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1. RF‐induced heating for active implantable medical devices in dual parallel leads configurations at 1.5 T MRI

   https://doi.org/10.1002/mrm.29650  

   Hu, Wei ; Guo, Ran ; Wang, Qingyan ; Zheng, Jianfeng ; Tsang, Jeffrey ; Kainz, Wolfgang ; Long, Stuart ; Chen, Ji ( April 2023 , Magnetic Resonance in Medicine)

   The Radiofrequency (RF)‐induced heating for an active implantable medical device (AIMD) with dual parallel leads is evaluated in this paper. The coupling effects between dual parallel leads are studied via simulations and experiments methods. The global transfer function technique is used to assess the RF‐induced heating for dual‐lead AIMDs inside four human body models.

   RF‐induced heating for spinal cord stimulator systems with 60 and 90 cm length leads are studied at three parallel dual‐lead configurations (closely spaced, 8 mm spaced, and 40 mm spaced) and a single‐lead configuration. The global transfer function method is used to develop the AIMD models of different configurations and is used for lead‐tip heating assessments inside human body models.

   In simulation studies, the peak 1g specific absorption rate/temperatrue rises of dual parallel leads systems is lower than those from the single‐lead system. In experimental American Society for Testing and Materials phantom studies, the temperature rises for the single‐lead AIMD system can be 2.4 times higher than that from dual‐lead AIMD systems. For the spinal cord stimulator systems used in the study, the statistical analysis shows the RF‐induced heating of dual‐lead configurations are also lower than those from the single‐lead configuration inside all four human body models.

   For the AIMD system in this study, it shows that the coupling effects between the dual parallel leads of AIMD systems can reduce RF‐induced heating. The global transfer function for different spatial distance dual‐lead configurations can potentially provide a method for the RF‐induced heating evaluation for dual‐lead AIMD systems.

    

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2. Magnetic resonance conditionality of abandoned leads from active implantable medical devices at 1.5 T

   https://doi.org/10.1002/mrm.28967  

   Wang, Yu ; Guo, Ran ; Hu, Wei ; Zheng, Jianfeng ; Wang, Qingyan ; Jiang, Jay ; Kurpad, Krishna K. N. ; Kaula, Norbert ; Long, Stuart ; Chen, Ji ; et al ( August 2021 , Magnetic Resonance in Medicine)

   During MR scans, abandoned leads from active implantable medical devices (AIMDs) can experience excessive heating at the lead tip, depending on the type of termination applied to the proximal contacts (proximal end treatment). The influence of different proximal end treatments (ie, [1] freely exposed in the tissue, [2] terminated with metal in contact with the tissue, or [3] capped with plastic, and thereby fully insulated, on the RF‐induced lead‐tip heating) are studied. A technique to ensure that MR Conditional AIMD leads remain MR Conditional even when abandoned is recommended.

   Abandoned leads from three MR Conditional AIMDs ([1] a sacral neuromodulation system, [2] a cardiac rhythm management pacemaker system, and [3] a deep brain stimulator system) were investigated in this study. The computational lead models (ie, the transfer functions) for different proximal end treatments were measured and used to assess the in vivo lead‐tip heating for four virtual human models (FATS, Duke, Ella, and Billie) and compared with the lead‐tip heating of the complete MR Conditional AIMD system.

   The average and maximum lead‐tip heating for abandoned leads proximally capped with metal is always lower than that from the complete AIMD system. Abandoned leads proximally insulated could lead to an average in vivo temperature rise up to 3.5 times higher than that from the complete AIMD system.

   For the three investigated AIMDs under 1.5T MR scanning, our results indicate that RF‐induced lead‐tip heating of abandoned leads strongly depends on the proximal lead termination. A metallic cap applied to the proximal termination of the tested leads could significantly reduce the RF‐induced lead‐tip heating.

    

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3. Multi‐channel helical‐antenna inner‐volume RF coils for ultra‐high field MR scanners

   https://doi.org/10.1002/cmr.b.21405  

   Athalye, Pranav S. ; Ilić, Milan M. ; van de Moortele, Pierre‐Francois ; Kiruluta, Andrew J. M. ; Notaroš, Branislav M. ( February 2019 , Concepts in Magnetic Resonance Part B: Magnetic Resonance Engineering)

   RFcoil design for human ultra‐high field (7 T and higher) magnetic resonance (MR) imaging is an area of intense development, to overcome difficult challenges such asRFexcitation spatial heterogeneity and lowRFtransfer efficiency into the spin system. This article proposes a novel category of multi‐channelRFvolume coil structures at both 7 T and 10.5 T based on a subject‐loaded multifilar helical‐antennaRFcoil that aims at addressing these problems. In some prior applications of helix antennas asMR RFcoils at 7 T, the imaged sample was positioned outside the helix. Here, we introduce a radically different approach, with the inner volume of a helix antenna being utilized to image a sample. The new coil uniquely combines traveling‐wave behavior through the overall antenna wire structure and near‐fieldRFinteraction between the conducting elements and the imaged tissues. It thus benefits from the congruence of far‐ and near‐field regimes. Design and analysis of the novel inner‐volume coils are performed by numerical simulations using multiple computational electromagnetics techniques. The fabricated coil prototypes are tested, validated, and evaluated experimentally in 7‐T and 10.5‐TMRhuman wide bore (90‐cm) MRscanners. Phantom data at 7 T show good consistency between numerical simulations and experimental results. SimulatedB₁⁺transmit efficiencies, in T/√W, are comparable to those of some of the conventional and state‐of‐the‐artRFcoil designs at 7 T. Experimental results at 10.5 T show the scalability of the helix coil design.

    

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4. A technique for the reduction of RF‐induced heating of active implantable medical devices during MRI

   https://doi.org/10.1002/mrm.28953  

   Wang, Yu ; Zheng, Jianfeng ; Guo, Ran ; Wang, Qingyan ; Kainz, Wolfgang ; Long, Stuart ; Chen, Ji ( August 2021 , Magnetic Resonance in Medicine)

   The paper presents a novel method to reduce the RF‐induced heating of active implantable medical devices during MRI.

   With the addition of an energy decoying and dissipating structure, RF energy can be redirected toward the dissipating rings through the decoying conductor. Three lead groups (45 cm‐50 cm) and 4 (50 cm‐100 cm) were studied in 1.5 Tesla MR systems by simulation and measurement, respectively. In vivo modeling was performed using human models to estimate the RF‐induced heating of an active implantable medical device for spinal cord treatment.

   In the simulation study, it was shown that the peak 1g‐averaged specific absorption rate near the lead‐tips can be reduced by 70% to 80% compared to those from the control leads. In the experimental measurements during a 2‐min exposure test in a 1.5 Telsa MR system, the temperature rises dropped from the original 18.3℃, 25.8℃, 8.1℃, and 16.1℃ (control leads 1‐4) to 5.4℃, 6.9℃, 1.6℃, and 3.3℃ (leads 1‐4 with the energy decoying and dissipation structure). The in vivo calculation results show that the maximum induced temperature rise among all cases can be substantially reduced (up to 80%) when the energy decoying and dissipating structures were used.

   Our studies confirm the effectiveness of the novel technique for a variety of scanning scenarios. The results also indicate that the decoying conductor length, number of rings, and ring area must be carefully chosen and validated.

    

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5. Effect of radiofrequency shield diameter on signal‐to‐noise ratio at ultra‐high field MRI

   https://doi.org/10.1002/mrm.28670  

   Zhang, Bei ; Adriany, Gregor ; Delabarre, Lance ; Radder, Jerahmie ; Lagore, Russell ; Rutt, Brian ; Yang, Qing X. ; Ugurbil, Kamil ; Lattanzi, Riccardo ( January 2021 , Magnetic Resonance in Medicine)

   In this work, we investigated how the position of the radiofrequency (RF) shield can affect the signal‐to‐noise ratio (SNR) of a receive RF coil. Our aim was to obtain physical insight for the design of a 10.5T 32‐channel head coil, subject to the constraints on the diameter of the RF shield imposed by the head gradient coil geometry.

   We used full‐wave numerical simulations to investigate how the SNR of an RF receive coil depends on the diameter of the RF shield at ultra‐high magnetic field (UHF) strengths (≥7T).

   Our simulations showed that there is an SNR‐optimal RF shield size at UHF strength, whereas at low field the SNR monotonically increases with the shield diameter. For a 32‐channel head coil at 10.5T, an optimally sized RF shield could act as a cylindrical waveguide and increase the SNR in the brain by 27% compared to moving the shield as far as possible from the coil. Our results also showed that a separate transmit array between the RF shield and the receive array could considerably reduce SNR even if they are decoupled.

   At sufficiently high magnetic field strength, the design of local RF coils should be optimized together with the design of the RF shield to benefit from both near field and resonant modes.

    

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