitates the growth of a homogeneous metallic conducting phase following superheating via photoexcitation. A simple dynamic model using Bruggeman effective medium theory describes the observed initial condition sensitivity.

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Terahertz conductivity of the metal-insulator transition in a nanogranular VO2 film

Cocker

Titova

Fourmaux

et al. 2010

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Terahertz time-domain spectroscopy is used to measure the complex terahertz conductivity of a nanogranular vanadium dioxide (VO2) thin film as a function of temperature through the metal-insulator transition. The Drude–Smith model provides a good fit to the observed terahertz conductivity, revealing a metallic state that forms via switching of individual nanograins and strong carrier confinement within the nanograins due to scattering off grain boundaries. Furthermore, the directly applied Drude–Smith model provides a more accurate description of the measured terahertz conductivity in this material than either Bruggeman or Maxwell–Garnett effective medium theories.

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Assessment of multidrug resistance on cell coculture patterns using scanning electrochemical microscopy

Kuss

Polcari

Geißler

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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The emergence of resistance to multiple unrelated chemotherapeutic drugs impedes the treatment of several cancers. Although the involvement of ATP-binding cassette transporters has long been known, there is no in situ method capable of tracking this transporter-related resistance at the single-cell level without interfering with the cell's environment or metabolism. Here, we demonstrate that scanning electrochemical microscopy (SECM) can quantitatively and noninvasively track multidrug resistance-related protein 1-dependent multidrug resistance in patterned adenocarcinoma cervical cancer cells. Nonresistant human cancer cells and their multidrug resistant variants are arranged in a side-by-side format using a stencil-based patterning scheme, allowing for precise positioning of target cells underneath the SECM sensor. SECM measurements of the patterned cells, performed with ferrocenemethanol and [Ru(NH 3 ) 6 ] 3+ serving as electrochemical indicators, are used to establish a kinetic "map" of constant-height SECM scans, free of topography contributions. The concept underlying the work described herein may help evaluate the effectiveness of treatment administration strategies targeting reduced drug efflux.ancer cells, such as lung cancer or leukemia, acquire resistance to multiple unrelated drugs in response to treatment with chemotherapeutic agents (1, 2). Resistance impedes therapeutic effectiveness, which in turn, reduces the long-term survival rate of cancer patients (2). The emergence of multidrug resistance (MDR) involves the overexpression of transmembrane proteins P-glycoprotein (P-gp) and MDR-related protein 1 (MRP1), which both belong to the family of 5′-triphosphatebinding cassette transporters (known as ABC transporters). P-gp and MRP1 act as molecular "pumps," actively removing therapeutic agents from the cancer cells, thereby preventing the drug from inducing the desired effect on the cell nucleus or cytoplasm. MDR based on P-gp is relatively well understood and involves binding of hyaluronan to the cell surface glycoprotein CD44. The resulting up-regulation of the transcriptional cofactor p300 expression and therefore the NFkappaB-specific transcriptional up-regulation lead to the production of P-gp, and with that chemoresistance in cells (3). However, the mechanism that causes MRP1-mediated MDR remains unclear.Currently, quantification of MDR relies on immunohistochemical analyses, such as real-time PCR, focusing mostly on P-gp or other members of ABC transporters (4-9). Fluorescent MRP1-specific studies were also conducted, revealing that resistant and nonresistant cancer cells have differential intracellular content of glutathione and GST, which affect their cell death mechanism during hyperthermia (10). Microvoltammetry was also used to measure the efflux of chemotherapeutic drugs from normal and MDR cancer cells on the single-cell level, with detection limits in the nanomolar range (11). Finally, flow cytometry has routinely been used to quantify and compare expression levels and activity of dif...

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Active pneumatic control of centrifugal microfluidic flows for lab-on-a-chip applications

et al. 2015

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This paper reports a novel method of controlling liquid motion on a centrifugal microfluidic platform based on the integration of a regulated pressure pump and a programmable electromechanical valving system. We demonstrate accurate control over the displacement of liquids within the system by pressurizing simultaneously multiple ports of the microfluidic device while the platform is rotating at high speed. Compared to classical centrifugal microfluidic platforms where liquids are solely driven by centrifugal and capillary forces, the method presented herein adds a new degree of freedom for fluidic manipulation, which represents a paradigm change in centrifugal microfluidics. We first demonstrate how various core microfluidic functions such as valving, switching, and reverse pumping (i.e., against the centrifugal field) can be easily achieved by programming the pressures applied at dedicated access ports of the microfluidic device. We then show, for the first time, that the combination of centrifugal force and active pneumatic pumping offers the possibility of mixing fluids rapidly (~0.1 s) and efficiently based on the creation of air bubbles at the bottom of a microfluidic reservoir. Finally, the suitability of the developed platform for performing complex bioanalytical assays in an automated fashion is demonstrated in a DNA harvesting experiment where recovery rates of about 70% were systematically achieved. The proposed concept offers the interesting prospect to decouple basic microfluidic functions from specific material properties, channel dimensions and fabrication tolerances, surface treatments, or on-chip active components, thus promoting integration of complex assays on simple and low-cost microfluidic cartridges.

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Water-oil core-shell droplets for electrowetting-based digital microfluidic devices

et al. 2008

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Digital microfluidics based on electrowetting-on-dielectric (EWOD) has recently emerged as one of the most promising technologies to realize integrated and highly flexible lab-on-a-chip systems. In such EWOD-based digital microfluidic devices, the aqueous droplets have traditionally been manipulated either directly in air or in an immiscible fluid such as silicone oil. However, both transporting mediums have important limitations and neither offers the flexibility required to fulfil the needs of several applications. In this paper, we report on an alternative mode of operation for EWOD-based devices in which droplets enclosed in a thin layer of oil are manipulated in air. We demonstrate the possibility to perform on-chip the fundamental fluidic operations by using such water-oil core-shell droplets and compare systematically the results with the traditional approach where the aqueous droplets are manipulated directly in air or oil. We show that the core-shell configuration combines several advantages of both the air and oil mediums. In particular, this configuration not only reduces the operation voltage of EWOD-based devices but also leads to higher transport velocities when compared with the manipulation of droplets directly in air or oil.

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D. Brassard

Grain size effect on the semiconductor-metal phase transition characteristics of magnetron-sputtered VO2 thin films

Phase diagram of the ultrafast photoinduced insulator-metal transition in vanadium dioxide

Integration and detection of biochemical assays in digital microfluidic LOC devices

Enhanced Photosusceptibility nearTcfor the Light-Induced Insulator-to-Metal Phase Transition in Vanadium Dioxide

Terahertz conductivity of the metal-insulator transition in a nanogranular VO2 film

Assessment of multidrug resistance on cell coculture patterns using scanning electrochemical microscopy

Active pneumatic control of centrifugal microfluidic flows for lab-on-a-chip applications

Water-oil core-shell droplets for electrowetting-based digital microfluidic devices

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