Mapping B1-induced eddy current effects near metallic structures in MR images: A comparison of simulation and experiment

Vashaee, Sarah; Goora, Frédéric G.; Britton, Melanie M.; Newling, Benedict; Balcom, Bruce J.

doi:10.1016/j.jmr.2014.10.016

Cited by 36 publications

(23 citation statements)

References 42 publications

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“…Possible signal alterations due to eddy currents or RF shielding induced in the solid markers were not considered. Given the size and composition of fiducial markers tested, this effect is expected to be secondary relative to the susceptibility induced

T_{2}^{*}

reduction effect . Eddy currents resulting from changing RF field are, however, very likely the main source of the Gold Anchor™ signal voids observed in SE sequences (as seen in Fig.…”

Section: Discussionmentioning

confidence: 99%

Quantification of MRI visibility and artifacts at 3T of liquid fiducial marker in a pancreas tissue‐mimicking phantom

et al. 2017

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The liquid fiducial marker causes signal voids on MRI due to its absence of water hydrogen atoms without strongly affecting the magnetic field in the surrounding tissue. The alteration of the static magnetic field was found to be the main effect leading to the visibility of the solid fiducial markers. Hence, especially when a low level of image distortion is required, MRI characteristics of the liquid marker surpass those of solid gold markers currently being used for IGRT of PDAC.

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T_{2}^{*}

reduction effect . Eddy currents resulting from changing RF field are, however, very likely the main source of the Gold Anchor™ signal voids observed in SE sequences (as seen in Fig.…”

Section: Discussionmentioning

confidence: 99%

Quantification of MRI visibility and artifacts at 3T of liquid fiducial marker in a pancreas tissue‐mimicking phantom

et al. 2017

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“…Dirichlet boundary conditions were used on the surface of the sphere to specify the incoming field, H in 1 = ð0,1,0Þ, whereas perfect conductor boundary conditions were used on the surface of the dendrite. When using calculations with finite conductivity, the magnitude of an object's conductivity has a negligible effect on B 1 distortions (12,27). The computations were performed in the rotating frame at a frequency of 400 MHz (the Larmor frequency of 1 H in the MRI experiments) using the BiCGStab solver.…”

Section: Methodsmentioning

confidence: 99%

Real-time 3D imaging of microstructure growth in battery cells using indirect MRI

Ilott

Mohammadi

Chang

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

135

102

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Lithium metal is a promising anode material for Li-ion batteries due to its high theoretical specific capacity and low potential. The growth of dendrites is a major barrier to the development of high capacity, rechargeable Li batteries with lithium metal anodes, and hence, significant efforts have been undertaken to develop new electrolytes and separator materials that can prevent this process or promote smooth deposits at the anode. Central to these goals, and to the task of understanding the conditions that initiate and propagate dendrite growth, is the development of analytical and nondestructive techniques that can be applied in situ to functioning batteries. MRI has recently been demonstrated to provide noninvasive imaging methodology that can detect and localize microstructure buildup. However, until now, monitoring dendrite growth by MRI has been limited to observing the relatively insensitive metal nucleus directly, thus restricting the temporal and spatial resolution and requiring special hardware and acquisition modes. Here, we present an alternative approach to detect a broad class of metallic dendrite growth via the dendrites' indirect effects on the surrounding electrolyte, allowing for the application of fast 3D 1 H MRI experiments with high resolution. We use these experiments to reconstruct 3D images of growing Li dendrites from MRI, revealing details about the growth rate and fractal behavior. Radiofrequency and static magnetic field calculations are used alongside the images to quantify the amount of the growing structures.Li-ion batteries | in situ MRI | dendrite growth L ithium metal is a promising anode material for secondary lithium batteries because it has the highest theoretical specific capacity of possible anode materials (3,860 mAh/g), and the most negative voltage. The metal's use is currently limited due to irregular microstructure buildup on the electrode during charging (1). These mossy, needle-like, or dendritic structures severely compromise battery performance and can eventually penetrate the separator and cause overheating and short circuiting, thus presenting serious safety concerns. Preventing dendrite growth has proven to be extremely challenging, due in part to the current poor understanding of the conditions under which the dendrites' growth is initiated and the factors that contribute to their continued growth (2, 3). The development of new analytical techniques that are sensitive to dendrite growth and amenable to studying electrochemical cells in situ is crucial to future efforts of improving battery designs and performance (4, 5).In situ NMR spectroscopy and MRI are powerful noninvasive methods that can provide time-resolved and quantitative information about the changes within the electrolyte and the electrodes. NMR measurements are sensitive to dendrite growth and are also able to resolve different lithium microstructure morphologies through chemical shift measurements (6-9). MRI approaches provide additional spatial information, allowing specific structural changes ...

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“…These stents are known to cause artifacts 21,22 such as susceptibility artifacts, 23 gradient-induced artifacts, 24,25 and radio frequency (RF)induced artifacts (also known as RF-shielding). [26][27][28][29] As the stent is placed in the vicinity of the tumor, 30 MRI artifacts caused by these stents may hinder tumor delineation.…”

Section: Introductionmentioning

confidence: 99%

Quantitative assessment of biliary stent artifacts on MR images: Potential implications for target delineation in radiotherapy

et al. 2016

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Mapping B1-induced eddy current effects near metallic structures in MR images: A comparison of simulation and experiment

Cited by 36 publications

References 42 publications

Quantification of MRI visibility and artifacts at 3T of liquid fiducial marker in a pancreas tissue‐mimicking phantom

Quantification of MRI visibility and artifacts at 3T of liquid fiducial marker in a pancreas tissue‐mimicking phantom

Real-time 3D imaging of microstructure growth in battery cells using indirect MRI

Quantitative assessment of biliary stent artifacts on MR images: Potential implications for target delineation in radiotherapy

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