Your search keyword '"Vreeland, Erika C."' showing total 11 results

1. Surface Functionalized Barium Titanate Nanoparticles: A Combined Experimental and Computational Study.

Author

Domrzalski, Jessica N., Stevens, Tyler E., Van Ginhoven, Renee M., Fritzsching, Keith J., Walder, Brennan J., Johnson, Emily M., Lewis, Riley E., Vreeland, Erika C., Pearce, Charles J., Vargas, David A., Coker, Eric N., Martinez, Estevan J., Grey, John K., and Monson, Todd C.

Published

2022

2. Charge‐Separated and Lewis Paired Metal–Organic Framework for Anion Exchange and CO2 Chemical Fixation.

Author

Thapa, Sheela, Meng, Lingyao, Hettiarachchi, Eshani, Bader, Yousef K., Dickie, Diane A., Rubasinghege, Gayan, Ivanov, Sergei A., Vreeland, Erika C., and Qin, Yang

Subjects

LEWIS pairs (Chemistry), METAL-organic frameworks, CHEMICAL reactions, ANIONS, LEWIS bases, ION-permeable membranes, PYRAZOLYL compounds

Abstract

Charge‐separated metal–organic frameworks (MOFs) are a unique class of MOFs that can possess added properties originating from the exposed ionic species. A new charge‐separated MOF, namely, UNM‐6 synthesized from a tetrahedral borate ligand and Co2+ cation is reported herein. UNM‐6 crystalizes into the highly symmetric P43n space group with fourfold interpenetration, despite the stoichiometric imbalance between the B and Co atoms, which also leads to loosely bound NO3− anions within the crystal structure. These NO3− ions can be quantitatively exchanged with various other anions, leading to Lewis acid (Co2+) and Lewis base (anions) pairs within the pores and potentially cooperative catalytic activities. For example, UNM‐6‐Br, the MOF after anion exchange with Br− anions, displays high catalytic activity and stability in reactions of CO2 chemical fixation into cyclic carbonates. [ABSTRACT FROM AUTHOR]

Published

2020

3. Rapid Nucleic Acid Extraction and Purification Using a Miniature Ultrasonic Technique.

Author

Branch, Darren W., Vreeland, Erika C., McClain, Jamie L., Murton, Jaclyn K., James, Conrad D., and Achyuthan, Komandoor E.

Subjects

NUCLEIC acid isolation methods, LITHIUM niobate, BULK acoustic waves

Abstract

Miniature ultrasonic lysis for biological sample preparation is a promising technique for efficient and rapid extraction of nucleic acids and proteins from a wide variety of biological sources. Acoustic methods achieve rapid, unbiased, and efficacious disruption of cellular membranes while avoiding the use of harsh chemicals and enzymes, which interfere with detection assays. In this work, a miniature acoustic nucleic acid extraction system is presented. Using a miniature bulk acoustic wave (BAW) transducer array based on 36° Y-cut lithium niobate, acoustic waves were coupled into disposable laminate-based microfluidic cartridges. To verify the lysing effectiveness, the amount of liberated ATP and the cell viability were measured and compared to untreated samples. The relationship between input power, energy dose, flow-rate, and lysing efficiency were determined. DNA was purified on-chip using three approaches implemented in the cartridges: a silica-based sol-gel silica-bead filled microchannel, nucleic acid binding magnetic beads, and Nafion-coated electrodes. Using E. coli, the lysing dose defined as ATP released per joule was 2.2 x greater, releasing 6.1 x more ATP for the miniature BAW array compared to a bench-top acoustic lysis system. An electric field-based nucleic acid purification approach using Nafion films yielded an extraction efficiency of 69.2% in 10 min for 50 μL samples. [ABSTRACT FROM AUTHOR]

Published

2017

4. Nucleic acid extraction using a rapid, chemical free, ultrasonic technique for point-of-care diagnostics.

Author

Branch, Darren W., Smith, Gennifer T., Vreeland, Erika C., Blakemore, Robert, and Alland, David

Published

2014

5. Charge-Separated and Lewis Paired Metal-Organic Framework for Anion Exchange and CO 2 Chemical Fixation.

Author

Thapa S, Meng L, Hettiarachchi E, Bader YK, Dickie DA, Rubasinghege G, Ivanov SA, Vreeland EC, and Qin Y

Abstract

Charge-separated metal-organic frameworks (MOFs) are a unique class of MOFs that can possess added properties originating from the exposed ionic species. A new charge-separated MOF, namely, UNM-6 synthesized from a tetrahedral borate ligand and Co 2+ cation is reported herein. UNM-6 crystalizes into the highly symmetric P43n space group with fourfold interpenetration, despite the stoichiometric imbalance between the B and Co atoms, which also leads to loosely bound NO 3 - anions within the crystal structure. These NO 3 - ions can be quantitatively exchanged with various other anions, leading to Lewis acid (Co 2+ ) and Lewis base (anions) pairs within the pores and potentially cooperative catalytic activities. For example, UNM-6-Br, the MOF after anion exchange with Br - anions, displays high catalytic activity and stability in reactions of CO 2 chemical fixation into cyclic carbonates., (© 2020 Wiley-VCH GmbH.)

Published

2020

6. Self-Assembled Layering of Magnetic Nanoparticles in a Ferrofluid on Silicon Surfaces.

Author

Theis-Bröhl K, Vreeland EC, Gomez A, Huber DL, Saini A, Wolff M, Maranville BB, Brok E, Krycka KL, Dura JA, and Borchers JA

Abstract

This article describes the three-dimensional self-assembly of monodisperse colloidal magnetite nanoparticles (NPs) from a dilute water-based ferrofluid onto a silicon surface and the dependence of the resultant magnetic structure on the applied field. The NPs assemble into close-packed layers on the surface followed by more loosely packed ones. The magnetic field-dependent magnetization of the individual NP layers depends on both the rotational freedom of the layer and the magnetization of the adjacent layers. For layers in which the NPs are more free to rotate, the easy axis of the NP can readily orient along the field direction. In more dense packing, free rotation of the NPs is hampered, and the NP ensembles likely build up quasi-domain states to minimize energy, which leads to lower magnetization in those layers. Detailed analysis of polarized neutron reflectometry data together with model calculations of the arrangement of the NPs within the layers and input from small-angle scattering measurements provide full characterization of the core/shell NP dimensions, degree of chaining, arrangement of the NPs within the different layers, and magnetization depth profile.

Published

2018

7. Magnetic Nanocomposites and Their Incorporation into Higher Order Biosynthetic Functional Architectures.

Author

Watt J, Collins AM, Vreeland EC, Montano GA, and Huber DL

Abstract

A magnetically active Fe 3 O 4 /poly(ethylene oxide)- block -poly(butadiene) (PEO- b -PBD) nanocomposite is formed by the encapsulation of magnetite nanoparticles with a short-chain amphiphilic block copolymer. This material is then incorporated into the self-assembly of higher order polymer architectures, along with an organic pigment, to yield biosynthetic, bifunctional optical and magnetically active Fe 3 O 4 /bacteriochlorophyll c /PEO- b -PBD polymeric chlorosomes., Competing Interests: The authors declare no competing financial interest.

Published

2018

8. Phase-sensitive small-angle neutron scattering experiment.

Author

Brok E, Krycka KL, Vreeland EC, Gomez A, Huber DL, and Majkrzak CF

Abstract

In the work reported herein, we investigate the practicality of a recently introduced variant of a general phase-sensitive method in small-angle neutron scattering that attempts to address the loss of phase-information as well as the orientational averaging simultaneously-through the use of reference structures in conjunction with finite element analysis. In particular, one possible physical realization of this approach is to employ polarized beams together with a magnetic reference connected to the sample object. We report on a first such practical implementation by successfully recovering the structure of a core-shell nanoparticle system.

Published

2018

9. The Relaxation Wall: Experimental Limits to Improving MPI Spatial Resolution by Increasing Nanoparticle Core size.

Author

Tay ZW, Hensley DW, Vreeland EC, Zheng B, and Conolly SM

Abstract

Magnetic Particle Imaging (MPI) is a promising new tracer modality with zero attenuation in tissue, high contrast and sensitivity, and an excellent safety profile. However, the spatial resolution of MPI is currently around 1 mm in small animal scanners. Especially considering tradeoffs when scaling up MPI scanning systems to human size, this resolution needs to be improved for clinical applications such as angiography and brain perfusion. One method to improve spatial resolution is to increase the magnetic core size of the superparamagnetic nanoparticle tracers. The Langevin model of superparamagnetism predicts a cubic improvement of spatial resolution with magnetic core diameter. However, prior work has shown that the finite temporal response, or magnetic relaxation, of the tracer increases with magnetic core diameter and eventually leads to blurring in the MPI image. Here we perform the first wide ranging study of 5 core sizes between 18-32 nm with experimental quantification of the spatial resolution of each. Our results show that increasing magnetic relaxation with core size eventually opposes the expected Langevin behavior, causing spatial resolution to stop improving after 25 nm. Different MPI excitation strategies were experimentally investigated to mitigate the effect of magnetic relaxation. The results show that magnetic relaxation could not be fully mitigated for the larger core sizes and the cubic resolution improvement predicted by the Langevin was not achieved. This suggests that magnetic relaxation is a significant and unsolved barrier to achieving the high spatial resolutions predicted by the Langevin model for large core size SPIOs.

Published

2017

10. Development of advanced signal processing and source imaging methods for superparamagnetic relaxometry.

Author

Huang MX, Anderson B, Huang CW, Kunde GJ, Vreeland EC, Huang JW, Matlashov AN, Karaulanov T, Nettles CP, Gomez A, Minser K, Weldon C, Paciotti G, Harsh M, Lee RR, and Flynn ER

Subjects

Humans, Algorithms, Image Processing, Computer-Assisted methods, Magnetic Resonance Spectroscopy instrumentation, Magnetite Nanoparticles, Molecular Imaging methods, Phantoms, Imaging, Signal Processing, Computer-Assisted instrumentation

Abstract

Superparamagnetic relaxometry (SPMR) is a highly sensitive technique for the in vivo detection of tumor cells and may improve early stage detection of cancers. SPMR employs superparamagnetic iron oxide nanoparticles (SPION). After a brief magnetizing pulse is used to align the SPION, SPMR measures the time decay of SPION using super-conducting quantum interference device (SQUID) sensors. Substantial research has been carried out in developing the SQUID hardware and in improving the properties of the SPION. However, little research has been done in the pre-processing of sensor signals and post-processing source modeling in SPMR. In the present study, we illustrate new pre-processing tools that were developed to: (1) remove trials contaminated with artifacts, (2) evaluate and ensure that a single decay process associated with bounded SPION exists in the data, (3) automatically detect and correct flux jumps, and (4) accurately fit the sensor signals with different decay models. Furthermore, we developed an automated approach based on multi-start dipole imaging technique to obtain the locations and magnitudes of multiple magnetic sources, without initial guesses from the users. A regularization process was implemented to solve the ambiguity issue related to the SPMR source variables. A procedure based on reduced chi-square cost-function was introduced to objectively obtain the adequate number of dipoles that describe the data. The new pre-processing tools and multi-start source imaging approach have been successfully evaluated using phantom data. In conclusion, these tools and multi-start source modeling approach substantially enhance the accuracy and sensitivity in detecting and localizing sources from the SPMR signals. Furthermore, multi-start approach with regularization provided robust and accurate solutions for a poor SNR condition similar to the SPMR detection sensitivity in the order of 1000 cells. We believe such algorithms will help establishing the industrial standards for SPMR when applying the technique in pre-clinical and clinical settings.

Published

2017

11. Magnetic relaxometry as applied to sensitive cancer detection and localization.

Author

De Haro LP, Karaulanov T, Vreeland EC, Anderson B, Hathaway HJ, Huber DL, Matlashov AN, Nettles CP, Price AD, Monson TC, and Flynn ER

Subjects

Animals, Cell Line, Tumor, Female, Mice, Mice, Nude, Mice, SCID, Molecular Imaging methods, Reproducibility of Results, Sensitivity and Specificity, Biomarkers, Tumor analysis, Magnetic Resonance Imaging methods, Magnetic Resonance Spectroscopy methods, Magnetite Nanoparticles, Neoplasms, Experimental chemistry, Neoplasms, Experimental diagnostic imaging

Abstract

Background: Here we describe superparamagnetic relaxometry (SPMR), a technology that utilizes highly sensitive magnetic sensors and superparamagnetic nanoparticles for cancer detection. Using SPMR, we sensitively and specifically detect nanoparticles conjugated to biomarkers for various types of cancer. SPMR offers high contrast in vivo, as there is no superparamagnetic background, and bones and tissue are transparent to the magnetic fields., Methods: In SPMR measurements, a brief magnetizing pulse is used to align superparamagnetic nanoparticles of a discrete size. Following the pulse, an array of superconducting quantum interference detectors (SQUID) sensors detect the decaying magnetization field. NP size is chosen so that, when bound, the induced field decays in seconds. They are functionalized with specific biomarkers and incubated with cancer cells in vitro to determine specificity and cell binding. For in vivo experiments, functionalized NPs are injected into mice with xenograft tumors, and field maps are generated to localize tumor sites., Results: Superparamagnetic NPs developed here have small size dispersion. Cell incubation studies measure specificity for different cell lines and antibodies with very high contrast. In vivo animal measurements verify SPMR localization of tumors. Our results indicate that SPMR possesses sensitivity more than 2 orders of magnitude better than previously reported.

Published

2015