Wireless coils based on resonant and nonresonant coupled‐wire structure for small animal multinuclear imaging

Gomez, Tania S. Vergara; Dubois, Marc; Glybovski, Stanislav; Larrat, Benoît; Rosny, Julien de; Rockstuhl, Carsten; Bernard, Monique; Abdeddaïm, Redha; Enoch, Stefan; Kober, Frank

doi:10.1002/nbm.4079

Cited by 14 publications

(12 citation statements)

References 24 publications

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“…It has been shown recently that the distribution of currents within the components of the coil plays an important role in the resulting B1 + field distribution [18]. A matched loop presents higher current amplitude compared to a feed loop, therefore the B1 + magnitude in case A is high but localized, compared to cases B and B with capacitors, where the B1 + field is more homogeneous as shown in the simulations (Figures 2 and 3).…”

Section: Discussionmentioning

confidence: 53%

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RF Coils for Preclinical Multinuclear Imaging Based on Coupled-wire Structures Working in Resonant and Non-resonant Regime

Gomez¹,

Kober²,

Dubois³

et al. 2019

2019 PhotonIcs &Amp; Electromagnetics Research Symposium - Spring (PIERS-Spring)

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Passive inductive metamaterials have been explored as alternative radio frequency (RF) coils for magnetic resonance imaging (MRI) with the aim to control and optimize the imaged volume and the sensitivity independently. Nevertheless, such structures result in a low signal-to-noise ratio (SNR) since the contribution of the loop in the global performance of the coil is reduced. Therefore, the purpose of this work is to explore a new strategy by combining off-resonance metamaterials with a resonant surface coil and observe the advantages that can be obtained. An elementary structure consisting of two parallel off-resonance wires coupled with a resonant surface coil was numerically analyzed. For experimental characterization, a prototype was built and tested in a 7 T MRI scanner for proton ( 1 H) and fluorine ( 19 F) using a phantom. In addition, other coil setups were tested for reference and comparison in terms of B1 + magnetic field homogeneity, signal and noise. The resultsshow that with this new strategy a conventional surface coil can be optimized in terms of sensitive volume while maintaining its high SNR. Metamaterials permit a customized adjustment of volume and sensitivity in addition to the simple adaptation to other nuclei, making them beneficial elements in the design of RF coils.

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Section: Discussionmentioning

confidence: 53%

“…However, their sensitivity extends along the whole phantom ( Figure 3B). This can be linked to the currents flowing inside the loop and the wires in each case [18]. Case C seems to maintain a high B1 + magnitude (25 µT), similar to case A (26 µT), in addition to a horizontal extension of the field.…”

Section: Mri Experimentsmentioning

confidence: 89%

RF Coils for Preclinical Multinuclear Imaging Based on Coupled-wire Structures Working in Resonant and Non-resonant Regime

Gomez¹,

Kober²,

Dubois³

et al. 2019

2019 PhotonIcs &Amp; Electromagnetics Research Symposium - Spring (PIERS-Spring)

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“…For our example the value ܸ = 10 ି V has been adopted. Other quantities: ݂ = 4.45 ‫ݖܪܯ‬ ܳ = 250 is quality factor of the unloaded coil ܺ = ߱ ‫ܮ‬ = 75 Ω is reactance of the coil ܴ ௨௧ is output resistance of the tuning and matching circuit, corresponding to ܴ ܴ = ఠ బ ொ is resistance of the unloaded coil Values of the capacitances ‫ܥ‬ ଵ and ‫ܥ‬ ଶ are given by (10) and (11): Auxiliary voltage ܸ ଷ is given by (12):…”

Section: Resultsmentioning

confidence: 99%

Sensitivity Analysis of the Simply Noise-matched Receiving Coil for NMR Experiments

Andris

Frollo

2020

Measurement Science Review

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The article analyzes the sensitivity of unmatched receiving coil for the NMR scanner. Receiver of the scanner was investigated from the point of view of noise features. Theory of the noise figure has been modified to utilize the receiver for digitization of its own noise and the noise figure calculation. The resulting noise figure has been measured with different source impedances and the optimal value has been acquired. Influence of the noise figure on the resulting signal-to-noise ratio has been calculated for the sensitivity judgement. The output SNR has been investigated for constant input SNR as well as for constant input voltage. Many results are depicted in figures. Also examples of theoretical results are depicted graphically.

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“…The values of the quadrupole and magnetic dipole moments in this mode are balanced that makes the electric quadrupole (off-diagonal) and magnetic dipole not distinguishable in what concerns their electromagnetic fields the central transverse plane (H-plane of the array) [30]. Therefore, the currents of this mode create in the transverse plane the near magnetic field identical to that of a horizontal loop of the same length [31], [32]. This field is presented in the bottom panel of As we expected, when the mode order increases the corresponding electromagnetic field better concentrates around the MS.…”

Section: Decoupling By the Metasurface A Metasurface Decouplingmentioning

confidence: 99%

Decoupling of Closely Spaced Dipole Antennas for Ultrahigh Field MRI With Metasurfaces

Hurshkainen

Mollaei

Dubois

et al. 2021

IEEE Trans. Antennas Propagat.

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Phased antenna arrays of dipoles are widely used in ultra-high field magnetic resonance imaging for creating the controllable radio-frequency magnetic field distributions in a human body. Due to safety and imaging quality reasons each individual channel of the array should be decoupled-electromagnetically isolated from the others. The required number of channels is large and in some techniques the dipole antennas should be located in the close proximity of the human body. Their ultimately dense arrangement leads to a strong mutual coupling and makes the conventional decoupling structures inefficient. This coupling needs to be suppressed without a significant distortion of radio-frequency fields in the imaged area. In this work, we propose and study a novel decoupling technique for two ultra-high field transceiver on-body dipole antennas. The decoupling is performed by a periodic structure of five parallel resonant wires referred to as a metasurface. In contrast to conventional decoupling with a single resonant wire, the metasurface decoupled by means of excitation of a higher-order coupled mode of the wires, which field is highly confined. The main advantage is a low distortion of the RF-field in the central region of the body.

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Wireless coils based on resonant and nonresonant coupled‐wire structure for small animal multinuclear imaging

Cited by 14 publications

References 24 publications

RF Coils for Preclinical Multinuclear Imaging Based on Coupled-wire Structures Working in Resonant and Non-resonant Regime

RF Coils for Preclinical Multinuclear Imaging Based on Coupled-wire Structures Working in Resonant and Non-resonant Regime

Sensitivity Analysis of the Simply Noise-matched Receiving Coil for NMR Experiments

Decoupling of Closely Spaced Dipole Antennas for Ultrahigh Field MRI With Metasurfaces

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