Showing total 3 results

1. Multiplexed paper analytical device for quantification of metals using distance-based detection.

Author

Cate DM, Noblitt SD, Volckens J, and Henry CS

Subjects

Coloring Agents chemistry, Microfluidics instrumentation, Colorimetry, Copper analysis, Iron analysis, Nickel analysis, Paper

Abstract

Exposure to metal-containing aerosols has been linked with adverse health outcomes for almost every organ in the human body. Commercially available techniques for quantifying particulate metals are time-intensive, laborious, and expensive; often sample analysis exceeds $100. We report a simple technique, based upon a distance-based detection motif, for quantifying metal concentrations of Ni, Cu, and Fe in airborne particulate matter using microfluidic paper-based analytical devices. Paper substrates are used to create sensors that are self-contained, self-timing, and require only a drop of sample for operation. Unlike other colorimetric approaches in paper microfluidics that rely on optical instrumentation for analysis, with distance-based detection, analyte is quantified visually based on the distance of a colorimetric reaction, similar to reading temperature on a thermometer. To demonstrate the effectiveness of this approach, Ni, Cu, and Fe were measured individually in single-channel devices; detection limits as low as 0.1, 0.1, and 0.05 μg were reported for Ni, Cu, and Fe. Multiplexed analysis of all three metals was achieved with detection limits of 1, 5, and 1 μg for Ni, Cu, and Fe. We also extended the dynamic range for multi-analyte detection by printing concentration gradients of colorimetric reagents using an off-the-shelf inkjet printer. Analyte selectivity was demonstrated for common interferences. To demonstrate utility of the method, Ni, Cu, and Fe were measured from samples of certified welding fume; levels measured with paper sensors matched known values determined gravimetrically.

Published

2015

2. High-yield paper-based quantitative blood separation system

Author

Saurabh Mehta, Zhengda Lu, Sasank Vemulapati, Balaji Srinivasan, Elizabeth Rey, and David Erickson

Subjects

Paper, Materials science, Capillary action, Iron, Point-of-Care Systems, Biomedical Engineering, Bioengineering, 02 engineering and technology, 01 natural sciences, Biochemistry, Article, law.invention, Blood cell, law, Lab-On-A-Chip Devices, medicine, Humans, Vitamin A, Filtration, Whole blood, Blood separation, Iron levels, 010401 analytical chemistry, Equipment Design, General Chemistry, Paper based, 021001 nanoscience & nanotechnology, 0104 chemical sciences, medicine.anatomical_structure, Yield (chemistry), 0210 nano-technology, Porosity, Blood Chemical Analysis, Biomedical engineering

Abstract

Interest in developing paper-based devices for point-of-care diagnostics in resource-limited settings has risen remarkably in recent decades. In this paper, we demonstrate what we refer to as “High Yield Passive Erythrocyte Removal” (HYPER) technology, which utilizes capillary forces in a unique cross-flow filtration for the separation of whole blood with performance comparable to centrifuges. As we will demonstrate, state-of-the-art passive blood separation methods implemented in paper-based systems exhibit rapid blood cell clogging on the filtration media or serum outlet and yield only about 10%−30% of the total serum present in the sample. Our innovation results from the inclusion of a differentiation pad, which exploits hydrodynamic effects to reduce the formation of a fouling layer on the blood filtration membrane resulting in more than 60% serum yield with undiluted whole blood as direct input. To demonstrate the effectiveness of the HYPER technology we implement it in a lateral flow system and demonstrate the accurate quantification of vitamin A and iron levels in whole blood samples in 15 minutes.

Published

2018

3. Multiplexed paper analytical device for quantification of metals using distance-based detection

Author

Charles S. Henry, David M. Cate, John Volckens, and Scott D. Noblitt

Subjects

Paper, Analyte, Materials science, Iron, Microfluidics, Biomedical Engineering, Analytical chemistry, Bioengineering, 02 engineering and technology, 01 natural sciences, Biochemistry, Article, Transition metal, Nickel, Colorimetry, Coloring Agents, Detection limit, Dynamic range, 010401 analytical chemistry, General Chemistry, 021001 nanoscience & nanotechnology, 0104 chemical sciences, Thermometer, Reagent, 0210 nano-technology, Copper

Abstract

Exposure to metal-containing aerosols has been linked with adverse health outcomes for almost every organ in the human body. Commercially available techniques for quantifying particulate metals are time-intensive, laborious, and expensive; often sample analysis exceeds $100. We report a simple technique, based upon a distance-based detection motif, for quantifying metal concentrations of Ni, Cu, and Fe in airborne particulate matter using microfluidic paper-based analytical devices. Paper substrates are used to create sensors that are self-contained, self-timing, and require only a drop of sample for operation. Unlike other colorimetric approaches in paper microfluidics that rely on optical instrumentation for analysis, with distance-based detection, analyte is quantified visually based on the distance of a colorimetric reaction, similar to reading temperature on a thermometer. To demonstrate the effectiveness of this approach, Ni, Cu, and Fe were measured individually in single-channel devices; detection limits as low as 0.1, 0.1, and 0.05 μg were reported for Ni, Cu, and Fe. Multiplexed analysis of all three metals was achieved with detection limits of 1, 5, and 1 μg for Ni, Cu, and Fe. We also extended the dynamic range for multi-analyte detection by printing concentration gradients of colorimetric reagents using an off-the-shelf inkjet printer. Analyte selectivity was demonstrated for common interferences. To demonstrate utility of the method, Ni, Cu, and Fe were measured from samples of certified welding fume; levels measured with paper sensors matched known values determined gravimetrically.

Published

2015