Monitoring local heating around an interventional MRI antenna with RF radiometry

Ertürk, Mehmet; El-Sharkawy, Abdel Monem M.; Bottomley, Paul A.

doi:10.1118/1.4907960

Cited by 5 publications

(5 citation statements)

References 66 publications

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“…Furthermore, incorporation of novel quantitative imaging methods that can perform in the presence of heterogeneous RF fields may alleviate the need of strict transmit field control . Numerical modeling, validation, and real‐time monitoring of RF safety will play an important role in successful implementation of pTx methods. Even though increasing B 0 and Larmor frequency poses challenges in terms of field uniformity and RF management, it also opens up new opportunities for transmit array design using higher element densities and channel counts.…”

Section: Discussionmentioning

confidence: 99%

Toward imaging the body at 10.5 tesla

Ertürk

Eryaman

et al. 2016

Magnetic Resonance in Med

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106

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Purpose To explore the potential of performing body imaging at 10.5T compared to 7.0T through evaluating the transmit/receive performance of similarly configured dipole antenna arrays. Methods Fractionated dipole antenna elements for 10.5T body imaging were designed and evaluated using numerical simulations. Transmit performance of antenna arrays inside the prostate, kidneys and heart were investigated and compared to those at 7.0T using both phase-only RF shimming and multi-spoke pulses. Signal-to-noise ratio (SNR) comparisons were also performed. A 10-channel antenna array was constructed to image the abdomen of a swine at 10.5T. Numerical methods were validated with phantom studies at both field strengths. Results Similar power efficiencies were observed inside target organs with phase-only shimming, but RF non-uniformity was significantly higher at 10.5T. Spokes RF pulses allowed similar transmit performance with accompanying local SAR increases of 25–90% compared to 7.0T. Relative SNR gains inside the target anatomies were calculated to be >2-fold higher at 10.5T, and 2.2-fold SNR gain was measured in a phantom. Gradient echo and fast spin echo imaging demonstrated the feasibility of body imaging at 10.5T with the designed array. Conclusion While comparable power efficiencies can be achieved using dipole antenna arrays with static shimming at 10.5T; increasing RF non-uniformities underscore the need for efficient, robust and safe parallel transmission methods.

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Section: Discussionmentioning

confidence: 99%

Toward imaging the body at 10.5 tesla

Ertürk

Eryaman

et al. 2016

Magnetic Resonance in Med

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106

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“…To further ensure patient safety, the SAR near the ERC was based on a 1 g average as opposed to the standard 10 g average as a means to derive TAP limits. Further assessment of subject‐dependent

{normalB}_{1}^{+}

shimming and its impact on local coupling and heating could be assessed by monitoring temperature through embedded fiberoptic sensors on the surface of the coil and/or using an RF radiometry method . Temperature monitoring of the coil surface may also identify additional constraints that need to be considered beyond SAR when using the ERC coils as transceivers.…”

Section: Discussionmentioning

confidence: 99%

Development and evaluation of a multichannel endorectal RF coil for prostate MRI at 7T in combination with an external surface array

Ertürk

Tian

Moortele

et al. 2015

Magnetic Resonance Imaging

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Purpose To develop and evaluate a sterilizable multi-channel endorectal coil (ERC) for use in combination with an external surface array (ESA) for high resolution anatomical and functional studies of the prostate at 7 Tesla. Methods A two-loop ERC (ERC-2L) and a microstrip-loop ERC (ERC-ML) were compared at 7T in terms of transmit and receive performance. The best performing ERC was evaluated alone and in combination with the ESA through 1) simulations on both phantom and an anatomically correct numerical human model to assess B1+ transmit and specific absorption rate (SAR) efficiencies and 2) phantom experiments to calculate B1+ transmit efficiency and SNR. Phantom studies were also performed to look at heating when using the ERC as a transmitter and for comparing the new coil against a single-channel balloon-type ERC (ERC-b). High-resolution MRI acquisitions were performed on a single healthy subject using the two-channel ERC combined with the ESA. Results Compared to the ERC-ML, the ERC-2L demonstrated 20% higher SAR efficiency and higher SNR 3 cm from the coil. The presence of a tuned and detuned ERC-2L did not alter the peak local SAR of the ESA alone, however the detuned ERC-2L had 45% less peak local SAR around the rectum compared to the tuned ERC-2L. The receive-only version of the ERC-2L improved the SNR 4.7-fold and 1.3-fold compared to the ESA and ERC-b, respectively. In combination with the ESA, the ERC-2L supported in-plane voxel-size of 0.36×0.36mm2 in T2-weighted anatomic imaging. Conclusions The reusable ERC-2L combined with an ESA offers a high SNR imaging platform for translational studies of the prostate at 7T.

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“…MRI thermometry was performed using the proton resonance frequency (PRF)-shift method (20). A temperature coefficient of −0.01 ppm/°C was used to convert thermometric phase images acquired by the probe to temperature maps (20, 21). Large temperature changes near the probe causing ‘phase-wraps’ were unwrapped in the image field-of-view starting furthest (i.e., coolest) from the probe where phase-wraps were minimal, and proceeding towards it (SSH).…”

Section: Methodsmentioning

confidence: 99%

Radiofrequency Ablation, MR Thermometry, and High-Spatial-Resolution MR Parametric Imaging with a Single, Minimally Invasive Device

Ertürk¹,

Hegde²,

Bottomley³

2016

Radiology

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Purpose To develop and demonstrate in vitro and in vivo, a single interventional MR-active device that integrates the functions of precise identification of a tissue site with the delivery of RF energy for ablation, high-resolution thermal mapping to monitor thermal dose, and with quantitative MRI relaxometry to document ablation-induced tissue changes for characterizing ablated tissue. Materials and Methods All animal studies were approved by our Institutional Animal Care and Use Committee. A loopless MRI antenna comprised of a tuned micro-cable either 0.8 or 2.2mm in diameter with an extended central conductor, was switched between a 3T MRI scanner and an RF power source, to monitor and perform RF ablation in bovine muscle and human artery samples in vitro, and in rabbits in vivo. High-resolution (250–300μm) proton resonance frequency shift MR thermometry was interleaved with ablations. Quantitative spin-lattice (T1) and spin-spin (T2) relaxation time MRI mapping was performed pre- and post-ablation, and compared with gross tissue examination of the region of ablated tissue, post-MRI. Results High-resolution MRI afforded temperature mapping in under 8s for monitoring ablation temperatures exceeding 85°C delivered by the same device, producing irreversible thermal injury and necrosis. Quantitative MRI relaxation time maps revealed up to a two-fold variation in mean regional T1 and T2 post-vs. pre-ablation. Conclusion A simple, integrated, minimally-invasive interventional probe that provides image-guided therapy delivery, thermal mapping of dose and the detection of ablation-associated MRI parametric changes was developed and demonstrated. This single-device approach avoided coupling-related safety concerns associated with multiple conductor approaches.

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Monitoring local heating around an interventional MRI antenna with RF radiometry

Cited by 5 publications

References 66 publications

Toward imaging the body at 10.5 tesla

Toward imaging the body at 10.5 tesla

Development and evaluation of a multichannel endorectal RF coil for prostate MRI at 7T in combination with an external surface array

Radiofrequency Ablation, MR Thermometry, and High-Spatial-Resolution MR Parametric Imaging with a Single, Minimally Invasive Device

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