Abstract
Background: Parallel transmit (pTx) has introduced many benefits to MRI with regard to decreased specific absorption rates and improved transmit field homogeneity, of particular importance in applications at higher magnetic field strengths. PTx has also been proposed as a solution to mitigating dangerous RF induced heating of elongated conductive devices such as those used in cardiac interventions. In this work we present a system that can augment a conventional scanner with pTx, in particular for use in interventional MRI for guidewire safety.
Methods: The pTx system was designed to work in-line with a 1.5T MRI while the RF synthesis and imaging control was maintained on the host MR scanner. The add on pTx system relies on the RF transmit signal, unblanking pulse, and a protocol driven trigger from the scanner. The RF transmit was split into multiple fully modulated transmit signals to drive an array of custom transceiver coils. The performance of the 8-channel implementation was tested with regards to active and real-time control of RF induced currents on a standard guidewire, heating mitigation tests, and anatomical imaging in a sheep torso.
Results: The pTx system was intended to update RF shims in real-time and it was
demonstrated that the safe RF shim could be determined while the guidewire is moved. The anatomical imaging demonstrated that heart anatomy and neighbouring structures can be fully imaged with the pTx system inline.
Conclusion: We have presented the design and performance of a real-time feedback
control pTx system capable of adding such capabilities to a conventional MRI with the
focus guidewire imaging in cardiac interventional MRI applications.
Methods: The pTx system was designed to work in-line with a 1.5T MRI while the RF synthesis and imaging control was maintained on the host MR scanner. The add on pTx system relies on the RF transmit signal, unblanking pulse, and a protocol driven trigger from the scanner. The RF transmit was split into multiple fully modulated transmit signals to drive an array of custom transceiver coils. The performance of the 8-channel implementation was tested with regards to active and real-time control of RF induced currents on a standard guidewire, heating mitigation tests, and anatomical imaging in a sheep torso.
Results: The pTx system was intended to update RF shims in real-time and it was
demonstrated that the safe RF shim could be determined while the guidewire is moved. The anatomical imaging demonstrated that heart anatomy and neighbouring structures can be fully imaged with the pTx system inline.
Conclusion: We have presented the design and performance of a real-time feedback
control pTx system capable of adding such capabilities to a conventional MRI with the
focus guidewire imaging in cardiac interventional MRI applications.
Original language | English |
---|---|
Journal | arxiv preprint arxiv:2103.10399 |
Publication status | Published - 2021 |