AI Article Synopsis
- The study aimed to evaluate the compatibility of an oval-shaped PET insert with MRI technology, focusing on its RF field penetration and its use as both transmitter and receiver.
- A prototype was constructed using 12 PET detector modules, and various parameters like signal-to-noise ratio (SNR) and RF pulse amplitude were measured during tests with a phantom in a 3T MRI system.
- Results indicated that while the insert's RF maps were similar to MRI-only systems, there were significant reductions in SNR and increased RF pulse amplitude requirements, leading to safety concerns for the clinical MRI environment.
Article Abstract
Purpose: To perform an MRI compatibility study of an RF field-penetrable oval-shaped PET insert that implements an MRI built-in body RF coil both as a transmitter and a receiver.
Methods: Twelve electrically floating RF shielded PET detector modules were used to construct the prototype oval PET insert with a major axis of 440 mm, a minor axis of 350 mm, and an axial length of 225 mm. The electric floating of the PET detector modules was accomplished by isolating the cable shield from the detector shield using plastic tape. Studies were conducted on the transmit (B) RF field, the image signal-to-noise ratio (SNR), and the RF pulse amplitude for a homogeneous cylindrical (diameter: 160 mm and length: 260 mm) phantom (NaCl + NiSO solution) in a 3 T clinical MRI system (Verio, Siemens, Erlangen, Germany).
Results: The B maps for the oval insert were similar to the MRI-only field responses. Compared to the MRI-only values, SNR reductions of 51%, 45%, and 59% were seen, respectively, for the spin echo (SE), gradient echo (GE), and echo planar (EPI) images for the case of oval PET insert. Moreover, the required RF pulse amplitudes for the SE, GE, and EPI sequences were, respectively, 1.93, 1.85, and 1.36 times larger. However, a 30% reduction in the average RF reception sensitivity was observed for the oval insert.
Conclusions: The prototype floating PET insert was a safety concern for the clinical MRI system, and this compatibility study provided clearance for developing a large body size floating PET insert for the existing MRI system. Because of the RF shield of the insert, relatively large RF powers compared to the MRI-only case were required. Because of this and also due to low RF sensitivity of the body coil, the SNRs reduced largely.
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| http://dx.doi.org/10.1007/s11604-023-01514-y | DOI Listing |
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