Parallel transmission RF pulse design with strict temperature constraints

Parallel transmission RF pulse design with strict temperature constraints

RF safety in parallel transmission (pTx) is generally ensured by imposing specific absorption rate (SAR) limits during pTx RF pulse design. There is increasing interest in using temperature to ensure safety in MRI. In this work, we present a local temperature correlation matrix formalism and apply i...

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Bibliographic Details
Published in:NMR in biomedicine Vol. 30; no. 5; pp. np - n/a
Main Authors: Deniz, Cem M., Carluccio, Giuseppe, Collins, Christopher
Format: Journal Article
Language:English
Published: England Wiley Subscription Services, Inc 01-05-2017
Subjects:
Body Temperature - physiology
Brain - physiology
Brain - radiation effects
Computer Simulation
Computer-Aided Design
Dose-Response Relationship, Radiation
Equipment Design
Equipment Failure Analysis
Equipment Safety
Humans
Magnetic Fields
Magnetic Resonance Imaging - instrumentation
Models, Neurological
parallel transmission
Patient Safety
Phantoms, Imaging
Radiation Dosage
Radio Waves
RF pulse design
Signal Processing, Computer-Assisted - instrumentation
temperature constraints
temperature correlation matrices
Thermography - instrumentation
Transducers
RF pulse design
parallel transmission
temperature correlation matrices
temperature constraints
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Summary:RF safety in parallel transmission (pTx) is generally ensured by imposing specific absorption rate (SAR) limits during pTx RF pulse design. There is increasing interest in using temperature to ensure safety in MRI. In this work, we present a local temperature correlation matrix formalism and apply it to impose strict constraints on maximum absolute temperature in pTx RF pulse design for head and hip regions. Electromagnetic field simulations were performed on the head and hip of virtual body models. Temperature correlation matrices were calculated for four different exposure durations ranging between 6 and 24 min using simulated fields and body‐specific constants. Parallel transmission RF pulses were designed using either SAR or temperature constraints, and compared with each other and unconstrained RF pulse design in terms of excitation fidelity and safety. The use of temperature correlation matrices resulted in better excitation fidelity compared with the use of SAR in parallel transmission RF pulse design (for the 6 min exposure period, 8.8% versus 21.0% for the head and 28.0% versus 32.2% for the hip region). As RF exposure duration increases (from 6 min to 24 min), the benefit of using temperature correlation matrices on RF pulse design diminishes. However, the safety of the subject is always guaranteed (the maximum temperature was equal to 39°C). This trend was observed in both head and hip regions, where the perfusion rates are very different. There is increasing interest in using temperature to ensure safety in MRI. In this study, we present a local temperature correlation matrix formalism and apply it to impose strict constraints on maximum absolute temperature in parallel transmission RF pulse design for head and hip regions. The use of temperature correlation matrices resulted in better excitation fidelity compared with the use of SAR, while the safety of the subject is always guaranteed.
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ISSN:0952-3480
1099-1492
DOI:10.1002/nbm.3694