Your search keyword '"D. Erickson"' showing total 28 results

1. Prediction of Binary Critical Loci by Cubic Equations of State

Author

Robert M. Palenchar, Dale D. Erickson, and Thomas W. Leland

Published

1986

2. Sampling and Analysis for Semivolatile Brominated Organics in Ambient Air

Author

Edo D Pellizzari, Larry C. Michael, Ruth A. Zweidinger, Stephen D. Cooper, and Mitchell D. Erickson

Subjects

Environmental chemistry, Environmental science, Sampling (statistics), Ambient air

Published

1979

3. Equations of State

Author

K. C. CHAO, ROBERT L. ROBINSON, Michael M. Abbott, Kathryn K. Nass, John S. Rowlinson, Gunter J. Esper, James C. Holste, Kenneth R. Hall, Maria A. Barrufet, Philip T. Eubank, J. C. G. Calado, R. G. Rubio, W. B. Streett, Andy F. Burcham, Mark D. Trampe, Bruce E. Poling, David B. Manley, J. M. H. Levelt Sengers, R. F. Chang, G. Morrison, Robert M. Palenchar, Dale D. Erickson, Thomas W. Leland, J. S. Haselow, S. J. Han, R. A. Greenkorn, S. I. Sandler, K.-H. Lee, H. Kim, K. G. Honnell, C. K. Hall, R. J. Lee, S. B. Kanchanakpan, L. L. Lee, Chorng H. Twu, M. H. Li, F. T. H. Chung, C.-K. So, K. E. Starling, Douglas Henderson, Lesser Blum, Alessandro Tani, P. Vimalchand, Marc D. Donohue, Ilga Celmins, G. Ali Mansoori, James F. Ely, Thomas W. Copeman, Paul M. Mathias, Ulrich K. Deiters, Randall W. Morris, Edward A. Turek, Joseph J. Chaback, Gus K. Georgeton, Richard Lee Smith, Amyn S. Teja, Ali I. Majeed, Jan Wagner, Marinus P. W. Rijkers, Robert A. Heidemann, R. M. Enick, G. D. Holder, J. A. Grenko, A. J. Brainard, Grant M. Wilson, J.-M. Yu, Y. Adachi, B.C.-Y, K. C. CHAO, ROBERT L. ROBINSON, Michael M. Abbott, Kathryn K. Nass, John S. Rowlinson, Gunter J. Esper, James C. Holste, Kenneth R. Hall, Maria A. Barrufet, Philip T. Eubank, J. C. G. Calado, R. G. Rubio, W. B. Streett, Andy F. Burcham, Mark D. Trampe, Bruce E. Poling, David B. Manley, J. M. H. Levelt Sengers, R. F. Chang, G. Morrison, Robert M. Palenchar, Dale D. Erickson, Thomas W. Leland, J. S. Haselow, S. J. Han, R. A. Greenkorn, S. I. Sandler, K.-H. Lee, H. Kim, K. G. Honnell, C. K. Hall, R. J. Lee, S. B. Kanchanakpan, L. L. Lee, Chorng H. Twu, M. H. Li, F. T. H. Chung, C.-K. So, K. E. Starling, Douglas Henderson, Lesser Blum, Alessandro Tani, P. Vimalchand, Marc D. Donohue, Ilga Celmins, G. Ali Mansoori, James F. Ely, Thomas W. Copeman, Paul M. Mathias, Ulrich K. Deiters, Randall W. Morris, Edward A. Turek, Joseph J. Chaback, Gus K. Georgeton, Richard Lee Smith, Amyn S. Teja, Ali I. Majeed, Jan Wagner, Marinus P. W. Rijkers, Robert A. Heidemann, R. M. Enick, G. D. Holder, J. A. Grenko, A. J. Brainard, Grant M. Wilson, J.-M. Yu, Y. Adachi, and B.C.-Y

Subjects

Equations of state--Congresses

Published

1986

4. Monitoring Toxic Substances

Author

DENNIS SCHUETZLE, BRUCE N. AMES, WILLIAM G. THILLY, JOHN G. DELUCA, J. A. DORSEY, L. D. JOHNSON, R. G. MERRILL, THOMAS A. BELLAR, WILLIAM L. BUDDE, JAMES W. EICHELBERGER, RONALD A. HITES, G. A. JUNGCLAUS, V. LOPEZ-AVILA, L. S. SHELDON, BONITA A. GLATZ, COLIN D. CHRISWELL, GREGOR A. JUNK, PETER BARRETT, THOMAS R. COPELAND, FRANK N. ABERCROMBIE, ROMANA B. CRUZ, R. W. LINTON, P. D. MAKER, H. NIKI, C. M. SAVAGE, L. P. BREITENBACH, C. K. N. PATEL, T. M. HARVEY, D. SCHUETZLE, S. P. LEVINE, RUTH A. ZWEIDINGER, STEPHEN D. COOPER, MITCHELL D. ERICKSON, LARRY C. MICHAEL, EDO D. PELLIZZARI, W. E. RICH, R. A. WETZEL, DAVID H. FINE, S. R. HELLER, G. W. MILNE, DENNIS SCHUETZLE, BRUCE N. AMES, WILLIAM G. THILLY, JOHN G. DELUCA, J. A. DORSEY, L. D. JOHNSON, R. G. MERRILL, THOMAS A. BELLAR, WILLIAM L. BUDDE, JAMES W. EICHELBERGER, RONALD A. HITES, G. A. JUNGCLAUS, V. LOPEZ-AVILA, L. S. SHELDON, BONITA A. GLATZ, COLIN D. CHRISWELL, GREGOR A. JUNK, PETER BARRETT, THOMAS R. COPELAND, FRANK N. ABERCROMBIE, ROMANA B. CRUZ, R. W. LINTON, P. D. MAKER, H. NIKI, C. M. SAVAGE, L. P. BREITENBACH, C. K. N. PATEL, T. M. HARVEY, D. SCHUETZLE, S. P. LEVINE, RUTH A. ZWEIDINGER, STEPHEN D. COOPER, MITCHELL D. ERICKSON, LARRY C. MICHAEL, EDO D. PELLIZZARI, W. E. RICH, R. A. WETZEL, DAVID H. FINE, S. R. HELLER, and G. W. MILNE

Subjects

Pollution--Measurement--Congresses, Environmental toxicology--Congresses

Published

1979

5. Early Warning Diagnostics for Emerging Infectious Diseases in Developing into Late-Stage Pandemics.

Author

Oeschger TM, McCloskey DS, Buchmann RM, Choubal AM, Boza JM, Mehta S, and Erickson D

Subjects

Animals, Artificial Intelligence, COVID-19 diagnosis, COVID-19 epidemiology, COVID-19 virology, Communicable Diseases, Emerging epidemiology, Humans, Mass Screening, Pandemics, SARS-CoV-2 isolation & purification, Wastewater microbiology, Wastewater parasitology, Wastewater virology, Zoonoses diagnosis, Zoonoses epidemiology, Communicable Diseases, Emerging diagnosis

Abstract

The spread of infectious diseases due to travel and trade can be seen throughout history, whether from early settlers or traveling businessmen. Increased globalization has allowed infectious diseases to quickly spread to different parts of the world and cause widespread infection. Posthoc analysis of more recent outbreaks-SARS, MERS, swine flu, and COVID-19-has demonstrated that the causative viruses were circulating through populations for days or weeks before they were first detected, allowing disease to spread before quarantines, contact tracing, and travel restrictions could be implemented. Earlier detection of future novel pathogens could decrease the time before countermeasures are enacted. In this Account, we examined a variety of novel technologies from the past 10 years that may allow for earlier detection of infectious diseases. We have arranged these technologies chronologically from pre-human predictive technologies to population-level screening tools. The earliest detection methods utilize artificial intelligence to analyze factors such as climate variation and zoonotic spillover as well as specific species and geographies to identify where the infection risk is high. Artificial intelligence can also be used to monitor health records, social media, and various publicly available data to identify disease outbreaks faster than traditional epidemiology. Secondary to predictive measures is monitoring infection in specific sentinel animal species, where domestic animals or wildlife are indicators of potential disease hotspots. These hotspots inform public health officials about geographic areas where infection risk in humans is high. Further along the timeline, once the disease has begun to infect humans, wastewater epidemiology can be used for unbiased sampling of large populations. This method has already been shown to precede spikes in COVID-19 diagnoses by 1 to 2 weeks. As total infections increase in humans, bioaerosol sampling in high-traffic areas can be used for disease monitoring, such as within an airport. Finally, as disease spreads more quickly between humans, rapid diagnostic technologies such as lateral flow assays and nucleic acid amplification become very important. Minimally invasive point-of-care methods can allow for quick adoption and use within a population. These individual diagnostic methods then transfer to higher-throughput methods for more intensive population screening as an infection spreads. There are many promising early warning technologies being developed. However, no single technology listed herein will prevent every future outbreak. A combination of technologies from across our infection timeline would offer the most benefit in preventing future widespread disease outbreaks and pandemics.

Published

2021

6. Two-Color Duplex Platform for Point-of-Care Differential Detection of Malaria and Typhoid Fever.

Author

Cao XE, Kim J, Mehta S, and Erickson D

Subjects

Humans, L-Lactate Dehydrogenase, Point-of-Care Systems, Sensitivity and Specificity, Malaria diagnosis, Plasmodium, Typhoid Fever diagnosis

Abstract

Malaria and typhoid fever are two febrile illnesses prevalent in the tropics that often present overlapping symptoms. In this work, we demonstrate an optical reader-based diagnostics platform for rapid codetection and quantification of two antigen targets: lipopolysaccharide (LPS) for typhoid fever and plasmodium lactate dehydrogenase (pLDH) for malaria infections. We report a limit of detection (LoD) of 5 ng/mL for LPS and 10 ng/mL for pLDH in a spiked serum test. We also validated the duplex test's performance of differentiating malaria infection, typhoid fever infection, and coinfection by testing clinical samples in human serum. Our platform provides the potential for further multiplexing by encoding different color codes to various detection targets. The rapid result (∼15 min), low cost (∼$2), and minimal volume requirement for human serum clinical samples (4 μL) of our diagnostic platform offer great potential for deployment in resource-limited settings to help distinguish common causes for acute febrile illnesses at the point-of-need.

Published

2021

7. Paper-Based Semi-quantitative Antimicrobial Susceptibility Testing.

Author

Wang R and Erickson D

Abstract

Antimicrobial resistance is increasingly recognized as a major threat to global health. To combat this emerging threat, accessible antimicrobial susceptibility testing should be prioritized as a key component of stewardship efforts. In this work, we developed a user-friendly paper-based test that provides visual readout of bacterial antibiotic susceptibility in a semiquantitative format. We leveraged on-chip paper microfluidics to enable multiplexed testing of multiple antibiotic dilutions with a single sample addition step, replicating the functionality of traditional broth-dilution-based susceptibility testing in a simplified format. Our paper-based test offers several advantages including low sample volume requirement and lack of need for humidity control during incubation, an innovation that addresses a key limitation of conventional paper-microfluidic devices. Using several clinically relevant bacterial organisms and antimicrobial agents, we demonstrate that our colorimetric readout approach provides a strong predictor of susceptibility category., Competing Interests: The authors declare no competing financial interest., (© 2021 American Chemical Society.)

Published

2021

8. cAST: Capillary-Based Platform for Real-Time Phenotypic Antimicrobial Susceptibility Testing.

Author

Wang R, Vemulapati S, Westblade LF, Glesby MJ, Mehta S, and Erickson D

Subjects

Capillary Tubing, Drug Resistance, Bacterial drug effects, Equipment Design, Microbial Sensitivity Tests, Phenotype, Printing, Three-Dimensional, Stainless Steel, Time Factors, Acinetobacter baumannii drug effects, Anti-Bacterial Agents pharmacology, Enterobacter cloacae drug effects, Escherichia coli drug effects, Pseudomonas aeruginosa drug effects

Abstract

Antimicrobial resistance is recognized as one of the greatest emerging threats to public health. Antimicrobial resistant (AMR) microorganisms affect nearly 2 million people a year in the United States alone and place an estimated $20 billion burden on the healthcare system. The rise of AMR microorganisms can be attributed to a combination of overprescription of antimicrobials and a lack of accessible diagnostic methods. Delayed diagnosis is one of the primary reasons for empiric therapy, and diagnostic methods that enable rapid and accurate results are highly desirable to facilitate evidence-based treatment. This is particularly true for clinical situations at the point-of-care where access to state-of-the-art diagnostic equipment is scarce. Here, we present a capillary-based antimicrobial susceptibility testing platform (cAST), a unique approach that offers accelerated assessment of antimicrobial susceptibility in a low-cost and simple testing format. cAST delivers an expedited time-to-readout by means of optical assessment of bacteria incubated in a small capillary form factor along with a resazurin dye. cAST was designed using a combination of off-the-shelf and custom 3D-printed parts, making it extremely suitable for use in resource-limited settings. We demonstrate that growth of bacteria in cAST is approximately 25% faster than in a conventional microplate, further validate the diagnostic performance with clinical isolates, and show that cAST can deliver accurate antimicrobial susceptibility test results within 4-8 h.

Published

2020

9. Portable Resource-Independent Blood-Plasma Separator.

Author

Vemulapati S and Erickson D

Subjects

Antibodies chemistry, Blood Specimen Collection instrumentation, Cell Aggregation, Erythrocytes chemistry, Erythrocytes cytology, Humans, Immunomagnetic Separation instrumentation, Magnets, Plasma chemistry, Blood Specimen Collection methods, Immunoconjugates chemistry, Immunomagnetic Separation methods

Abstract

The centrifuge is the gold standard for lab-based sample processing. While extremely efficient and robust, centrifuges are seldom used in the field due to the high-power requirements, size, and operational complexity. The lack of viable alternatives for remote sample collection has crippled the ability for mobile practitioners in human and animal medicine to reliably collect blood samples from their patients. There is no truly resource-independent solution that is able to perform highly efficient blood-plasma separation. Here, we describe our initial efforts in developing the High Efficiency Rapid Magnetic Erythrocyte Separator (H.E.R.M.E.S) sleeve, an apparatus that uses a magnetic bead-based separation assay in a scaled-up form factor to achieve highly efficient separation of erythrocytes from plasma within a short amount of time. The sleeve is easy-to-use, is completely resource independent, and achieves highly efficient separation in sample volumes as large as 1 mL by means of a unique mixing scheme. We demonstrate the performance of the sleeve with human blood samples and compare it against conventional end-over-end mixing.

Published

2019

10. Rapid Diagnostic Platform for Colorimetric Differential Detection of Dengue and Chikungunya Viral Infections.

Author

Wang R, Ongagna-Yhombi SY, Lu Z, Centeno-Tablante E, Colt S, Cao X, Ren Y, Cárdenas WB, Mehta S, and Erickson D

Subjects

Humans, Immunoglobulin G analysis, Immunoglobulin M analysis, Particle Size, Surface Properties, Chikungunya Fever diagnosis, Colorimetry, Dengue diagnosis

Abstract

In this work, we demonstrate a rapid diagnostic platform with potential to transform clinical diagnosis of acute febrile illnesses in resource-limited settings. Acute febrile illnesses such as dengue and chikungunya, which pose high burdens of disease in tropical regions, share many nonspecific symptoms and are difficult to diagnose based on clinical history alone in the absence of accessible laboratory diagnostics. Through a unique color-mixing encoding and readout strategy, our platform enabled consistent and accurate multiplexed detection of dengue and chikungunya IgM/IgG antibodies in human clinical samples within 30 min. Our multiplex assay offers several advantages over conventional rapid diagnostic tests deployed in resource-limited settings, including a low sample volume requirement and the ability to concurrently detect four analytes. Our platform is a step toward multiplexed diagnostics that will be transformative for disease management in resource-limited settings by enabling informed treatment decisions through accessible evidence-based diagnosis.

Published

2019

11. Mitigating the Hook Effect in Lateral Flow Sandwich Immunoassays Using Real-Time Reaction Kinetics.

Author

Rey EG, O'Dell D, Mehta S, and Erickson D

Subjects

Antibodies immunology, C-Reactive Protein immunology, Gold chemistry, Humans, Kinetics, Metal Nanoparticles chemistry, Physical Phenomena, C-Reactive Protein analysis, Immunoassay methods

Abstract

The quantification of analyte concentrations using lateral flow assays is a low-cost and user-friendly alternative to traditional lab-based assays. However, sandwich-type immunoassays are often limited by the high-dose hook effect, which causes falsely low results when analytes are present at very high concentrations. In this paper, we present a reaction kinetics-based technique that solves this problem, significantly increasing the dynamic range of these devices. With the use of a traditional sandwich lateral flow immunoassay, a portable imaging device, and a mobile interface, we demonstrate the technique by quantifying C-reactive protein concentrations in human serum over a large portion of the physiological range. The technique could be applied to any hook effect-limited sandwich lateral flow assay and has a high level of accuracy even in the hook effect range.

Published

2017

12. Two-Color Lateral Flow Assay for Multiplex Detection of Causative Agents Behind Acute Febrile Illnesses.

Author

Lee S, Mehta S, and Erickson D

Subjects

Acute Disease, Chikungunya virus isolation & purification, Dengue Virus isolation & purification, Diagnostic Tests, Routine, Humans, Point-of-Care Systems, Antibodies analysis, Chikungunya Fever diagnosis, Colorimetry, Dengue diagnosis, Immunoglobulin G analysis, Immunoglobulin M analysis

Abstract

Acute undifferentiated febrile illnesses (AFIs) represent a significant health burden worldwide. AFIs can be caused by infection with a number of different pathogens including dengue (DENV) and Chikungunya viruses (CHIKV), and their differential diagnosis is critical to the proper patient management. While rapid diagnostic tests (RDTs) for the detection of IgG/IgM against a single pathogen have played a significant role in enabling the rapid diagnosis in the point-of-care settings, the state-of-the-art assay scheme is incompatible with the multiplex detection of IgG/IgM to more than one pathogen. In this paper, we present a novel assay scheme that uses two-color latex labels for rapid multiplex detection of IgG/IgM. Adapting this assay scheme, we show that 4-plex detection of the IgG/IgM antibodies to DENV and CHIKV is possible in 10 min by using it to correctly identify 12 different diagnostic scenarios. We also show that blue, mixed, and red colorimetric signals corresponding to IgG, IgG/IgM, and IgM positive cases, respectively, can be associated with distinct ranges of hue intensities, which could be exploited by analyzer systems in the future for making accurate, automated diagnosis. This represents the first steps toward the development of a single RDT-based system for the differential diagnosis of numerous AFIs of interest.

Published

2016

13. Optimal intensity and biomass density for biofuel production in a thin-light-path photobioreactor.

Author

Jain A, Voulis N, Jung EE, Doud DF, Miller WB, Angenent LT, and Erickson D

Subjects

Ethylenes analysis, Ethylenes metabolism, Microalgae growth & development, Microalgae metabolism, Biofuels, Biomass, Photobioreactors

Abstract

Production of competitive microalgal biofuels requires development of high volumetric productivity photobioreactors (PBRs) capable of supporting high-density cultures. Maximal biomass density supported by the current PBRs is limited by nonuniform distribution of light as a result of self-shading effects. We recently developed a thin-light-path stacked photobioreactor with integrated slab waveguides that distributed light uniformly across the volume of the PBR. Here, we enhance the performance of the stacked waveguide photobioreactor (SW-PBR) by determining the optimal wavelength and intensity regime of the incident light. This enabled the SW-PBR to support high-density cultures, achieving a carrying capacity of OD730 20. Using a genetically modified algal strain capable of secreting ethylene, we improved ethylene production rates to 937 μg L(-1) h(-1). This represents a 4-fold improvement over a conventional flat-plate PBR. These results demonstrate the advantages of the SW-PBR design and provide the optimal operational parameters to maximize volumetric production.

Published

2015

14. Nanophotonic force microscopy: characterizing particle-surface interactions using near-field photonics.

Author

Schein P, Kang P, O'Dell D, and Erickson D

Subjects

Surface Properties, Microscopy methods, Nanoparticles

Abstract

Direct measurements of particle-surface interactions are important for characterizing the stability and behavior of colloidal and nanoparticle suspensions. Current techniques are limited in their ability to measure pico-Newton scale interaction forces on submicrometer particles due to signal detection limits and thermal noise. Here we present a new technique for making measurements in this regime, which we refer to as nanophotonic force microscopy. Using a photonic crystal resonator, we generate a strongly localized region of exponentially decaying, near-field light that allows us to confine small particles close to a surface. From the statistical distribution of the light intensity scattered by the particle we are able to map out the potential well of the trap and directly quantify the repulsive force between the nanoparticle and the surface. As shown in this Letter, our technique is not limited by thermal noise, and therefore, we are able to resolve interaction forces smaller than 1 pN on dielectric particles as small as 100 nm in diameter.

Published

2015

15. In situ UV disinfection of a waveguide-based photobioreactor.

Author

Doud DF, Jain A, Ahsan SS, Erickson D, and Angenent LT

Subjects

Bacillus subtilis radiation effects, Escherichia coli radiation effects, Models, Theoretical, Spores, Bacterial radiation effects, Disinfection methods, Photobioreactors, Ultraviolet Rays

Abstract

Compact waveguide-based photobioreactors with high surface area-to-volume ratios and optimum light-management strategies have been developed to achieve high volumetric productivities within algal cultures. The light-managing strategies have focused on optimizing sunlight collection, sunlight filtration, and light delivery throughout the entire bioreactor volume by using light-directing waveguides. In addition to delivering broad-spectrum or monochromatic light for algal growth, these systems present an opportunity for advances in photobioreactor disinfection by using germicidal ultraviolet (UV) light. Here, we investigated the efficacy of in situ, nonchemical UV treatment to disinfect a heterotrophic contaminant in a compact photobioreactor. We maintained a >99% pure culture of Synechocystis sp. PCC 6803 for an operating period exceeding 3 weeks following UV treatment of an intentionally contaminated waveguide photobioreactor. Without UV treatment, the culture became contaminated within only a few days (control). We developed a theoretical model to predict disinfection efficiency based on operational parameters and bioreactor geometry, and we verified it with experimental results to predict the disinfection efficiency of a Bacillus subtilis spore culture.

Published

2014

16. Angular orientation of nanorods using nanophotonic tweezers.

Author

Kang P, Serey X, Chen YF, and Erickson D

Subjects

Hydrodynamics, Optical Tweezers, Photons, Microtubules chemistry, Nanotubes chemistry, Nanotubes, Carbon chemistry

Abstract

Near-field optical techniques have enabled the trapping, transport, and handling of nanoscopic materials much smaller than what can be manipulated with traditional optical tweezers. Here we extend the scope of what is possible by demonstrating angular orientation and rotational control of both biological and nonbiological nanoscale rods using photonic crystal nanotweezers. In our experiments, single microtubules (diameter 25 nm, length 8 μm) and multiwalled carbon nanotubes (outer diameter 110-170 nm, length 5 μm) are rotated by the optical torque resulting from their interaction with the evanescent field emanating from these devices. An angular trap stiffness of κ = 92.8 pN·nm/rad(2)·mW is demonstrated for the microtubules, and a torsional spring constant of 22.8 pN·nm/rad(2)·mW is measured for the nanotubes. We expect that this new capability will facilitate the development of high precision nanoassembly schemes and biophysical studies of bending strains of biomolecules.

Published

2012

17. Controlled photonic manipulation of proteins and other nanomaterials.

Author

Chen YF, Serey X, Sarkar R, Chen P, and Erickson D

Subjects

Binding Sites, Equipment Design, Equipment Failure Analysis, Materials Testing, Protein Binding, Micromanipulation instrumentation, Micromanipulation methods, Nanostructures chemistry, Nanostructures ultrastructure, Optical Tweezers, Proteins chemistry, Proteins ultrastructure

Abstract

The ability to controllably handle the smallest materials is a fundamental enabling technology for nanoscience. Conventional optical tweezers have proven useful for manipulating microscale objects but cannot exert enough force to manipulate dielectric materials smaller than about 100 nm. Recently, several near-field optical trapping techniques have been developed that can provide higher trapping stiffness, but they tend to be limited in their ability to reversibly trap and release smaller materials due to a combination of the extremely high electromagnetic fields and the resulting local temperature rise. Here, we have developed a new form of photonic crystal "nanotweezer" that can trap and release on-command Wilson disease proteins, quantum dots, and 22 nm polymer particles with a temperature rise less than ~0.3 K, which is below the point where unwanted fluid mechanical effects will prevent trapping or damage biological targets., (© 2012 American Chemical Society)

Published

2012

18. Directed self-assembly of microcomponents enabled by laser-activated bubble latching.

Author

Jiang L and Erickson D

Abstract

This article introduces a method for microscale assembly using laser-activated bubble latching. The technique combines the advantages of directed fluidic assembly and surface tension-driven latching to create arbitrarily complex and irregular structures with unique properties. The bubble latches, generated through the laser degradation of the tile material, are created on the fly, reversibly linking components at user-determined locations. Different phases of latching bubble growth are analyzed, and shear force calculations show that each bubble is able to support a tensile force of approximately 0.33 μN. We demonstrate that by exploiting the compressibility of bubbles, assembled objects can be made to switch between rigid and flexible states, facilitating component assembly and transport. Furthermore, we show reconfiguration capabilities through the use of bubble hinging. This novel hybrid approach to the assembly of microscale components offers significant user control while retaining a simplistic design environment., (© 2011 American Chemical Society)

Published

2011

19. High resolution reversible color images on photonic crystal substrates.

Author

Kang P, Ogunbo SO, and Erickson D

Subjects

Color, Optics and Photonics

Abstract

When light is incident on a crystalline structure with appropriate periodicity, some colors will be preferentially reflected (Joannopoulos, J. D.; Meade, R. D.; Winn, J. N. Photonic crystals: molding the flow of light; Princeton University Press: Princeton, NJ, 1995; p ix, 137 pp). These photonic crystals and the structural color they generate represent an interesting method for creating reflective displays and drawing devices, since they can achieve a continuous color response and do not require back lighting (Joannopoulos, J. D.; Villeneuve, P. R.; Fan, S. H. Photonic crystals: Putting a new twist on light. Nature 1997, 386, 143-149; Graham-Rowe, D. Tunable structural colour. Nat. Photonics 2009, 3, 551-553.; Arsenault, A. C.; Puzzo, D. P.; Manners, I.; Ozin, G. A. Photonic-crystal full-colour displays. Nat. Photonics 2007, 1, 468-472; Walish, J. J.; Kang, Y.; Mickiewicz, R. A.; Thomas, E. L. Bioinspired Electrochemically Tunable Block Copolymer Full Color Pixels. Adv. Mater.2009, 21, 3078). Here we demonstrate a technique for creating erasable, high-resolution, color images using otherwise transparent inks on self-assembled photonic crystal substrates (Fudouzi, H.; Xia, Y. N. Colloidal crystals with tunable colors and their use as photonic papers. Langmuir 2003, 19, 9653-9660). Using inkjet printing, we show the ability to infuse fine droplets of silicone oils into the crystal, locally swelling it and changing the reflected color (Sirringhaus, H.; Kawase, T.; Friend, R. H.; Shimoda, T.; Inbasekaran, M.; Wu, W.; Woo, E. P. High-resolution inkjet printing of all-polymer transistor circuits. Science 2000, 290, 2123-2126). Multicolor images with resolutions as high as 200 μm are obtained from oils of different molecular weights with the lighter oils being able to penetrate deeper, yielding larger red shifts. Erasing of images is done simply by adding a low vapor pressure oil which dissolves the image, returning the substrate to its original state.

Published

2011

20. Multiplex single nucleotide polymorphism genotyping utilizing ligase detection reaction coupled surface enhanced Raman spectroscopy.

Author

Lowe AJ, Huh YS, Strickland AD, Erickson D, and Batt CA

Subjects

Genotype, ras Proteins genetics, ras Proteins metabolism, Ligase Chain Reaction methods, Polymorphism, Single Nucleotide, Spectrum Analysis, Raman methods

Abstract

Single nucleotide polymorphisms (SNPs) are one of the key diagnostic markers for genetic disease, cancer progression, and pharmcogenomics. The ligase detection reaction (LDR) is an excellent method to identify SNPs, combining low detection limits and high specificity. We present the first multiplex LDR-surface enhanced Raman spectroscopy (SERS) SNP genotyping scheme. The platform has the advantage in that the diagnostic peaks of Raman are more distinct than fluorescence, and in theory, a clinically significant number of markers can be multiplexed in a single sample using different SERS reporters. Here we report LDR-SERS multiplex SNP genotyping of K-Ras oncogene alleles at 10 pM detection levels, optimization of DNA labeling as well as Raman conditions, and the linear correlation of diagnostic peak intensity to SNP target concentration in heterozygous samples. Genomic DNA from typed cells lines was obtained and scored for the K-Ras genotype. These advances are significant as we have further developed our new SNP genotyping platform and have demonstrated the ability to correlate genotype ratios directly to diagnostic Raman peak signal intensity.

Published

2010

21. Nanomanipulation using silicon photonic crystal resonators.

Author

Mandal S, Serey X, and Erickson D

Subjects

Crystallization, Light, Microscopy, Electron, Scanning methods, Nanoparticles chemistry, Nanostructures chemistry, Optics and Photonics methods, Particle Size, Photons, Polystyrenes chemistry, Nanotechnology methods, Optical Tweezers, Silicon chemistry

Abstract

Optical tweezers have enabled a number of microscale processes such as single cell handling, flow-cytometry, directed assembly, and optical chromatography. To extend this functionality to the nanoscale, a number of near-field approaches have been developed that yield much higher optical forces by confining light to subwavelength volumes. At present, these techniques are limited in both the complexity and precision with which handling can be performed. Here, we present a new class of nanoscale optical trap exploiting optical resonance in one-dimensional silicon photonic crystals. The trapping of 48 nm and 62 nm dielectric nanoparticles is demonstrated along with the ability to transport, trap, and manipulate larger nanoparticles by simultaneously exploiting the propagating nature of the light in a coupling waveguide and its stationary nature within the resonator. Field amplification within the resonator is shown to produce a trap several orders of magnitude stronger than conventional tweezers and an order of magnitude stiffer than other near-field techniques. Our approach lays the groundwork for a new class of optical trapping platforms that could eventually enable complex all-optical single molecule manipulation and directed assembly of nanoscale material.

Published

2010

22. Hydrodynamically tunable affinities for fluidic assembly.

Author

Krishnan M, Tolley MT, Lipson H, and Erickson D

Abstract

Most current micro- and nanoscale self-assembly methods rely on static, preprogrammed assembly affinities between the assembling components such as capillarity, DNA base pair matching, and geometric interactions. While these techniques have proven successful at creating relatively simple and regular structures, it is difficult to adapt these methods to enable dynamic reconfiguration of the structure or on-the-fly error correction. Here we demonstrate a technique to hydrodynamically tune affinities between assembling components by direct thermal modulation of the local viscosity field surrounding them. This approach is shown here for two-dimensional silicon elements of 500 microm length using a thermorheological fluid that undergoes reversible sol-gel transition on heating. Using this system, we demonstrate the ability to dynamically change the assembly point in a fluidic self-assembly process and selectively attract and reject elements from a larger structure. Although this technique is demonstrated here for a small number of passive mobile components around a fixed structure, it has the potential to overcome some of the limitations of current static affinity based self-assembly.

Published

2009

23. Forces and transport velocities for a particle in a slot waveguide.

Author

Yang AH, Lerdsuchatawanich T, and Erickson D

Subjects

Algorithms, Equipment Design, Models, Statistical, Models, Theoretical, Nanoparticles chemistry, Optics and Photonics, Particle Size, Physical Phenomena, Polystyrenes chemistry, Scattering, Radiation, Silicon chemistry, Microfluidic Analytical Techniques, Microfluidics, Nanotechnology methods

Abstract

Optofluidic transport seeks to exploit the high-intensity electromagnetic energy in waveguiding structures to manipulate nanoscopic matter using radiation pressure and optical trapping forces. In this paper, we present an analysis of optical trapping and transport of sub-100 nm polystyrene and gold nanoparticles in silicon slot waveguides. This study focuses on the effect of particle size, particle refractive index, and slot waveguide geometry on trapping stability and the resulting transport speed. Our results indicate that stable trapping and transport can be achieved for objects as small as 10 or 20 nm in diameter with as much as a 100 fold enhancement in trapping stiffness over the state of the art.

Published

2009

24. Surface-enhanced Raman scattering based ligase detection reaction.

Author

Huh YS, Lowe AJ, Strickland AD, Batt CA, and Erickson D

Subjects

Genes, ras, Humans, Models, Molecular, Point Mutation, DNA analysis, DNA genetics, DNA Mutational Analysis methods, Ligase Chain Reaction methods, Polymorphism, Single Nucleotide, Spectrum Analysis, Raman methods

Abstract

Genomics provides a comprehensive view of the complete genetic makeup of an organism. Individual sequence variations, as manifested by single nucleotide polymorphisms (SNPs), can provide insight into the basis for a large number of phenotypes and diseases including cancer. The ability rapidly screen for SNPs will have a profound impact on a number of applications, most notably personalized medicine. Here we demonstrate a new approach to SNP detection through the application of surface-enhanced Raman scattering (SERS) to the ligase detection reaction (LDR). The reaction uses two LDR primers, one of which contains a Raman enhancer and the other a reporter dye. In LDR, one of the primers is designed to interrogate the SNP. When the SNP being interrogated matches the discriminating primer sequence, the primers are ligated and the enhancer and dye are brought into close proximity enabling the dye's Raman signature to be detected. By detecting the Raman signature of the dye rather than its fluorescence emission, our technique avoids the problem of spectral overlap which limits number of reactions which can be carried out in parallel by existing systems. We demonstrate the LDR-SERS reaction for the detection of point mutations in the human K-ras oncogene. The reaction is implemented in an electrokinetically active microfluidic device that enables physical concentration of the reaction products for enhanced detection sensitivity and quantization. We report a limit of detection of 20 pM of target DNA with the anticipated specificity engendered by the LDR platform.

Published

2009

25. Electrokinetically based approach for single-nucleotide polymorphism discrimination using a microfluidic device.

Author

Erickson D, Liu X, Venditti R, Li D, and Krull UJ

Subjects

Cyclic AMP Response Element-Binding Protein chemistry, DNA Mutational Analysis methods, Electrochemistry, Mutation, Nerve Tissue Proteins chemistry, RNA-Binding Proteins chemistry, SMN Complex Proteins, Cyclic AMP Response Element-Binding Protein genetics, DNA Mutational Analysis instrumentation, Microfluidic Analytical Techniques instrumentation, Nerve Tissue Proteins genetics, Polymorphism, Single Nucleotide genetics, RNA-Binding Proteins genetics

Abstract

In this work, we describe and implement an electrokinetic approach for single-nucleotide polymorphism (SNP) discrimination using a PDMS/glass-based microfluidic chip. The technique takes advantage of precise control of the coupled thermal (Joule heating), shear (electroosmosis), and electrical (electrophoresis) energies present at an array of probes afforded by the application of external electrical potentials. Temperature controllers and embedded thermal devices are not required. The chips can be easily and inexpensively fabricated using standard microarray printing methods combined with soft-lithography patterned PDMS fluidics, making these systems easily adaptable to applications using higher density arrays. Extensive numerical simulations of the coupled flow and thermal properties and microscale thermometry experiments are described and used to characterize the in-channel conditions. It was found that optimal conditions for SNP detection occur at a lower temperature on-chip than for typical microarray experiments, thereby revealing the importance of the electrical and shear forces to the overall process. To demonstrate the clinical utility of the technique, the detection of single-base pair mutations in the survival motor neuron gene, associated with the childhood disease spinal muscular atrophy, is conducted.

Published

2005

26. Electrokinetically controlled DNA hybridization microfluidic chip enabling rapid target analysis.

Author

Erickson D, Liu X, Krull U, and Li D

Subjects

Adsorption, Biosensing Techniques, DNA Probes, Electricity, Electrochemistry, Kinetics, Microscopy, Fluorescence, Osmosis, DNA analysis, Microfluidics methods, Nucleic Acid Hybridization methods

Abstract

Biosensors and more specifically biochips exploit the interactions between a target analyte and an immobilized biological recognition element to produce a measurable signal. Systems based on surface nucleic acid hybridization, such as microarrays, are particularly attractive due to the high degree of selectivity in the binding interactions. One of the drawbacks of this reaction is the relatively long time required for complete hybridization to occur, which is often the result of diffusion-limited reaction kinetics. In this work, an electrokinetically controlled DNA hybridization microfluidic chip will be introduced. The electrokinetic delivery technique provides the ability to dispense controlled samples of nanoliter volumes directly to the hybridization array (thereby increasing the reaction rate) and rapidly remove nonspecific adsorption, enabling the hybridization, washing, and scanning procedures to be conducted simultaneously. The result is that all processes from sample dispensing to hybridization detection can be completed in as little as 5 min. The chip also demonstrates an efficient hybridization scheme in which the probe saturation level is reached very rapidly as the targets are transported over the immobilized probe site enabling quantitative analysis of the sample concentration. Detection levels as low as 50 pM have been recorded using an epifluorescence microscope.

Published

2004

27. Heterogeneous surface charge enhanced micromixing for electrokinetic flows.

Author

Biddiss E, Erickson D, and Li D

Abstract

Enhancing the species mixing in microfluidic applications is key to reducing analysis time and increasing device portability. The mixing in electroosmotic flow is usually diffusion-dominated. Recent numerical studies have indicated that the introduction of electrically charged surface heterogeneities may augment mixing efficiencies by creating localized regions of flow circulation. In this study, we experimentally visualized the effects of surface charge patterning and developed an optimized electrokinetic micromixer applicable to the low Reynolds number regime. Using the optimized micromixer, mixing efficiencies were improved between 22 and 68% for the applied potentials ranging from 70 to 555 V/cm when compared with the negatively charged homogeneous case. For producing a 95% mixture, this equates to a potential decrease in the required mixing channel length of up to 88% for flows with Péclet numbers between 190 and 1500.

Published

2004

28. Ionic strength-dependent pK shift in the helix-coil transition of grafted poly(L-glutamic acid) layers analyzed by electrokinetic and ellipsometric measurements.

Author

Zimmermann R, Kratzmüller T, Erickson D, Li D, Braun HG, and Werner C

Subjects

Electrochemistry, Hydrogen-Ion Concentration, Osmolar Concentration, Protein Structure, Secondary, Solutions, Surface Properties, Water, Polyglutamic Acid chemistry

Abstract

Surface-bound layers of poly(L-glutamic acid) prepared by a recently described "grafting-from" method were analyzed with respect to electrical charging and structural alterations upon variation of pH and concentration of the background electrolyte in aqueous solutions. The microslit electrokinetic setup (MES) was utilized for the combined determination of zeta potential and surface conductivity on the basis of streaming potential and streaming current measurements at polypeptide layers in contact with aqueous electrolyte solutions of varied composition. In situ ellipsometry was applied at similar samples immersed in identical aqueous solutions to investigate the influence of the solution pH on the structure of the polypeptide layers. Zeta potential and Dukhin number versus pH plots revealed the dissociation behavior of the surface-bound polypeptides indicating a significant shift of the pK of their acidic side chains correlating with the concentration of the background electrolyte potassium chloride and the related variation of the Debye screening length. Surface conductivity data pointed at a more expanded structure of the polypeptide layer in the fully dissociated state as an increased ion conductance in this part of the interface was determined. The occurrence of a strong increase of the thickness and a corresponding decrease of the refractive index for the coil state of the layer strongly supports the findings of the electrokinetic measurements. This fully reversible "switching" of the layer structure was attributed to helix-coil transitions within the grafted polypeptides induced by the dissociation of carboxylic acid functions of the polypeptide side chains. The shift of the "switching pH" of the surface-bound poly(L-glutamic acid) layers at varied concentrations of the background electrolyte was interpreted as a result of the pK shift of the carboxylic acid groups of the polypeptide side chains. The observed patterns prove that the electrostatic interactions causing this shift occur within but not between the grafted chains.

Published

2004