Your search keyword '"Hall LT"' showing total 87 results

1. Detection of nanoscale electron spin resonance spectra demonstrated using nitrogen-vacancy centre probes in diamond.

Author

Hall, LT, Kehayias, P, Simpson, DA, Jarmola, A, Stacey, A, Budker, D, and Hollenberg, LCL

Abstract

Electron spin resonance (ESR) describes a suite of techniques for characterizing electronic systems with applications in physics, chemistry, and biology. However, the requirement for large electron spin ensembles in conventional ESR techniques limits their spatial resolution. Here we present a method for measuring ESR spectra of nanoscale electronic environments by measuring the longitudinal relaxation time of a single-spin probe as it is systematically tuned into resonance with the target electronic system. As a proof of concept, we extracted the spectral distribution for the P1 electronic spin bath in diamond by using an ensemble of nitrogen-vacancy centres, and demonstrated excellent agreement with theoretical expectations. As the response of each nitrogen-vacancy spin in this experiment is dominated by a single P1 spin at a mean distance of 2.7 nm, the application of this technique to the single nitrogen-vacancy case will enable nanoscale ESR spectroscopy of atomic and molecular spin systems.

Published

2016

2. Temperature and angle dependent magnetic imaging of biological iron nanoparticles using quantum diamond microscopy

Author

de Gille, RW, Healey, AJ, Robertson, IO, Hall, LT, Tetienne, J-P, Malkemper, EP, Keays, DA, Hollenberg, LCL, Simpson, DA, de Gille, RW, Healey, AJ, Robertson, IO, Hall, LT, Tetienne, J-P, Malkemper, EP, Keays, DA, Hollenberg, LCL, and Simpson, DA

Abstract

Quantum diamond microscopy is an emerging versatile technique for studying the magnetic properties of materials. It has been applied extensively in condensed matter physics and materials science and has blossomed into a unique platform for the magnetic study of biological systems. To date, biological demonstrations of quantum diamond microscopy have been performed under ambient conditions. Here, we extend this magnetic microscopy platform to cryogenic temperatures to study magnetic anisotropy and the blocking temperature from an individual iron organelle found within the inner ear of pigeons. Our work confirms that the interface between thin histological tissue sections and diamond can be maintained under cryogenic temperatures. Our magnetic images provide evidence of magnetic anisotropy from a single iron organelle with sub-cellular resolution using this correlative optical imaging method. This approach may be extended to a broad range of systems where magnetic materials play structural and functional roles in biological systems.

Published

2023

3. Quantum magnetic imaging of iron organelles within the pigeon cochlea

Author

de Gille, RW, McCoey, JM, Hall, LT, Tetienne, J-P, Malkemper, EP, Keays, DA, Hollenberg, LCL, Simpson, DA, de Gille, RW, McCoey, JM, Hall, LT, Tetienne, J-P, Malkemper, EP, Keays, DA, Hollenberg, LCL, and Simpson, DA

Abstract

The ability of pigeons to sense geomagnetic fields has been conclusively established despite a notable lack of determination of the underlying biophysical mechanisms. Quasi-spherical iron organelles previously termed "cuticulosomes" in the cochlea of pigeons have potential relevance to magnetoreception due to their location and iron composition; however, data regarding the magnetic susceptibility of these structures are currently limited. Here quantum magnetic imaging techniques are applied to characterize the magnetic properties of individual iron cuticulosomes in situ. The stray magnetic fields emanating from cuticulosomes are mapped and compared to a detailed analytical model to provide an estimate of the magnetic susceptibility of the individual particles. The images reveal the presence of superparamagnetic and ferrimagnetic domains within individual cuticulosomes and magnetic susceptibilities within the range 0.029 to 0.22. These results provide insights into the elusive physiological roles of cuticulosomes. The susceptibilities measured are not consistent with a torque-based model of magnetoreception, placing iron storage and stereocilia stabilization as the two leading putative cuticulosome functions. This work establishes quantum magnetic imaging as an important tool to complement the existing array of techniques used to screen for potential magnetic particle-based magnetoreceptor candidates.

Published

2021

4. Quantum Magnetic Imaging of Iron Biomineralization in Teeth of the Chiton Acanthopleura hirtosa

Author

McCoey, JM, Matsuoka, M, de Gille, RW, Hall, LT, Shaw, JA, Tetienne, J-P, Kisailus, D, Hollenberg, LCL, Simpson, DA, McCoey, JM, Matsuoka, M, de Gille, RW, Hall, LT, Shaw, JA, Tetienne, J-P, Kisailus, D, Hollenberg, LCL, and Simpson, DA

Abstract

Iron is critical for life. Nature capitalizes on the physical attributes of iron biominerals for functional, structural, and sensory applications. Iron biomineralization is well exemplified by the magnetite-bearing radula of chitons, the hardest known biomineral of any animal. Although magnetism is an integral property of iron biominerals, limited information exists on the magnetic state, structure, and orientation of these nanoscale materials during mineralization. The advent of quantum-based magnetic microscopy provides a new avenue to probe these biological systems directly, providing detailed magnetic information of the iron oxide structures. Here two complementary quantum magnetic microscopy methods are applied, based on nitrogen-vacancy centers in diamond, to spatially map the mineral phases ferrihydrite and magnetite in the developing teeth of the chiton Acanthopleura hirtosa. The images reveal previously undiscovered long-range magnetic order, established at the onset of magnetite mineralization. This is in contrast to electron microscopy studies that show no strong common crystallographic orientation. The implications of these results are important, not just for the insights gained in biomineralization of the target organism, but also for the study of a broad range of iron minerals in the physical and biological sciences.

Published

2020

5. Rapid, High-Resolution Magnetic Microscopy of Single Magnetic Microbeads

Author

McCoey, JM, de Gille, RW, Nasr, B, Tetienne, J-P, Hall, LT, Simpson, DA, Hollenberg, LCL, McCoey, JM, de Gille, RW, Nasr, B, Tetienne, J-P, Hall, LT, Simpson, DA, and Hollenberg, LCL

Abstract

Magnetic microparticles or “beads” are used in a variety of research applications from cell sorting through to optical force traction microscopy. The magnetic properties of such particles can be tailored for specific applications with the uniformity of individual beads critical to their function. However, the majority of magnetic characterization techniques quantify the magnetic properties from large bead ensembles. Developing new magnetic imaging techniques to evaluate and visualize the magnetic fields from single beads will allow detailed insight into the magnetic uniformity, anisotropy, and alignment of magnetic domains. Here, diamond‐based magnetic microscopy is applied to image and characterize individual magnetic beads with varying magnetic and structural properties: ferromagnetic and superparamagnetic/paramagnetic, shell (coated with magnetic material), and solid (magnetic material dispersed in matrix). The single‐bead magnetic images identify irregularities in the magnetic profiles from individual bead populations. Magnetic simulations account for the varying magnetic profiles and allow to infer the magnetization of individual beads. Additionally, this work shows that the imaging technique can be adapted to achieve illumination‐free tracking of magnetic beads, opening the possibility of tracking cell movements and mechanics in photosensitive contexts.

Published

2019

6. Nonvanishing effect of detuning errors in dynamical-decoupling-based quantum sensing experiments

Author

Lang, JE, Madhavan, T, Tetienne, J-P, Broadway, DA, Hall, LT, Teraji, T, Monteiro, TS, Stacey, A, Hollenberg, LCL, Lang, JE, Madhavan, T, Tetienne, J-P, Broadway, DA, Hall, LT, Teraji, T, Monteiro, TS, Stacey, A, and Hollenberg, LCL

Abstract

Characteristic dips appear in the coherence traces of a probe qubit when dynamical decoupling (DD) is applied in synchrony with the precession of target nuclear spins, forming the basis for nanoscale nuclear magnetic resonance (NMR). The frequency of the microwave control pulses is chosen to match the qubit transition but this can be detuned from resonance by experimental errors, hyperfine coupling intrinsic to the qubit, or inhomogeneous broadening. The detuning acts as an additional static field which is generally assumed to be completely removed in Hahn echo and DD experiments. Here we demonstrate that this is not the case in the presence of finite pulse-durations, where a detuning can drastically alter the coherence response of the probe qubit, with important implications for sensing applications. Using the electronic spin associated with a nitrogen-vacancy center in diamond as a test qubit system, we analytically and experimentally study the qubit coherence response under CPMG and XY8 dynamical decoupling control schemes in the presence of finite pulse-durations and static detunings. Most striking is the splitting of the NMR resonance under CPMG, whereas under XY8 the amplitude of the NMR signal is modulated. Our work shows that the detuning error must not be neglected when extracting data from quantum sensor coherence traces.

Published

2019

7. Quantum probe hyperpolarisation of molecular nuclear spins

Author

Broadway, DA, Tetienne, J-P, Stacey, A, Wood, JDA, Simpson, DA, Hall, LT, Hollenberg, LCL, Broadway, DA, Tetienne, J-P, Stacey, A, Wood, JDA, Simpson, DA, Hall, LT, and Hollenberg, LCL

Abstract

Hyperpolarisation of nuclear spins is important in overcoming sensitivity and resolution limitations of magnetic resonance imaging and nuclear magnetic resonance spectroscopy. Current hyperpolarisation techniques require high magnetic fields, low temperatures, or catalysts. Alternatively, the emergence of room temperature spin qubits has opened new pathways to achieve direct nuclear spin hyperpolarisation. Employing a microwave-free cross-relaxation induced polarisation protocol applied to a nitrogen vacancy qubit, we demonstrate quantum probe hyperpolarisation of external molecular nuclear spins to ~50% under ambient conditions, showing a single qubit increasing the polarisation of ~106 nuclear spins by six orders of magnitude over the thermal background. Results are verified against a detailed theoretical treatment, which also describes how the system can be scaled up to a universal quantum hyperpolarisation platform for macroscopic samples. Our results demonstrate the prospects for this approach to nuclear spin hyperpolarisation for molecular imaging and spectroscopy and its potential to extend beyond into other scientific areas.

Published

2018

8. High precision single qubit tuning via thermo-magnetic field control

Author

Broadway, DA, Lillie, SE, Dontschuk, N, Stacey, A, Hall, LT, Tetienne, J-P, Hollenberg, LCL, Broadway, DA, Lillie, SE, Dontschuk, N, Stacey, A, Hall, LT, Tetienne, J-P, and Hollenberg, LCL

Abstract

Precise control of the resonant frequency of a spin qubit is of fundamental importance to quantum sensing protocols. We demonstrate a control technique on a single nitrogen-vacancy (NV) centre in diamond where the applied magnetic field is modified by fine-tuning a permanent magnet's magnetisation via temperature control. Through this control mechanism, nanoscale cross-relaxation spectroscopy of both electron and nuclear spins in the vicinity of the NV centre is performed. We then show that through maintaining the magnet at a constant temperature, an order of magnitude improvement in the stability of the NV qubit frequency can be achieved. This improved stability is tested in the polarisation of a small ensemble of nearby 13C spins via resonant cross-relaxation, and the lifetime of this polarisation explored. The effectiveness and relative simplicity of this technique may find use in the realisation of portable spectroscopy and/or hyperpolarisation systems.

Published

2018

9. Proximity-Induced Artefacts in Magnetic Imaging with Nitrogen-Vacancy Ensembles in Diamond

Author

Tetienne, J-P, Broadway, DA, Lillie, SE, Dontschuk, N, Teraji, T, Hall, LT, Stacey, A, Simpson, DA, Hollenberg, LCL, Tetienne, J-P, Broadway, DA, Lillie, SE, Dontschuk, N, Teraji, T, Hall, LT, Stacey, A, Simpson, DA, and Hollenberg, LCL

Abstract

Magnetic imaging with ensembles of nitrogen-vacancy (NV) centres in diamond is a recently developed technique that allows for quantitative vector field mapping. Here we uncover a source of artefacts in the measured magnetic field in situations where the magnetic sample is placed in close proximity (a few tens of nm) to the NV sensing layer. Using magnetic nanoparticles as a test sample, we find that the measured field deviates significantly from the calculated field, in shape, amplitude and even in sign. By modelling the full measurement process, we show that these discrepancies are caused by the limited measurement range of NV sensors combined with the finite spatial resolution of the optical readout. We numerically investigate the role of the stand-off distance to identify an artefact-free regime, and discuss an application to ultrathin materials. This work provides a guide to predict and mitigate proximity-induced artefacts that can arise in NV-based wide-field magnetic imaging, and also demonstrates that the sensitivity of these artefacts to the sample can make them a useful tool for magnetic characterisation.

Published

2018

10. Spin properties of dense near-surface ensembles of nitrogen-vacancy centers in diamond

Author

Tetienne, J-P, de Gille, RW, Broadway, DA, Teraji, T, Lillie, SE, McCoey, JM, Dontschuk, N, Hall, LT, Stacey, A, Simpson, DA, Hollenberg, LCL, Tetienne, J-P, de Gille, RW, Broadway, DA, Teraji, T, Lillie, SE, McCoey, JM, Dontschuk, N, Hall, LT, Stacey, A, Simpson, DA, and Hollenberg, LCL

Abstract

We present a study of the spin properties of dense layers of near-surface nitrogen-vacancy (NV) centers in diamond created by nitrogen ion implantation. The optically detected magnetic resonance contrast and linewidth, spin coherence time, and spin relaxation time, are measured as a function of implantation energy, dose, annealing temperature, and surface treatment. To track the presence of damage and surface-related spin defects, we perform in situ electron spin resonance spectroscopy through both double electron-electron resonance and cross-relaxation spectroscopy on the NV centers. We find that, for the energy (4-30 keV) and dose (5×1011-1013ions/cm2) ranges considered, the NV spin properties are mainly governed by the dose via residual implantation-induced paramagnetic defects, but that the resulting magnetic sensitivity is essentially independent of both dose and energy. We then show that the magnetic sensitivity is significantly improved by high-temperature annealing at ≥1100-C. Moreover, the spin properties are not significantly affected by oxygen annealing, apart from the spin relaxation time, which is dramatically decreased. Finally, the average NV depth is determined by nuclear magnetic resonance measurements, giving ≈10-17 nm at 4-6 keV implantation energy. This study sheds light on the optimal conditions to create dense layers of near-surface NV centers for high-sensitivity sensing and imaging applications.

Published

2018

11. lMicrowave-free nuclear magnetic resonance at molecular scales

Author

Wood, JDA, Tetienne, J-P, Broadway, DA, Hall, LT, Simpson, DA, Stacey, A, Hollenberg, LCL, Wood, JDA, Tetienne, J-P, Broadway, DA, Hall, LT, Simpson, DA, Stacey, A, and Hollenberg, LCL

Abstract

The implementation of nuclear magnetic resonance (NMR) at the nanoscale is a major challenge, as the resolution of conventional methods is limited to mesoscopic scales. Approaches based on quantum spin probes, such as the nitrogen-vacancy (NV) centre in diamond, have achieved nano-NMR under ambient conditions. However, the measurement protocols require application of complex microwave pulse sequences of high precision and relatively high power, placing limitations on the design and scalability of these techniques. Here we demonstrate NMR on a nanoscale organic environment of proton spins using the NV centre while eliminating the need for microwave manipulation of either the NV or the environmental spin states. We also show that the sensitivity of our significantly simplified approach matches that of existing techniques using the NV centre. Removing the requirement for coherent manipulation while maintaining measurement sensitivity represents a significant step towards the development of robust, non-invasive nanoscale NMR probes.

Published

2017

12. Electron paramagnetic resonance microscopy using spins in diamond under ambient conditions

Author

Simpson, DA, Ryan, RG, Hall, LT, Panchenko, E, Drew, SC, Petrou, S, Donnelly, PS, Mulvaney, P, Hollenberg, LCL, Simpson, DA, Ryan, RG, Hall, LT, Panchenko, E, Drew, SC, Petrou, S, Donnelly, PS, Mulvaney, P, and Hollenberg, LCL

Abstract

Magnetic resonance spectroscopy is one of the most important tools in chemical and bio-medical research. However, sensitivity limitations typically restrict imaging resolution to ~ 10 µm. Here we bring quantum control to the detection of chemical systems to demonstrate high-resolution electron spin imaging using the quantum properties of an array of nitrogen-vacancy centres in diamond. Our electron paramagnetic resonance microscope selectively images electronic spin species by precisely tuning a magnetic field to bring the quantum probes into resonance with the external target spins. This provides diffraction limited spatial resolution of the target spin species over a field of view of 50 × 50 µm2 with a spin sensitivity of 104 spins per voxel or ∼100 zmol. The ability to perform spectroscopy and dynamically monitor spin-dependent redox reactions at these scales enables the development of electron spin resonance and zepto-chemistry in the physical and life sciences.Electron paramagnetic resonance spectroscopy has important scientific and medical uses but improving the resolution of conventional methods requires cryogenic, vacuum environments. Simpson et al. show nitrogen vacancy centres can be used for sub-micronmetre imaging with improved sensitivity in ambient conditions.

Published

2017

13. A K-Band Frequency Doubler with 35-dB Fundamental Rejection Based on Novel Transformer Balun in 0.13-μm SiGe Technology

Author

Chakraborty, S, Milner, LE, Zhu, X, Hall, LT, Sevimli, O, and Heimlich, MC

Subjects

Applied Physics

Abstract

© 2016 IEEE. A compact balanced frequency doubler with more than 35 dB odd-harmonic rejection and fractional bandwidth of 73% is presented in this letter. Wide bandwidth and high odd-harmonic suppression is achieved by adopting a new technique for the transformer balun design, resulting in a very low magnitude imbalance of 0.13 dB and a phase imbalance of 0.4° over 7-15 GHz. The balun performance is improved by offsetting the radius of the primary and secondary coils, which reduces the parasitic coupling capacitance. The input and output frequency ranges for the doubler are 7-15 GHz and 14-30 GHz respectively. The circuit was fabricated in 0.13-μm SiGe technology. The chip size is 0.6 mm ×, 0.4 mm.

Published

2016

14. Wide-band nanoscale magnetic resonance spectroscopy using quantum relaxation of a single spin in diamond

Author

Wood, JDA, Broadway, DA, Hall, LT, Stacey, A, Simpson, DA, Tetienne, JP, Hollenberg, LCL, Wood, JDA, Broadway, DA, Hall, LT, Stacey, A, Simpson, DA, Tetienne, JP, and Hollenberg, LCL

Abstract

We demonstrate an all-optical approach of nanoscale magnetic resonance (MR) spectroscopy whereby quantum relaxation (T1) of a single probe spin in diamond is monitored during a precise static magnetic field sweep to construct a spectrum of the surrounding spin environment. The method is inherently noninvasive as it involves no driving fields, and instead relies on the natural resonance between the quantum probe and target spins. As a proof of concept, we measure the T1-MR spectra across a wide band [megahertz (MHz) to gigahertz (GHz)] of a small ensemble of N14 impurities surrounding a single probe spin, providing information on both electron spin transitions (in the GHz range) and nuclear spin transitions (in the MHz range) of the N14 spin targets. Analysis of the T1-MR spectrum reveals that the electron spin transitions are probed via dipole interactions with the probe, while the relatively weak nuclear spin resonances are dramatically enhanced by hyperfine coupling in an electron-mediated process. With a projected sensitivity to external single-proton spins, this work establishes T1-MR as a powerful noninvasive wide-band technique for nanoscale MR spectroscopy.

Published

2016

15. Anticrossing Spin Dynamics of Diamond Nitrogen-Vacancy Centers and All-Optical Low-Frequency Magnetometry

Author

Broadway, DA, Wood, JDA, Hall, LT, Stacey, A, Markham, M, Simpson, DA, Tetienne, J-P, Hollenberg, LCL, Broadway, DA, Wood, JDA, Hall, LT, Stacey, A, Markham, M, Simpson, DA, Tetienne, J-P, and Hollenberg, LCL

Abstract

We investigate the photoinduced spin dynamics of single nitrogen-vacancy (N-V) centers in diamond near the electronic ground-state level anticrossing (GSLAC), which occurs at an axial magnetic field around 1024 G. Using optically detected magnetic resonance spectroscopy, we first find that the electron-spin transition frequency can be tuned down to 100 kHz for the N14-V center, while, for the N15-V center, the transition strength vanishes for frequencies below about 2 MHz owing to the GSLAC structure. Using optical pulses to prepare and read out the spin state, we observe coherent spin oscillations at 1024 G for the N14-V center which originate from spin mixing induced by residual transverse magnetic fields. This effect is responsible for limiting the smallest observable transition frequency, which can span 2 orders of magnitude ranging from 100 kHz to tens of megahertz, depending on the local magnetic noise. A similar feature is observed for the N15-V center at 1024 G. As an application of these findings, we demonstrate all-optical detection and spectroscopy of externally generated fluctuating magnetic fields at frequencies ranging from 8 MHz down to 500 kHz using a N14-V center. Since the Larmor frequency of most nuclear-spin species lies within this frequency range near the GSLAC, these results pave the way towards all-optical, nanoscale nuclear magnetic resonance spectroscopy, using longitudinal spin cross-relaxation.

Published

2016

16. A quantum spin-probe molecular microscope

Author

Perunicic, VS, Hill, CD, Hall, LT, Hollenberg, LCL, Perunicic, VS, Hill, CD, Hall, LT, and Hollenberg, LCL

Abstract

Imaging the atomic structure of a single biomolecule is an important challenge in the physical biosciences. Whilst existing techniques all rely on averaging over large ensembles of molecules, the single-molecule realm remains unsolved. Here we present a protocol for 3D magnetic resonance imaging of a single molecule using a quantum spin probe acting simultaneously as the magnetic resonance sensor and source of magnetic field gradient. Signals corresponding to specific regions of the molecule's nuclear spin density are encoded on the quantum state of the probe, which is used to produce a 3D image of the molecular structure. Quantum simulations of the protocol applied to the rapamycin molecule (C51H79NO13) show that the hydrogen and carbon substructure can be imaged at the angstrom level using current spin-probe technology. With prospects for scaling to large molecules and/or fast dynamic conformation mapping using spin labels, this method provides a realistic pathway for single-molecule microscopy.

Published

2016

17. In vivo imaging and tracking of individual nanodiamonds in drosophila melanogaster embryos

Author

Simpson, DA, Thompson, AJ, Kowarsky, M, Zeeshan, NF, Barson, MSJ, Hall, LT, Yan, Y, Kaufmann, S, Johnson, BC, Ohshima, T, Caruso, F, Scholten, RE, Saint, RB, Murray, MJ, Hollenberg, LCL, Simpson, DA, Thompson, AJ, Kowarsky, M, Zeeshan, NF, Barson, MSJ, Hall, LT, Yan, Y, Kaufmann, S, Johnson, BC, Ohshima, T, Caruso, F, Scholten, RE, Saint, RB, Murray, MJ, and Hollenberg, LCL

Abstract

In this work, we incorporate and image individual fluorescent nanodiamonds in the powerful genetic model system Drosophila melanogaster. Fluorescence correlation spectroscopy and wide-field imaging techniques are applied to individual fluorescent nanodiamonds in blastoderm cells during stage 5 of development, up to a depth of 40 µm. The majority of nanodiamonds in the blastoderm cells during cellularization exhibit free diffusion with an average diffusion coefficient of (6 ± 3) × 10(-3) µm(2)/s, (mean ± SD). Driven motion in the blastoderm cells was also observed with an average velocity of 0.13 ± 0.10 µm/s (mean ± SD) µm/s and an average applied force of 0.07 ± 0.05 pN (mean ± SD). Nanodiamonds in the periplasm between the nuclei and yolk were also found to undergo free diffusion with a significantly larger diffusion coefficient of (63 ± 35) × 10(-3) µm(2)/s (mean ± SD). Driven motion in this region exhibited similar average velocities and applied forces compared to the blastoderm cells indicating the transport dynamics in the two cytoplasmic regions are analogous.

Published

2014

18. Towards single-molecule NMR detection and spectroscopy using single spins in diamond

Author

Perunicic, VS, Hall, LT, Simpson, DA, Hill, CD, Hollenberg, LCL, Perunicic, VS, Hall, LT, Simpson, DA, Hill, CD, and Hollenberg, LCL

Published

2014

19. Analytic solutions to the central-spin problem for nitrogen-vacancy centers in diamond

Author

Hall, LT, Cole, JH, Hollenberg, LCL, Hall, LT, Cole, JH, and Hollenberg, LCL

Published

2014

20. Nanoscale magnetometry through quantum control of nitrogen-vacancy centres in rotationally diffusing nanodiamonds

Author

Maclaurin, D, Hall, LT, Martin, AM, Hollenberg, LCL, Maclaurin, D, Hall, LT, Martin, AM, and Hollenberg, LCL

Published

2013

21. Detection of atomic spin labels in a lipid bilayer using a single-spin nanodiamond probe

Author

Kaufmann, S, Simpson, DA, Hall, LT, Perunicic, V, Senn, P, Steinert, S, McGuinness, LP, Johnson, BC, Ohshima, T, Caruso, F, Wrachtrup, J, Scholten, RE, Mulvaney, P, Hollenberg, L, Kaufmann, S, Simpson, DA, Hall, LT, Perunicic, V, Senn, P, Steinert, S, McGuinness, LP, Johnson, BC, Ohshima, T, Caruso, F, Wrachtrup, J, Scholten, RE, Mulvaney, P, and Hollenberg, L

Abstract

Magnetic field fluctuations arising from fundamental spins are ubiquitous in nanoscale biology, and are a rich source of information about the processes that generate them. However, the ability to detect the few spins involved without averaging over large ensembles has remained elusive. Here, we demonstrate the detection of gadolinium spin labels in an artificial cell membrane under ambient conditions using a single-spin nanodiamond sensor. Changes in the spin relaxation time of the sensor located in the lipid bilayer were optically detected and found to be sensitive to near-individual (4 ± 2) proximal gadolinium atomic labels. The detection of such small numbers of spins in a model biological setting, with projected detection times of 1 s [corresponding to a sensitivity of ∼5 Gd spins per Hz(1/2)], opens a pathway for in situ nanoscale detection of dynamical processes in biology.

Published

2013

22. High spatial and temporal resolution wide-field imaging of neuron activity using quantum NV-diamond

Author

Hall, LT, Beart, GCG, Thomas, EA, Simpson, DA, McGuinness, LP, Cole, JH, Manton, JH, Scholten, RE, Jelezko, F, Wrachtrup, J, Petrou, S, Hollenberg, LCL, Hall, LT, Beart, GCG, Thomas, EA, Simpson, DA, McGuinness, LP, Cole, JH, Manton, JH, Scholten, RE, Jelezko, F, Wrachtrup, J, Petrou, S, and Hollenberg, LCL

Abstract

A quantitative understanding of the dynamics of biological neural networks is fundamental to gaining insight into information processing in the brain. While techniques exist to measure spatial or temporal properties of these networks, it remains a significant challenge to resolve the neural dynamics with subcellular spatial resolution. In this work we consider a fundamentally new form of wide-field imaging for neuronal networks based on the nanoscale magnetic field sensing properties of optically active spins in a diamond substrate. We analyse the sensitivity of the system to the magnetic field generated by an axon transmembrane potential and confirm these predictions experimentally using electronically-generated neuron signals. By numerical simulation of the time dependent transmembrane potential of a morphologically reconstructed hippocampal CA1 pyramidal neuron, we show that the imaging system is capable of imaging planar neuron activity non-invasively at millisecond temporal resolution and micron spatial resolution over wide-fields.

Published

2012

23. Monitoring ion-channel function in real time through quantum decoherence

Author

Hall, LT, Hill, CD, Cole, JH, Staedler, B, Caruso, F, Mulvaney, P, Wrachtrup, J, Hollenberg, LCL, Hall, LT, Hill, CD, Cole, JH, Staedler, B, Caruso, F, Mulvaney, P, Wrachtrup, J, and Hollenberg, LCL

Abstract

In drug discovery, there is a clear and urgent need for detection of cell-membrane ion-channel operation with wide-field capability. Existing techniques are generally invasive or require specialized nanostructures. We show that quantum nanotechnology could provide a solution. The nitrogen-vacancy (NV) center in nanodiamond is of great interest as a single-atom quantum probe for nanoscale processes. However, until now nothing was known about the quantum behavior of a NV probe in a complex biological environment. We explore the quantum dynamics of a NV probe in proximity to the ion channel, lipid bilayer, and surrounding aqueous environment. Our theoretical results indicate that real-time detection of ion-channel operation at millisecond resolution is possible by directly monitoring the quantum decoherence of the NV probe. With the potential to scan and scale up to an array-based system, this conclusion may have wide-ranging implications for nanoscale biology and drug discovery.

Published

2010

24. Cardiovascular lasers: a look into the future.

Author

Hall LT

Published

1990

25. Cost and benefit of military quarantine policies.

Author

Hall, Andrew, Qureshi, Iram, Glaser, Jacob, Auchincloss, Paul, Wilson, Ramey, Hall, Lt Col Andrew, Glaser, C D R Jacob, Auchincloss, M A J Paul, and Wilson, C O L Ramey

Subjects

*MILITARY policy, *COST control, *COVID-19, *QUARANTINE, *MAGNITUDE (Mathematics)

Abstract

The initial response to COVID-19 included quarantine policies. This study aims to determine the infection containment proportions and cost of two variations of quarantine policies based on geographic travel and close contact with infected individuals within deployed US military populations. Special Operations Command Africa (SOCAF) records of individuals quarantined between March 1, 2020 and June 1, 2020 were examined. The infection containment proportion and cost in containment hours were compared between types of quarantine and between geographic areas. Geographic quarantine contained 2 cases out of 63 quarantined individuals in West Africa (3.2%) compared to 0 out of 221 in East Africa (p = 0.0486). Close contact quarantine contained 3 cases out of 31 quarantined individuals in West Africa compared to 4 out of 55 in East Africa (7.3%, p = 0.6989). Total confinement was 42,048 h for each contained infection using geographic quarantine compared to 4076 h using close contact quarantine. In the US military population deployed to Africa for COVID-19, quarantining based on geographic movement is an order of magnitude more costly in terms of time for each contained infection then quarantining based on close contact with infected individuals. There is not a statistical difference between East and West Africa. The associated costs of quarantine must be carefully weighed against the risk of disease spread. [ABSTRACT FROM AUTHOR]

Published

2021

26. Practical multiple-antenna solutions for enhancing adaptive OFDM performance in mm-wave WPANs

Author

I. D. Holland, L. T. Hall, W. G. Cowley, Holland, ID, Hall, LT, and Cowley, WG

Subjects

Computer Networks and Communications, mm-wave, selection diversity, coded OFDM, phased arrays, Electrical and Electronic Engineering, 60 GHz, sectorized

Abstract

The design of short-range high-speed wireless networks for the 60 GHz band requires consideration of factors from a wide range of disciplines. Key system choices that make significant differences to the final cost and performance include the type of antennas, multiple access strategy and channel coding. In this paper we assume a coded orthogonal frequency division multiplexing (OFDM) system providing high-speed communications between low-cost terminals over indoor 60 GHz channels that are frequently non-line-of-sight. Under constraints of low transmit power and high path attenuation, we consider two practical options for using multiple low-cost 'bond-wire' antennas, compared with ideal monopole antennas at each terminal. For specified multiple access and channel coding schemes, we show that a sectorized strategy based on simple 2 element phased arrays can provide substantial benefits in system performance and flexibility

Published

2010

27. Clogged Arteries, Safety Net Holes: Treating an Underinsured Patient for Homozygous Familial Hypercholesterolemia With Plasmapheresis.

Author

Patel P, Alinnor I, Hall MAK, Hall LT, and Watkins S

Abstract

This case report explores the difficulties with rapid lipid-lowering therapies in a resource-limited setting. We present a case of an individual with previously diagnosed homozygous familial hypercholesterolemia presenting with anginal chest pain concerning for non-ST elevation myocardial infarction (NSTEMI), with a low-density lipoprotein (LDL) of 984 mg/dL (reference range: 100-129 mg/dL) and a reversible perfusion defect on his nuclear medicine stress test. In addition to the standard treatment for NSTEMI, including cardiac catheterization, the patient was initiated on a proprotein convertase subtilisin/kexin type 9 inhibitor and underwent two rounds of plasmapheresis, which effectively and rapidly lowered his LDL levels., Competing Interests: Human subjects: Consent was obtained or waived by all participants in this study. Emory University Institutional Review Board issued approval N/A. Conflicts of interest: In compliance with the ICMJE uniform disclosure form, all authors declare the following: Payment/services info: All authors have declared that no financial support was received from any organization for the submitted work. Financial relationships: All authors have declared that they have no financial relationships at present or within the previous three years with any organizations that might have an interest in the submitted work. Other relationships: All authors have declared that there are no other relationships or activities that could appear to have influenced the submitted work., (Copyright © 2024, Patel et al.)

Published

2024

28. Nonmonotonic Superparamagnetic Behavior of the Ferritin Iron Core Revealed via Quantum Spin Relaxometry.

Author

Grant ES, Hall LT, Hollenberg LCL, McColl G, and Simpson DA

Subjects

Iron, Diamond, Magnetic Iron Oxide Nanoparticles, Ferritins, Metalloproteins

Abstract

Ferritin is the primary storage protein in our body and is of significant interest in biochemistry, nanotechnology, and condensed matter physics. More specifically within this sphere of interest are the magnetic properties of the iron core of ferritin, which have been utilized as a contrast agent in applications such as magnetic resonance imaging. This magnetism depends on both the number of iron atoms present, L , and the nature of the magnetic ordering of their electron spins. In this work, we create a series of ferritin samples containing homogeneous iron loads and apply diamond-based quantum spin relaxometry to systematically study their room temperature magnetic properties. We observe anomalous magnetic behavior that can be explained using a theoretical model detailing a morphological change to the iron core occurring at relatively low iron loads. This model provides an L 0.35±0.06 scaling of the uncompensated Fe spins, in agreement with previous theoretical predictions. The necessary inclusion of this morphological change within the model is also supported by electron microscopy studies of ferritin with low iron content. This provides evidence for a magnetic consequence of this morphological change and positions diamond-based quantum spin relaxometry as an effective, noninvasive tool for probing the magnetic properties of metalloproteins. The low detection limit (ferritin 2% loaded at a concentration of 7.5 ± 0.4 μg/mL) also makes this a promising method for precision applications where low analyte concentrations are unavoidable, such as in biological research or even clinical analysis.

Published

2023

29. Advanced Achalasia Mimicking Delayed Gastric Emptying During Standard Gastric Emptying Scintigraphy.

Author

Wu C, Hall LT, and Brandon DC

Subjects

Aged, 80 and over, Gastric Emptying, Humans, Male, Radionuclide Imaging, Tomography, X-Ray Computed, Esophageal Achalasia diagnostic imaging, Gastroparesis diagnostic imaging

Abstract

Abstract: An 82-year-old man underwent outpatient nuclear medicine gastric-emptying scintigraphy (GES) for dysphagia and regurgitation. Standard solid-meal GES showed significant elongated tracer retention with calculated 96% retention rate at 3 hours, with a presumed diagnosis of delayed gastric emptying. Subsequent CT of the chest and abdomen and upper gastrointestinal fluoroscopy instead showed normal size and function of the stomach but an enormously dilated esophagus with food debris, compatible with achalasia. Attention should be made on the location and shape of the visualized "stomach" and recognize that significantly dilated esophagus can mimic an elongated stomach during GES., Competing Interests: Conflicts of interest and sources of funding: none declared., (Copyright © 2022 Wolters Kluwer Health, Inc. All rights reserved.)

Published

2022

30. Molecular Imaging of Brain Metastases with PET

Author

Schroeder HW, Hall LT, and Sergi CM

Abstract

Molecular imaging of brain metastases with positron emission tomography with computed tomography (PET/CT) or with magnetic resonance imaging (PET/MRI) can be performed with a growing number of molecular imaging agents. The most commonly used molecular imaging agent for primary malignancies outside of the brain is a glucose analog radio-labelled with fluorine-18, 18F-fluorodeoxyglucose (18F- FDG), which can be used to identify brain metastases. Likewise, additional molecular imaging agents such as prostate specific membrane antigen (PSMA) ligands (i.e., 68Ga-PSMA-11), alkylphosphocholine analogs (i.e., CLR124/CLR1404), and amino acids (i.e., 11C-MET, 18F-FET, 18F-DOPA, 18F-FACBC) can identify brain metastases. Advantages of PET in brain tumor imaging include co-registration with other imaging technologies, quantitative measurements, and significant potential for improvement in diagnostic accuracy. PET can be used to detect brain metastases while imaging for other sites of metastatic disease, discriminate treatment-related changes from tumor recurrence, and identify patients for targeted radiotherapy from theranostic molecular imaging and targeted radiotherapy agents., (Copyright: The Authors.; The authors confirm that the materials included in this chapter do not violate copyright laws. Where relevant, appropriate permissions have been obtained from the original copyright holder(s), and all original sources have been appropriately acknowledged or referenced.)

Published

2022

31. Acoustomicrofluidic Concentration and Signal Enhancement of Fluorescent Nanodiamond Sensors.

Author

Akther A, Walsh EP, Reineck P, Gibson BC, Ohshima T, Abe H, McColl G, Jenkins NL, Hall LT, Simpson DA, Rezk AR, and Yeo LY

Subjects

Coloring Agents, Ions, Nitrogen, Nanodiamonds

Abstract

Diamond nitrogen-vacancy (NV) centers constitute a promising class of quantum nanosensors owing to the unique magneto-optic properties associated with their spin states. The large surface area and photostability of diamond nanoparticles, together with their relatively low synthesis costs, make them a suitable platform for the detection of biologically relevant quantities such as paramagnetic ions and molecules in solution. Nevertheless, their sensing performance in solution is often hampered by poor signal-to-noise ratios and long acquisition times due to distribution inhomogeneities throughout the analyte sample. By concentrating the diamond nanoparticles through an intense microcentrifugation effect in an acoustomicrofluidic device, we show that the resultant dense NV ensembles within the diamond nanoparticles give rise to an order-of-magnitude improvement in the measured acquisition time. The ability to concentrate nanoparticles under surface acoustic wave (SAW) microcentrifugation in a sessile droplet is, in itself, surprising given the well-documented challenge of achieving such an effect for particles below 1 μm in dimension. In addition to a demonstration of their sensing performance, we thus reveal in this work that the reason why the diamond nanoparticles readily concentrate under the SAW-driven recirculatory flow can be attributed to their considerably higher density and hence larger acoustic contrast compared to those for typical particles and cells for which the SAW microcentrifugation flow has been shown to date.

Published

2021

32. Quantum magnetic imaging of iron organelles within the pigeon cochlea.

Author

de Gille RW, McCoey JM, Hall LT, Tetienne JP, Malkemper EP, Keays DA, Hollenberg LCL, and Simpson DA

Subjects

Animals, Cochlea cytology, Diagnostic Imaging instrumentation, Magnetic Fields, Physical Phenomena, Smart Materials, Cochlea diagnostic imaging, Columbidae physiology, Diagnostic Imaging methods, Iron, Magnetics, Organelles

Abstract

The ability of pigeons to sense geomagnetic fields has been conclusively established despite a notable lack of determination of the underlying biophysical mechanisms. Quasi-spherical iron organelles previously termed "cuticulosomes" in the cochlea of pigeons have potential relevance to magnetoreception due to their location and iron composition; however, data regarding the magnetic susceptibility of these structures are currently limited. Here quantum magnetic imaging techniques are applied to characterize the magnetic properties of individual iron cuticulosomes in situ. The stray magnetic fields emanating from cuticulosomes are mapped and compared to a detailed analytical model to provide an estimate of the magnetic susceptibility of the individual particles. The images reveal the presence of superparamagnetic and ferrimagnetic domains within individual cuticulosomes and magnetic susceptibilities within the range 0.029 to 0.22. These results provide insights into the elusive physiological roles of cuticulosomes. The susceptibilities measured are not consistent with a torque-based model of magnetoreception, placing iron storage and stereocilia stabilization as the two leading putative cuticulosome functions. This work establishes quantum magnetic imaging as an important tool to complement the existing array of techniques used to screen for potential magnetic particle-based magnetoreceptor candidates., Competing Interests: The authors declare no competing interest., (Copyright © 2021 the Author(s). Published by PNAS.)

Published

2021

33. Re-examining ferritin-bound iron: current and developing clinical tools.

Author

Grant ES, Clucas DB, McColl G, Hall LT, and Simpson DA

Subjects

Anemia, Iron-Deficiency diagnosis, Biomarkers, Ferritins, Humans, Iron metabolism, Iron Deficiencies

Abstract

Iron is a highly important metal ion cofactor within the human body, necessary for haemoglobin synthesis, and required by a wide range of enzymes for essential metabolic processes. Iron deficiency and overload both pose significant health concerns and are relatively common world-wide health hazards. Effective measurement of total iron stores is a primary tool for both identifying abnormal iron levels and tracking changes in clinical settings. Population based data is also essential for tracking nutritional trends. This review article provides an overview of the strengths and limitations associated with current techniques for diagnosing iron status, which sets a basis to discuss the potential of a new serum marker - ferritin-bound iron - and the improvement it could offer to iron assessment., (© 2020 Walter de Gruyter GmbH, Berlin/Boston.)

Published

2020

34. [ 124 I]CLR1404 PET/CT in High-Grade Primary and Metastatic Brain Tumors.

Author

Hall LT, Titz B, Baidya N, van der Kolk AG, Robins HI, Otto M, Perlman SB, Weichert JP, and Kuo JS

Subjects

Adult, Aged, Brain diagnostic imaging, Brain Neoplasms pathology, Carcinoma, Renal Cell diagnostic imaging, Carcinoma, Renal Cell secondary, Decision Making, Female, Humans, Image Processing, Computer-Assisted, Magnetic Resonance Imaging, Male, Middle Aged, Predictive Value of Tests, Prognosis, Brain Neoplasms diagnostic imaging, Iodine Radioisotopes, Iodobenzenes, Membrane Microdomains chemistry, Neoplasm Metastasis, Phospholipid Ethers, Positron Emission Tomography Computed Tomography

Abstract

Purpose: There is a continuous search for imaging techniques with high sensitivity and specificity for brain tumors. Positron emission tomography (PET) imaging has shown promise, though many PET agents either have a low tumor specificity or impractical physical half-lives. [ 124 I]CLR1404 is a small molecule alkylphosphocholine analogue that is thought to bind to plasma membrane lipid rafts and has shown high tumor-to-background ratios (TBR) in a previous pilot study in brain tumor patients. This study attempts to define the clinical value of [ 124 I]CLR1404 PET/CT (aka CLR124)., Procedures: Adult patients with new or suspected recurrence of high-grade primary or metastatic brain tumors (N = 27) were injected with [ 124 I]CLR1404 followed by PET/CT at 6, 24, and 48 h. Standard uptake values (SUV) and TBR values were calculated for all time points. Uptake of [ 124 I]CLR1404 was qualitatively assessed, compared with magnetic resonance imaging (MRI), and correlated with clinical outcome. Final diagnosis (N = 25) was established based on surgically resected tissue or long-term follow-up., Results: Positive uptake with high TBR was detected in all but one patient with a final diagnosis of primary/recurrent brain tumor (12/13) and in less than half of patients with treatment-related changes (5/12). Concordance between [ 124 I]CLR1404 uptake and contrast enhancement on MRI was seen in < 40 %, with no concordance between T 2 -hyperintensities and uptake. No significant difference in overall outcome was found between patients with and without [ 124 I]CLR1404 uptake., Conclusions: The uptake pattern in these patients suggests a very high sensitivity of [ 124 I]CLR1404 PET/CT for diagnosing tumor tissue; however, tumor specificity needs to be further defined. Relative lack of concordance with standard MRI characteristics suggests that [ 124 I]CLR1404 PET/CT provides additional information about brain tumors compared to MRI alone, potentially improving clinical decision-making.

Published

2020

35. Quantum Bath Control with Nuclear Spin State Selectivity via Pulse-Adjusted Dynamical Decoupling.

Author

Lang JE, Broadway DA, White GAL, Hall LT, Stacey A, Hollenberg LCL, Monteiro TS, and Tetienne JP

Abstract

Dynamical decoupling (DD) is a powerful method for controlling arbitrary open quantum systems. In quantum spin control, DD generally involves a sequence of timed spin flips (π rotations) arranged to either average out or selectively enhance coupling to the environment. Experimentally, errors in the spin flips are inevitably introduced, motivating efforts to optimize error-robust DD. Here we invert this paradigm: by introducing particular control "errors" in standard DD, namely, a small constant deviation from perfect π rotations (pulse adjustments), we show we obtain protocols that retain the advantages of DD while introducing the capabilities of quantum state readout and polarization transfer. We exploit this nuclear quantum state selectivity on an ensemble of nitrogen-vacancy centers in diamond to efficiently polarize the ^{13}C quantum bath. The underlying physical mechanism is generic and paves the way to systematic engineering of pulse-adjusted protocols with nuclear state selectivity for quantum control applications.

Published

2019

36. Rapid, High-Resolution Magnetic Microscopy of Single Magnetic Microbeads.

Author

McCoey JM, de Gille RW, Nasr B, Tetienne JP, Hall LT, Simpson DA, and Hollenberg LCL

Subjects

Anisotropy, Cell Movement, Physical Phenomena, Magnetics, Microscopy methods, Microspheres

Abstract

Magnetic microparticles or "beads" are used in a variety of research applications from cell sorting through to optical force traction microscopy. The magnetic properties of such particles can be tailored for specific applications with the uniformity of individual beads critical to their function. However, the majority of magnetic characterization techniques quantify the magnetic properties from large bead ensembles. Developing new magnetic imaging techniques to evaluate and visualize the magnetic fields from single beads will allow detailed insight into the magnetic uniformity, anisotropy, and alignment of magnetic domains. Here, diamond-based magnetic microscopy is applied to image and characterize individual magnetic beads with varying magnetic and structural properties: ferromagnetic and superparamagnetic/paramagnetic, shell (coated with magnetic material), and solid (magnetic material dispersed in matrix). The single-bead magnetic images identify irregularities in the magnetic profiles from individual bead populations. Magnetic simulations account for the varying magnetic profiles and allow to infer the magnetization of individual beads. Additionally, this work shows that the imaging technique can be adapted to achieve illumination-free tracking of magnetic beads, opening the possibility of tracking cell movements and mechanics in photosensitive contexts., (© 2019 WILEY-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published

2019

37. Lateralized periodic discharges frequency correlates with glucose metabolism.

Author

Subramaniam T, Jain A, Hall LT, Cole AJ, Westover MB, Rosenthal ES, and Struck AF

Subjects

Adult, Aged, Aged, 80 and over, Brain diagnostic imaging, Electroencephalography, Epilepsies, Partial diagnostic imaging, Epilepsies, Partial metabolism, Epilepsies, Partial physiopathology, Female, Fluorodeoxyglucose F18, Humans, Male, Positron-Emission Tomography, Posterior Leukoencephalopathy Syndrome diagnostic imaging, Posterior Leukoencephalopathy Syndrome metabolism, Posterior Leukoencephalopathy Syndrome physiopathology, Radiopharmaceuticals, Retrospective Studies, Status Epilepticus diagnostic imaging, Status Epilepticus metabolism, Status Epilepticus physiopathology, Stroke diagnostic imaging, Stroke metabolism, Stroke physiopathology, Young Adult, Brain metabolism, Brain physiopathology, Glucose metabolism

Abstract

Objective: To investigate the correlation between characteristics of lateralized periodic discharges (LPDs) and glucose metabolism measured by 18 F-fluorodeoxyglucose (FDG)-PET., Methods: We retrospectively reviewed medical records to identify patients who underwent FDG-PET during EEG monitoring with LPDs present during the FDG uptake period. Two blinded board-certified neurophysiologists independently interpreted EEGs. FDG uptake was measured using standardized uptake value (SUV). Structural images were fused with PET images to aid with localization of SUV. Two PET readers independently measured maximum SUV. Relative SUV values were obtained by normalization of the maximum SUV to the SUV of pons (SUVRpons). LPD frequency was analyzed both as a categorical variable and as a continuous measure. Other secondary variables included duration, amplitude, presence of structural lesion, and "plus" EEG features such as rhythmic or fast sharp activity., Results: Nine patients were identified and 7 had a structural etiology for LPDs. Analysis using frequency as a categorical variable and continuous variable showed an association between increased LPD frequency and increased ipsilateral SUVRpons ( p = 0.02). Metabolism associated with LPDs (0.5 Hz as a baseline) increased by a median of 100% at 1 Hz and for frequencies >1 Hz increased by a median of 309%. There were no statistically significant differences in SUVRpons for other factors including duration ( p = 0.10), amplitude ( p = 0.80), structural etiology ( p = 0.55), or "plus" features such as rhythmic or fast sharp activity ( p = 0.84)., Conclusions: Metabolic activity increases monotonically with LPD frequency. LPD frequency should be a measure of interest when developing neuroprotection strategies in critical neurologic illness., (© 2019 American Academy of Neurology.)

Published

2019

38. Pretreatment CLR 124 Positron Emission Tomography Accurately Predicts CLR 131 Three-Dimensional Dosimetry in a Triple-Negative Breast Cancer Patient.

Author

Besemer AE, Grudzinski JJ, Weichert JP, Hall LT, and Bednarz BP

Subjects

Female, Humans, Pilot Projects, Retrospective Studies, Imaging, Three-Dimensional methods, Iodobenzenes administration & dosage, Phospholipid Ethers administration & dosage, Positron Emission Tomography Computed Tomography methods, Radiopharmaceuticals administration & dosage, Radiotherapy Planning, Computer-Assisted methods, Triple Negative Breast Neoplasms diagnostic imaging, Triple Negative Breast Neoplasms radiotherapy

Abstract

Introduction: CLR1404 is a theranostic molecular agent that can be radiolabeled with 124 I (CLR 124) for positron emission tomography (PET) imaging, or 131 I (CLR 131) for single-photon emission computed tomography (SPECT) imaging and targeted radionuclide therapy. This pilot study evaluated a pretreatment dosimetry methodology in a triple-negative breast cancer patient who was uniquely enrolled in both a CLR 124 PET imaging clinical trial and a CLR 131 therapeutic dose escalation clinical trial., Materials and Methods: Three-dimensional PET/CT images were acquired at 1, 3, 24, 48, and 120 h postinjection of 178 MBq CLR 124. One month later, pretherapy 2D whole-body planar images were acquired at 0.25, 5, 24, 48, and 144 h postinjection of 370 MBq CLR 131. Following the therapeutic administration of 1990 MBq CLR 131, 3D SPECT/CT images were acquired at 74, 147, 334, and 505 h postinjection. The therapeutic CLR 131 voxel-level absorbed dose was estimated from PET (RAPID PET) and SPECT (RAPID SPECT) images using a Geant4-based Monte Carlo dosimetry platform called RAPID (Radiopharmaceutical Assessment Platform for Internal Dosimetry), and region of interest (ROI) mean doses were also estimated using the OLINDA/EXM software based on PET (OLINDA PET), SPECT (OLINDA SPECT), and planar (OLINDA planar) images., Results: The RAPID PET and OLINDA PET tracer-predicted ROI mean doses correlated well (m ≥ 0.631, R 2 ≥ 0.694, p ≤ 0.01) with both the RAPID SPECT and OLINDA SPECT therapeutic mean doses. The 2D planar images did not have any significant correlations. The ROI mean doses differed by -4% to -43% between RAPID and OLINDA/EXM, and by -19% to 29% between PET and SPECT. The 3D dose distributions and dose volume histograms calculated with RAPID were similar for the PET/CT and SPECT/CT., Conclusions: This pilot study demonstrated that CLR 124 pretreatment PET images can be used to predict CLR 131 3D therapeutic dosimetry better than CLR 131 2D planar images. In addition, unlike OLINDA/EXM, Monte Carlo dosimetry methods were capable of accurately predicting dose heterogeneity, which is important for predicting dose-response relationships and clinical outcomes.

Published

2019

39. Enhanced Radiosensitivity in Solid Tumors using a Tumor-selective Alkyl Phospholipid Ether Analog.

Author

Elsaid MY, Shahi A, Wang AR, Baiu DC, Li C, Werner LR, Singhal S, Hall LT, Weichert JP, Armstrong EA, Bednarz BP, Harari PM, Iyer G, and Otto M

Subjects

Animals, Cell Line, Tumor, Cell Proliferation drug effects, Cell Proliferation radiation effects, Cell Survival drug effects, Cell Survival radiation effects, Clone Cells, DNA Damage, Histones metabolism, Humans, Mice, Nude, X-Rays, Xenograft Model Antitumor Assays, Neoplasms pathology, Phospholipid Ethers pharmacology, Radiation Tolerance drug effects, Radiation Tolerance radiation effects

Abstract

Antitumor alkyl phospholipid (APL) analogs comprise a group of structurally related molecules with remarkable tumor selectivity. Some of these compounds have shown radiosensitizing capabilities. CLR127 is a novel, clinical-grade antitumor APL ether analog, a subtype of synthetic APL broadly targeting cancer cells with limited uptake in normal tissues. The purpose of this study was to investigate the effect of CLR127 to modulate radiation response across several adult and pediatric cancer types in vitro as well as in murine xenograft models of human prostate adenocarcinoma, neuroblastoma, Ewing sarcoma, and rhabdomyosarcoma. In vitro , CLR127 demonstrated selective uptake in cancer cells compared to normal cells. In cancer cells, CLR127 treatment prior to radiation significantly decreased clonogenic survival in vitro , and led to increased radiation-induced double-stranded DNA (dsDNA) breakage compared with radiation alone, which was not observed in normal controls. In animal models, CLR127 effectively increased the antitumor response to fractionated radiotherapy and led to delayed tumor regrowth at potentially clinically achievable doses. In conclusion, our study highlights the ability of CLR127 to increase radiation response in several cancer types. Given almost universal uptake of CLR127 in malignant cells, future research should test whether the observed effects can be extended to other tumor types. Our data provide a strong rationale for clinical testing of CLR127 as a tumor-targeted radiosensitizing agent. Mol Cancer Ther; 17(11); 2320-8. ©2018 AACR ., (©2018 American Association for Cancer Research.)

Published

2018

40. Development and Validation of RAPID: A Patient-Specific Monte Carlo Three-Dimensional Internal Dosimetry Platform.

Author

Besemer AE, Yang YM, Grudzinski JJ, Hall LT, and Bednarz BP

Subjects

Humans, Imaging, Three-Dimensional methods, Radiopharmaceuticals therapeutic use, Radiotherapy Planning, Computer-Assisted methods

Abstract

This work describes the development and validation of a patient-specific Monte Carlo internal dosimetry platform called RAPID (Radiopharmaceutical Assessment Platform for Internal Dosimetry). RAPID utilizes serial PET/CT or SPECT/CT images to calculate voxelized three-dimensional (3D) internal dose distributions with the Monte Carlo code Geant4. RAPID's dosimetry calculations were benchmarked against previously published S-values and specific absorbed fractions (SAFs) calculated for monoenergetic photon and electron sources within the Zubal phantom and for S-values calculated for a variety of radionuclides within spherical tumor phantoms with sizes ranging from 1 to 1000 g. The majority of the S-values and SAFs calculated in the Zubal Phantom were within 5% of the previously published values with the exception of a few 10 keV photon SAFs that agreed within 10%, and one value within 16%. The S-values calculated in the spherical tumor phantoms agreed within 2% for 177 Lu, 131 I, 125 I, 18 F, and 64 Cu, within 3.5% for 211 At and 213 Bi, within 6.5% for 153 Sm, 111 In, 89 Zr, and 223 Ra, and within 9% for 90 Y, 68 Ga, and 124 I. In conclusion, RAPID is capable of calculating accurate internal dosimetry at the voxel-level for a wide variety of radionuclides and could be a useful tool for calculating patient-specific 3D dose distributions.

Published

2018

41. Proximity-Induced Artefacts in Magnetic Imaging with Nitrogen-Vacancy Ensembles in Diamond.

Author

Tetienne JP, Broadway DA, Lillie SE, Dontschuk N, Teraji T, Hall LT, Stacey A, Simpson DA, and Hollenberg LCL

Abstract

Magnetic imaging with ensembles of nitrogen-vacancy (NV) centres in diamond is a recently developed technique that allows for quantitative vector field mapping. Here we uncover a source of artefacts in the measured magnetic field in situations where the magnetic sample is placed in close proximity (a few tens of nm) to the NV sensing layer. Using magnetic nanoparticles as a test sample, we find that the measured field deviates significantly from the calculated field, in shape, amplitude and even in sign. By modelling the full measurement process, we show that these discrepancies are caused by the limited measurement range of NV sensors combined with the finite spatial resolution of the optical readout. We numerically investigate the role of the stand-off distance to identify an artefact-free regime, and discuss an application to ultrathin materials. This work provides a guide to predict and mitigate proximity-induced artefacts that can arise in NV-based wide-field magnetic imaging, and also demonstrates that the sensitivity of these artefacts to the sample can make them a useful tool for magnetic characterisation., Competing Interests: The authors declare no conflict of interest.

Published

2018

42. Quantum probe hyperpolarisation of molecular nuclear spins.

Author

Broadway DA, Tetienne JP, Stacey A, Wood JDA, Simpson DA, Hall LT, and Hollenberg LCL

Abstract

Hyperpolarisation of nuclear spins is important in overcoming sensitivity and resolution limitations of magnetic resonance imaging and nuclear magnetic resonance spectroscopy. Current hyperpolarisation techniques require high magnetic fields, low temperatures, or catalysts. Alternatively, the emergence of room temperature spin qubits has opened new pathways to achieve direct nuclear spin hyperpolarisation. Employing a microwave-free cross-relaxation induced polarisation protocol applied to a nitrogen vacancy qubit, we demonstrate quantum probe hyperpolarisation of external molecular nuclear spins to ~50% under ambient conditions, showing a single qubit increasing the polarisation of ~10 6 nuclear spins by six orders of magnitude over the thermal background. Results are verified against a detailed theoretical treatment, which also describes how the system can be scaled up to a universal quantum hyperpolarisation platform for macroscopic samples. Our results demonstrate the prospects for this approach to nuclear spin hyperpolarisation for molecular imaging and spectroscopy and its potential to extend beyond into other scientific areas.

Published

2018

43. Thalamic and basal ganglia metabolism on interictal 18 F-FDG PET in temporal lobe epilepsy: an SUV-based analysis.

Author

Jain A, Struck AF, Woo KM, Jaskowiak CJ, and Hall LT

Abstract

The aim of this study was to investigate thalamic and basal ganglia (BG) metabolism in temporal lobe epilepsy (TLE) on interictal 18 F-FDG PET using standardized uptake value (SUV). Retrospective review of data was undertaken for patients who were surgically treated for medically intractable TLE. All patients underwent 18 F-FDG PET, MRI brain and EEG as preoperative workup, and subsequently underwent temporal lobe resection. Postoperative outcomes were analyzed as without or with residual disabling seizures. SUV max and SUV peak values were calculated for thalamus and BG. Subgroup comparisons were performed with non-parametric tests. Study sample consisted of 33 patients (58% female; mean age 44.7 years) and 33 age- and sex-matched controls. Mean SUV peak for both right and left thalamus was significantly lower in TLE than controls (8.1 ± 1.9 vs. 9.7 ± 2.9 and 8.1 ± 1.9 vs. 9.8 ± 2.9, respectively, both p=0.035). Mean SUV peak for thalamus on the epileptogenic side was overall significantly lower than the contralateral side (8.0 ± 2.0 vs. 8.3 ± 2.0, p=0.040). One (3%) patient with MRI- and EEG-congruent left TLE showed marked left thalamic hypometabolism as the only finding on PET. There was no evidence of basal ganglia hypometabolism. No correlation was noted between thalamic metabolic asymmetry and postoperative outcomes. Thalamic metabolism was significantly reduced in patients with TLE compared to controls, and on the epileptogenic compared to the contralateral side among patients. Thalamic hypometabolism can have value in seizure focus localization in patients without interictal temporal hypometabolism., Competing Interests: None.

Published

2018

44. Targeted Molecular Radiotherapy of Pediatric Solid Tumors Using a Radioiodinated Alkyl-Phospholipid Ether Analog.

Author

Baiu DC, Marsh IR, Boruch AE, Shahi A, Bhattacharya S, Jeffery JJ, Zhao Q, Hall LT, Weichert JP, Bednarz BP, and Otto M

Subjects

Alkylation, Animals, Biological Transport, Cell Line, Tumor, Cell Transformation, Neoplastic, Child, Humans, Iodobenzenes metabolism, Mice, Neoplasms diagnostic imaging, Neoplasms metabolism, Neoplasms pathology, Phospholipid Ethers metabolism, Positron Emission Tomography Computed Tomography, Survival Analysis, Iodobenzenes chemistry, Iodobenzenes therapeutic use, Neoplasms radiotherapy, Phospholipid Ethers chemistry, Phospholipid Ethers therapeutic use

Abstract

External-beam radiotherapy plays a critical role in the treatment of most pediatric solid tumors. Particularly in children, achieving an optimal therapeutic index to avoid damage to normal tissue is extremely important. Consequently, in metastatic disease, the utility of external-beam radiotherapy is limited. Molecular radiotherapy with tumor-targeted radionuclides may overcome some of these challenges, but to date there exists no single cancer-selective agent capable of treating various pediatric malignancies independently of their histopathologic origin. We tested the therapeutic potential of the clinical-grade alkyl-phospholipid ether analog CLR1404, 18-( p -iodophenyl)octadecyl phosphocholine, as a scaffold for tumor-targeted radiotherapy of pediatric malignancies. Methods: Uptake of CLR1404 by pediatric solid tumor cells was tested in vitro by flow cytometry and in vivo by PET/CT imaging and dosimetry. The therapeutic potential of 131 I-CLR1404 was evaluated in xenograft models. Results: In vitro, fluorescent CLR1404-BODIPY showed significant selective uptake in a variety of pediatric cancer lines compared with normal controls. In vivo tumor-targeted uptake in mouse xenograft models using 124 I-CLR1404 was confirmed by imaging. Single-dose intravenous injection of 131 I-CLR1404 significantly delayed tumor growth in all rodent pediatric xenograft models and extended animal survival while demonstrating a favorable side effect profile. Conclusion: 131 I-CLR1404 has the potential to become a tumor-targeted radiotherapeutic drug with broad applicability in pediatric oncology. Because 131 I-CLR1404 has entered clinical trials in adults, our data warrant the development of pediatric clinical trials for this particularly vulnerable patient population., (© 2018 by the Society of Nuclear Medicine and Molecular Imaging.)

Published

2018

45. Non-Neurotoxic Nanodiamond Probes for Intraneuronal Temperature Mapping.

Author

Simpson DA, Morrisroe E, McCoey JM, Lombard AH, Mendis DC, Treussart F, Hall LT, Petrou S, and Hollenberg LCL

Abstract

Optical biomarkers have been used extensively for intracellular imaging with high spatial and temporal resolution. Extending the modality of these probes is a key driver in cell biology. In recent years, the nitrogen-vacancy (NV) center in nanodiamond has emerged as a promising candidate for bioimaging and biosensing with low cytotoxicity and stable photoluminescence. Here we study the electrophysiological effects of this quantum probe in primary cortical neurons. Multielectrode array recordings across five replicate studies showed no statistically significant difference in 25 network parameters when nanodiamonds are added at varying concentrations over various time periods, 12-36 h. The physiological validation motivates the second part of the study, which demonstrates how the quantum properties of these biomarkers can be used to report intracellular information beyond their location and movement. Using the optically detected magnetic resonance from the nitrogen-vacancy defects within the nanodiamonds we demonstrate enhanced signal-to-noise imaging and temperature mapping from thousands of nanodiamond probes simultaneously. This work establishes nanodiamonds as viable multifunctional intraneuronal sensors with nanoscale resolution, which may ultimately be used to detect magnetic and electrical activity at the membrane level in excitable cellular systems.

Published

2017

46. Electron paramagnetic resonance microscopy using spins in diamond under ambient conditions.

Author

Simpson DA, Ryan RG, Hall LT, Panchenko E, Drew SC, Petrou S, Donnelly PS, Mulvaney P, and Hollenberg LCL

Abstract

Magnetic resonance spectroscopy is one of the most important tools in chemical and bio-medical research. However, sensitivity limitations typically restrict imaging resolution to ~ 10 µm. Here we bring quantum control to the detection of chemical systems to demonstrate high-resolution electron spin imaging using the quantum properties of an array of nitrogen-vacancy centres in diamond. Our electron paramagnetic resonance microscope selectively images electronic spin species by precisely tuning a magnetic field to bring the quantum probes into resonance with the external target spins. This provides diffraction limited spatial resolution of the target spin species over a field of view of 50 × 50 µm 2 with a spin sensitivity of 10 4 spins per voxel or ∼100 zmol. The ability to perform spectroscopy and dynamically monitor spin-dependent redox reactions at these scales enables the development of electron spin resonance and zepto-chemistry in the physical and life sciences.Electron paramagnetic resonance spectroscopy has important scientific and medical uses but improving the resolution of conventional methods requires cryogenic, vacuum environments. Simpson et al. show nitrogen vacancy centres can be used for sub-micronmetre imaging with improved sensitivity in ambient conditions.

Published

2017

47. PET/CT imaging of the diapeutic alkylphosphocholine analog 124 I-CLR1404 in high and low-grade brain tumors.

Author

Hall LT, Titz B, Robins HI, Bednarz BP, Perlman SB, Weichert JP, and Kuo JS

Abstract

CLR1404 is a cancer-selective alkyl phosphocholine (APC) analog that can be radiolabeled with 124 I for PET imaging, 131 I for targeted radiotherapy and/or SPECT imaging, or 125 I for targeted radiotherapy. Studies have demonstrated avid CLR1404 uptake and prolonged retention in a broad spectrum of preclinical tumor models. The purpose of this pilot trial was to demonstrate avidity of 124 I-CLR1404 in human brain tumors and develop a framework to evaluate this uptake for use in larger studies. 12 patients (8 men and 4 women; mean age of 43.9 ± 15.1 y; range 23-66 y) with 13 tumors were enrolled. Eleven patients had suspected tumor recurrence and 1 patient had a new diagnosis of high grade tumor. Patients were injected with 185 MBq ± 10% of 124 I-CLR1404 followed by PET/CT imaging at 6-, 24-, and 48-hour. 124 I-CLR1404 PET uptake was assessed qualitatively and compared with MRI. After PET image segmentation SUV values and tumor to background ratios were calculated. There was no significant uptake of 124 I-CLR1404 in normal brain. In tumors, uptake tended to increase to 48 hours. Positive uptake was detected in 9 of 13 lesions: 5/5 high grade tumors, 1/2 low grade tumors, 1/1 meningioma, and 2/4 patients with treatment related changes. 124 I-CLR1404 uptake was not detected in 1/2 low grade tumors, 2/4 lesions from treatment related changes, and 1/1 indeterminate lesion. For 6 malignant tumors, the average tumor to background ratios (TBR) were 9.32 ± 4.33 (range 3.46 to 15.42) at 24 hours and 10.04 ± 3.15 (range 5.17 to 13.17) at 48 hours. For 2 lesions from treatment related change, the average TBR were 5.05 ± 0.4 (range 4.76 to 5.33) at 24 hours and 4.88 ± 1.19 (range 4.04 to 5.72) at 48 hours. PET uptake had areas of both concordance and discordance compared with MRI. 124 I-CLR1404 PET demonstrated avid tumor uptake in a variety of brain tumors with high tumor-to-background ratios. There were regions of concordance and discordance compared with MRI, which has potential clinical relevance. Expansion of these studies is required to determine the clinical significance of the 124 I-CLR1404 PET findings., Competing Interests: None.

Published

2017

48. Impact of PET and MRI threshold-based tumor volume segmentation on patient-specific targeted radionuclide therapy dosimetry using CLR1404.

Author

Besemer AE, Titz B, Grudzinski JJ, Weichert JP, Kuo JS, Robins HI, Hall LT, and Bednarz BP

Subjects

Humans, Multimodal Imaging methods, Neoplasms pathology, Radiometry methods, Tumor Burden, Iodobenzenes therapeutic use, Magnetic Resonance Imaging methods, Monte Carlo Method, Neoplasms diagnostic imaging, Neoplasms radiotherapy, Phospholipid Ethers therapeutic use, Positron-Emission Tomography methods

Abstract

Variations in tumor volume segmentation methods in targeted radionuclide therapy (TRT) may lead to dosimetric uncertainties. This work investigates the impact of PET and MRI threshold-based tumor segmentation on TRT dosimetry in patients with primary and metastatic brain tumors. In this study, PET/CT images of five brain cancer patients were acquired at 6, 24, and 48 h post-injection of 124 I-CLR1404. The tumor volume was segmented using two standardized uptake value (SUV) threshold levels, two tumor-to-background ratio (TBR) threshold levels, and a T1 Gadolinium-enhanced MRI threshold. The dice similarity coefficient (DSC), jaccard similarity coefficient (JSC), and overlap volume (OV) metrics were calculated to compare differences in the MRI and PET contours. The therapeutic 131 I-CLR1404 voxel-level dose distribution was calculated from the 124 I-CLR1404 activity distribution using RAPID, a Geant4 Monte Carlo internal dosimetry platform. The TBR, SUV, and MRI tumor volumes ranged from 2.3-63.9 cc, 0.1-34.7 cc, and 0.4-11.8 cc, respectively. The average  ±  standard deviation (range) was 0.19  ±  0.13 (0.01-0.51), 0.30  ±  0.17 (0.03-0.67), and 0.75  ±  0.29 (0.05-1.00) for the JSC, DSC, and OV, respectively. The DSC and JSC values were small and the OV values were large for both the MRI-SUV and MRI-TBR combinations because the regions of PET uptake were generally larger than the MRI enhancement. Notable differences in the tumor dose volume histograms were observed for each patient. The mean (standard deviation) 131 I-CLR1404 tumor doses ranged from 0.28-1.75 Gy GBq -1 (0.07-0.37 Gy GBq -1 ). The ratio of maximum-to-minimum mean doses for each patient ranged from 1.4-2.0. The tumor volume and the interpretation of the tumor dose is highly sensitive to the imaging modality, PET enhancement metric, and threshold level used for tumor volume segmentation. The large variations in tumor doses clearly demonstrate the need for standard protocols for multimodality tumor segmentation in TRT dosimetry.

Published

2017

49. Microwave-free nuclear magnetic resonance at molecular scales.

Author

Wood JDA, Tetienne JP, Broadway DA, Hall LT, Simpson DA, Stacey A, and Hollenberg LCL

Abstract

The implementation of nuclear magnetic resonance (NMR) at the nanoscale is a major challenge, as the resolution of conventional methods is limited to mesoscopic scales. Approaches based on quantum spin probes, such as the nitrogen-vacancy (NV) centre in diamond, have achieved nano-NMR under ambient conditions. However, the measurement protocols require application of complex microwave pulse sequences of high precision and relatively high power, placing limitations on the design and scalability of these techniques. Here we demonstrate NMR on a nanoscale organic environment of proton spins using the NV centre while eliminating the need for microwave manipulation of either the NV or the environmental spin states. We also show that the sensitivity of our significantly simplified approach matches that of existing techniques using the NV centre. Removing the requirement for coherent manipulation while maintaining measurement sensitivity represents a significant step towards the development of robust, non-invasive nanoscale NMR probes.

Published

2017

50. A quantum spin-probe molecular microscope.

Author

Perunicic VS, Hill CD, Hall LT, and Hollenberg LC

Abstract

Imaging the atomic structure of a single biomolecule is an important challenge in the physical biosciences. Whilst existing techniques all rely on averaging over large ensembles of molecules, the single-molecule realm remains unsolved. Here we present a protocol for 3D magnetic resonance imaging of a single molecule using a quantum spin probe acting simultaneously as the magnetic resonance sensor and source of magnetic field gradient. Signals corresponding to specific regions of the molecule's nuclear spin density are encoded on the quantum state of the probe, which is used to produce a 3D image of the molecular structure. Quantum simulations of the protocol applied to the rapamycin molecule (C 51 H 79 NO 13 ) show that the hydrogen and carbon substructure can be imaged at the angstrom level using current spin-probe technology. With prospects for scaling to large molecules and/or fast dynamic conformation mapping using spin labels, this method provides a realistic pathway for single-molecule microscopy.

Published

2016