Your search keyword '"Glynn, Macdara"' showing total 12 results

1. Centrifugo-Magnetophoretic Purification of CD4+ Cells from Whole Blood Toward Future HIV/AIDS Point-of-Care Applications.

Author

Glynn M, Kirby D, Chung D, Kinahan DJ, Kijanka G, and Ducrée J

Subjects

Acquired Immunodeficiency Syndrome diagnosis, Acquired Immunodeficiency Syndrome economics, Acquired Immunodeficiency Syndrome immunology, Acquired Immunodeficiency Syndrome pathology, Automation, Laboratory economics, Blood Buffy Coat cytology, Blood Buffy Coat immunology, Blood Buffy Coat metabolism, Blood Buffy Coat pathology, CD4-Positive T-Lymphocytes immunology, CD4-Positive T-Lymphocytes metabolism, CD4-Positive T-Lymphocytes pathology, Centrifugation economics, Centrifugation instrumentation, Fluorescent Dyes analysis, Fluorescent Dyes chemistry, HIV Infections diagnosis, HIV Infections economics, HIV Infections immunology, HIV Infections pathology, HL-60 Cells, HeLa Cells, Health Care Costs, Humans, Immunomagnetic Separation economics, Microfluidics economics, Microspheres, Point-of-Care Testing economics, Proof of Concept Study, Spectrometry, Fluorescence economics, Spectrometry, Fluorescence instrumentation, Automation, Laboratory instrumentation, CD4-Positive T-Lymphocytes cytology, Immunomagnetic Separation instrumentation, Lab-On-A-Chip Devices economics, Microfluidics instrumentation, Point-of-Care Systems economics

Abstract

In medical diagnostics, detection of cells exhibiting specific phenotypes constitutes a paramount challenge. Detection technology must ensure efficient isolation of (often rare) targets while eliminating nontarget background cells. Technologies exist for such investigations, but many require high levels of expertise, expense, and multistep protocols. Increasing automation, miniaturization, and availability of such technologies is an aim of microfluidic lab-on-a-chip strategies. To this end, we present an integrated, dual-force cellular separation strategy using centrifugo-magnetophoresis. Whole blood spiked with target cells is incubated with (super-)paramagnetic microparticles that specifically bind phenotypic markers on target cells. Under rotation, all cells sediment into a chamber located opposite a co-rotating magnet. Unbound cells follow the radial vector, but under the additional attraction of the lateral magnetic field, bead-bound target cells are deflected to a designated reservoir. This multiforce separation is continuous and low loss. We demonstrate separation efficiently up to 92% for cells expressing the HIV/AIDS relevant epitope (CD4) from whole blood. Such highly selective separation systems may be deployed for accurate diagnostic cell isolations from biological samples such as blood. Furthermore, this high efficiency is delivered in a cheap and simple device, thus making it an attractive option for future deployment in resource-limited settings., (© 2013 Society for Laboratory Automation and Screening.)

Published

2014

2. Dissolvable Film-Controlled Buoyancy Pumping and Aliquoting on a Lab-On-A-Disc.

Author

Kilcawley, Niamh A., Voebel, Toni C., Early, Philip L., McArdle, Niamh A., Renou, Marine, Rio, Jeanne, Saint-Martin, Godefroi, Glynn, Macdara T., Zontar, Daniel, Brecher, Christian, Ducrée, Jens, and Kinahan, David J.

Subjects

MONTE Carlo method, CENTRIFUGAL force, MICROFLUIDICS, BUOYANCY

Abstract

Lab-on-a-Disc (LoaD) has great potential for applications in decentralised bioanalytical testing where speed and robustness are critical. Here, a disc-shaped microfluidic chip is rotated to pump liquid radially outwards; thus, all microfluidic structures must be fitted into the available radial length. To overcome this limitation, several centripetal pumping technologies have been developed. In this work, we combine buoyancy pumping, enabled by displacing aqueous samples and reagents centripetally inwards by a dense liquid (fluorocarbon FC-40), with dissolvable film (DF) to automate a multi-step assay. The DF dissolves in the presence of water but is not in contact with the FC-40. Therefore, the FC-40 can be stored behind the DF membranes and is autonomously released by contact with the arriving aqueous sample. Using this technology, tasks such as blood centrifugation can be located on the disc periphery where 'disc real estate' is less valuable and centrifugal forces are higher. To demonstrate this, we use the combination of the buoyancy-driven centripetal pumping with DF barriers to implement a fully automated multi-parameter diagnostic assay on the LoaD platform. The implemented steps include plasma extraction from a structure, automatically triggered metering/aliquoting, and the management of five onboard stored liquid reagents. Critically, we also demonstrate highly accurate aliquoting of reagents using centripetal pumping. We also provide a mathematical model to describe the pumping mechanism and apply lumped-element modelling and Monte Carlo simulation to estimate errors in the aliquoting volumes caused by manufacturing deviations. [ABSTRACT FROM AUTHOR]

Published

2023

3. Laboratory unit operations on centrifugal lab-on-a-disc cartridges using dissolvable-film enabled flow control

Author

Kinahan, David J., Glynn, Macdara, Kilcawley, Niamh, Kearney, Sinéad M., and Ducrée, Jens

Subjects

Biomedical engineering, GeneralLiterature_MISCELLANEOUS, Microfluidics, Valving, Event-triggered, Sequential Actuation, Selective Routing

Abstract

The suitability of the centrifugal “lab-on-a-disc” (LoaD) platform for point-of-use / point-of-care deployment, where ruggedness, portability, rapid turn-around times and ease-of-use are key, has resulted in increased interest from the academic community over the last decade. Recently, a new, so-called event-triggered valving paradigm was introduced which circumvented a number of the limitations of commonly used, rotationally actuated valves and complex instrument-controlled valving. In the dissolvable-film based event-triggered approach, it is the liquid movement about a disc which actuates a valve; thus enabling the concatenating of a number of liquid handling operations into an automated cascade. Functioning broadly independent of spin rate, the number of discrete valving operations is only limited by the available disc real-estate. In this work we present this valving paradigm to control a network of discrete Laboratory Unit Operations (LUOs) which, with experienced design, can be integrated together to implement complex fluidic assays. We describe how these valves can be configured, using Boolean-like network relationships, to implement LUOs such as sequential washing steps. We also describe how these valves can be configured to enable metering, mixing and selective routing of liquid flows. Finally, we describe how these valves can be configured to provide accurate temporal control of LUOs; thus providing an entire suite of process control technology which can be used to enable many bio-assays.

Published

2014

4. Paper imbibition for timing of multi-step liquid handling protocols on event-triggered centrifugal microfluidic lab-on-a-disc platforms

Author

Kinahan, David J., Kearney, Sinéad M., Faneuil, Oliver, Glynn, Macdara, Dimov, Nikolay, and Ducrée, Jens

Subjects

Lab-on-a-Disc, Microfluidics, Biomedical engineering

Abstract

Rotational microfluidic platforms have attracted swiftly growing interest over the last decade due to their suitability for integration and automation of sample preparation and detection. Valving is of pivotal importance on these compact “Lab-on-a-Disc” (LoaD) platforms as all liquids are exposed to the same centrifugal field. A number of valving technologies have been developed to coordinate timing of serial and / or parallel multi-step / multi-liquid assay protocols comprising of laboratory unit opera-tions (LUOs) such as the release, metering and mixing of sample and reagents. So far these valving techniques could be broadly categorised into rotationally controlled or externally actuated schemes. Only recently a new, “event-triggered” flow control has been introduced. In this approach, a valve is opened upon arrival of a liquid at a defined destination on the disc; this innovative mechanism for the first time permits the cascading of LUOs independent of the spin rate. In one technology, dissolvable films (DFs) are configured with a pneumatic chamber to offer function akin to an electrical relay. Dissolving one DF, termed the control film (CF), results in the release of liquid at a distal location through a so-called load film (LF). In this paper, a new method for temporal control of actuating DF-based, event-triggered CFs which are serially aligned at defined distances along a paper strip is introduced. Liquids are transported through the paper strip at a given velocity, thus setting well-defined intervals between subsequent LUOs, e.g. incubation steps. As a proof-of-concept, we present a disc with inte-grated metering and mixing which can perform a prototypical, 4-fold serial dilution; a common function in bioanalytical protocols. Imbibition of the paper strip sequentially opens five valves for serial dilution and mixing. To illustrate an unprecedented level of on-disc automation, this is followed by a branched cascade of 17 event-triggered valves (for a total of 22 liquid handling steps) which completes the serial dilution protocol.

Published

2014

5. Isolation of white blood cells using paper-triggered dissolvable-film valves on a centrifugal platform

Author

Kinahan, David J., Kilcawley, Niamh, Glynn, Macdara, Kirby, Daniel, and Ducrée, Jens

Subjects

Microfluidics

Abstract

The inherent centrifugation capability of the so-called ‘Lab-on-a-Disc’ (LoaD) platforms is widely used for blood processing during sample preparation. Here we introduce a valving technique which ena-bles rotational control of paper wetting to actuate dissolvable film (DF) valves. This mechanism is applied to the separation of whole blood into its chief constituents; plasma, leukocytes and erythrocytes.

Published

2014

6. Buoyancy-driven centripetal pumping for nested sample preparation in bioassays

Author

Kilcawley, Niamh, Kinahan, David J., Nwankire, Charles, Glynn, Macdara, and Ducrée, Jens

Subjects

Microfluidics

Abstract

In this paper we present a method of buoyancy-driven centripetal pumping utilizing a heavy, water-immiscible liquid to displace an aqueous sample radially inwards against the prevailing centrifugal force. Using formerly introduced dissolvable-film valving, we demonstrate metering and bidirectional periodical pumping of a single sample in the radial direction. We then show integrated sample discretisation, meter-ing and buoyancy-driven inward pumping in a microfluidic structure designed towards multi-parameter bioassays. This structure permits centrifugation of sample on the periphery of a disc (where the centrifugal field p) and proves a high degree of metering accuracy better than 1.2%

Published

2014

7. A portable optical reader and wall projector towards enumeration of bio-conjugated beads or cells.

Author

Glynn, Macdara T., Kinahan, David J., McArdle, Niamh A., Kendlin, Jane L., O’Connell, Triona M., and Ducrée, Jens

Subjects

*BEADS, *BIOCONJUGATES, *PACKED towers (Chemical engineering), *HEMATOCRIT, *LABS on a chip

Abstract

Measurement of the height of a packed column of cells or beads, which can be direclty related to the number of cells or beads present in a chamber, is an important step in a number of diagnostic assays. For example, haematocrit measurements may rapidly identify anemia or polycthemia. Recently, user-friendly and cost-efficient Lab-on-a-Chip devices have been developed towards isolating and counting cell sub-populations for diagnostic purposes. In this work, we present a low-cost optical module for estimating the filling level of packed magnetic beads within a Lab-on-a-Chip device. The module is compatible with a previously introduced, disposable microfluidic chip for rapid determination of CD4+ cell counts. The device is a simple optical microscope module is manufactured by 3D printing. An objective lens directly interrogates the height of packed beads which are efficiently isolated on the finger-actuated chip. Optionally, an inexpensive, battery-powered Light Emitting Diode may project a shadow of the microfluidic chip at approximately 50-fold magnification onto a nearby surface. The reader is calibrated with the filling levels of known concentrations of paramagnetic beads within the finger actuated chip. Results in direct and projector mode are compared to measurements from a conventional, inverted white-light microscope. All three read-out methods indicate a maximum variation of 6.5% between methods. [ABSTRACT FROM AUTHOR]

Published

2017

8. Baking Powder Actuated Centrifugo-Pneumatic Valving for Automation of Multi-Step Bioassays.

Author

Kinahan, David J., Kurzbuch, Dirk, Kilcawley, Niamh A., Bailey, Éanna, Glynn, Macdara T., McDonagh, Colette, Ducrée, Jens, and Renou, Marine

Subjects

BAKING powder, MICROFLUIDICS, LABS on a chip

Abstract

We report a new flow control method for centrifugal microfluidic systems; CO2 is released from on-board stored baking powder upon contact with an ancillary liquid. The elevated pressure generated drives the sample into a dead-end pneumatic chamber sealed by a dissolvable film (DF). This liquid incursion wets and dissolves the DF, thus opening the valve. The activation pressure of the DF valve can be tuned by the geometry of the channel upstream of the DF membrane. Through pneumatic coupling with properly dimensioned disc architecture, we established serial cascading of valves, even at a constant spin rate. Similarly, we demonstrate sequential actuation of valves by dividing the disc into a number of distinct pneumatic chambers (separated by DF membranes). Opening these DFs, typically through arrival of a liquid to that location on a disc, permits pressurization of these chambers. This barrier-based scheme provides robust and strictly ordered valve actuation, which is demonstrated by the automation of a multi-step/multi-reagent DNA-based hybridization assay. [ABSTRACT FROM AUTHOR]

Published

2016

9. Density-Gradient Mediated Band Extraction of Leukocytes from Whole Blood Using Centrifugo-Pneumatic Siphon Valving on Centrifugal Microfluidic Discs.

Author

Kinahan, David J., Kearney, Sinéad M., Kilcawley, Niamh A., Early, Philip L., Glynn, Macdara T., and Ducrée, Jens

Subjects

MONONUCLEAR leukocytes, MICROFLUIDICS, EXTRACTION (Chemistry), DENSITY gradient centrifugation, PNEUMATIC machinery, SURFACE preparation

Abstract

Here we present retrieval of Peripheral Blood Mononuclear Cells by density-gradient medium based centrifugation for subsequent analysis of the leukocytes on an integrated microfluidic “Lab-on-a-Disc” cartridge. Isolation of white blood cells constitutes a critical sample preparation step for many bioassays. Centrifugo-pneumatic siphon valves are particularly suited for blood processing as they function without need of surface treatment and are ‘low-pass’, i.e., holding at high centrifugation speeds and opening upon reduction of the spin rate. Both ‘hydrostatically’ and ‘hydrodynamically’ triggered centrifugo-pneumatic siphon valving schemes are presented. Firstly, the geometry of the pneumatic chamber of hydrostatically primed centrifugo-pneumatic siphon valves is optimised to enable smooth and uniform layering of blood on top of the density-gradient medium; this feature proves to be key for efficient Peripheral Blood Mononuclear Cell extraction. A theoretical analysis of hydrostatically primed valves is also presented which determines the optimum priming pressure for the individual valves. Next, ‘dual siphon’ configurations for both hydrostatically and hydrodynamically primed centrifugo-pneumatic siphon valves are introduced; here plasma and Peripheral Blood Mononuclear Cells are extracted through a distinct siphon valve. This work represents a first step towards enabling on disc multi-parameter analysis. Finally, the efficiency of Peripheral Blood Mononuclear Cells extraction in these structures is characterised using a simplified design. A microfluidic mechanism, which we termed phase switching, is identified which affects the efficiency of Peripheral Blood Mononuclear Cell extraction. [ABSTRACT FROM AUTHOR]

Published

2016

10. Event-triggered logical flow control for comprehensive process integration of multi-step assays on centrifugal microfluidic platforms.

Author

Kinahan, David J., Kearney, Sinéad M., Dimov, Nikolay, Glynn, Macdara T., and Ducrée, Jens

Subjects

MICROFLUIDICS, LIQUIDS, FLUIDICS, CONDENSED matter, RNA

Abstract

The centrifugal “lab-on-a-disc” concept has proven to have great potential for process integration of bioanalytical assays, in particular where ease-of-use, ruggedness, portability, fast turn-around time and cost efficiency are of paramount importance. Yet, as all liquids residing on the disc are exposed to the same centrifugal field, an inherent challenge of these systems remains the automation of multi-step, multi-liquid sample processing and subsequent detection. In order to orchestrate the underlying bioanalytical protocols, an ample palette of rotationally and externally actuated valving schemes has been developed. While excelling with the level of flow control, externally actuated valves require interaction with peripheral instrumentation, thus compromising the conceptual simplicity of the centrifugal platform. In turn, for rotationally controlled schemes, such as common capillary burst valves, typical manufacturing tolerances tend to limit the number of consecutive laboratory unit operations (LUOs) that can be automated on a single disc. In this paper, a major advancement on recently established dissolvable film (DF) valving is presented; for the very first time, a liquid handling sequence can be controlled in response to completion of preceding liquid transfer event, i.e. completely independent of external stimulus or changes in speed of disc rotation. The basic, event-triggered valve configuration is further adapted to leverage conditional, large-scale process integration. First, we demonstrate a fluidic network on a disc encompassing 10 discrete valving steps including logical relationships such as an AND-conditional as well as serial and parallel flow control. Then we present a disc which is capable of implementing common laboratory unit operations such as metering and selective routing of flows. Finally, as a pilot study, these functions are integrated on a single disc to automate a common, multi-step lab protocol for the extraction of total RNA from mammalian cell homogenate. [ABSTRACT FROM AUTHOR]

Published

2014

11. A hybrid microfluidic platform for cell-based assays via diffusive and convective trans-membrane perfusion.

Author

Vereshchagina, Elizaveta, Mc Glade, Declan, Glynn, Macdara, and Ducrée, Jens

Subjects

POLYMER research, MICROFLUIDICS, CELL culture, ANTINEOPLASTIC agents, MYELOID leukemia, CELL lines

Abstract

We present a novel 3D hybrid assembly of a polymer microfluidic chip with polycarbonate track-etched membrane (PCTEM) enabling membrane-supported cell culture. Two chip designs have been developed to establish either diffusive or convective reagent delivery using the integrated PCTEM. While it is well suited to a range of cell-based assays, we specifically employ this platform for the screening of a common antitumor chemotoxic agent (mitomycin C - MMC) on the HL60 myeloid leukemia cell line. The toxic activity of MMC is based on the generation of severe DNA damage in the cells. Using either mode of operation, the HL60 cells were cultured on-chip before, during, and after exposure to MMC at concentrations ranging from 0 to 50 μM. Cell viability was analysed off-chip by the trypan blue dye exclusion assay. The results of the on-chip viability assay were found to be consistent with those obtained off-chip and indicated ca. 40% cell survival at MMC concentration of 50 μM. The catalogue of capabilities of the here described cell assay platform comprises of (i) the culturing of cells either under shear-free conditions or under induced through-membrane flows, (ii) the tight time control of the reagent exposure, (iii) the straightforward assembly of devices, (iv) the flexibility on the choice of the membrane, and, prospectively, (v) the amenability for large-scale parallelization. [ABSTRACT FROM AUTHOR]

Published

2013

12. Centrifugal microfluidics for cell analysis

Author

Burger, Robert, Kirby, Daniel, Glynn, Macdara, Nwankire, Charles, O'Sullivan, Mary, Siegrist, Jonathan, Kinahan, David, Aguirre, Gerson, Kijanka, Gregor, Gorkin, Robert A, and Ducrée, Jens

Subjects

*MICROFLUIDICS, *CELL analysis, *HIGH performance liquid chromatography, *LABORATORY techniques, *LIFE sciences, *BIOLOGICAL assay

Abstract

Over the past two decades, centrifugal microfluidic systems have successfully demonstrated their capability for robust, high-performance liquid handling to enable modular, multi-purpose lab-on-a-chip platforms for a wide range of life-science applications. Beyond the handling of homogeneous liquids, the unique, rotationally controlled centrifugal actuation has proven to be specifically advantageous for performing cell and particle handling and assays. In this review we discuss technologies to implement two important steps for cell handling, namely separation and capturing/counting. [ABSTRACT FROM AUTHOR]

Published

2012