An improved method to measure transfer functions using MRI

Purpose A previously published method for MRI‐based transfer function assessment makes use of the so‐called transceive phase assumption (TPA). This limits its applicability to shorter leads and/or lower field strengths. A new method is presented where the background electric field is determined from...

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Published in	Magnetic resonance in medicine Vol. 92; no. 5; pp. 2246 - 2260
Main Authors	Eijbersen, Michael A., Steensma, Bart R., Berg, Cornelis A. T., Raaijmakers, Alexander J. E.
Format	Journal Article
Language	English
Published	United States Wiley Subscription Services, Inc 01.11.2024
Subjects	Algorithms Computer Simulation Copper wire Electric fields Humans Image Processing, Computer-Assisted - methods Jefimenko's equation Magnetic resonance imaging Magnetic Resonance Imaging - methods magnitude squared least squares (MSLS) Maxwell's equations Phantoms, Imaging Reproducibility of Results RF heating safety Thrombolytic drugs transfer function/matrix Transfer functions magnitude squared least squares (MSLS) Jefimenko's equation Maxwell's equations RF heating transfer function/matrix safety
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ISSN	0740-3194 1522-2594 1522-2594
DOI	10.1002/mrm.30179

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Abstract	Purpose A previously published method for MRI‐based transfer function assessment makes use of the so‐called transceive phase assumption (TPA). This limits its applicability to shorter leads and/or lower field strengths. A new method is presented where the background electric field is determined from both B1+$$ {\mathrm{B}}_1^{+} $$‐ and B1−$$ {\mathrm{B}}_1^{-} $$‐field distributions, avoiding the TPA and making it more generally applicable. Theory and Methods These B1$$ {\mathrm{B}}_1 $$‐distributions are determined from a spoiled gradient echo multiflip angle acquisition. From the separated B1$$ {\mathrm{B}}_1 $$‐components the background electrical field and the induced current are computed. Further improvement is achieved by recasting the B1$$ {\mathrm{B}}_1 $$‐field model as a “magnitude squared least squares” problem. The proposed reconstruction method is used to determine transfer functions of various copper wire lengths up to 40 cm inside an elliptical ASTM phantom. The method is first tested on EM‐simulated data and subsequently phantom and bench measurements are used to determine transfer functions experimentally. Results In silica reconstructions demonstrate the validity of the proposed B1$$ {\mathrm{B}}_1 $$‐field model resulting in highly accurate reconstructed B1$$ {\mathrm{B}}_1 $$‐fields, currents, incident electric fields and transfer functions. The experimental results show slight deviations in the field model, however, resulting transfer functions are accurately determined with high similarity to simulations and comparable to bench measurements. Conclusion A more generally applicable method for MRI‐based transfer function assessment is presented. The proposed method circumvents phase assumptions making it applicable for longer objects and/or higher field strengths. Additional improvements are implemented in the B1$$ {\mathrm{B}}_1 $$‐mapping method and the solution algorithm.
AbstractList	Purpose A previously published method for MRI‐based transfer function assessment makes use of the so‐called transceive phase assumption (TPA). This limits its applicability to shorter leads and/or lower field strengths. A new method is presented where the background electric field is determined from both B1+$$ {\mathrm{B}}_1^{+} $$‐ and B1−$$ {\mathrm{B}}_1^{-} $$‐field distributions, avoiding the TPA and making it more generally applicable. Theory and Methods These B1$$ {\mathrm{B}}_1 $$‐distributions are determined from a spoiled gradient echo multiflip angle acquisition. From the separated B1$$ {\mathrm{B}}_1 $$‐components the background electrical field and the induced current are computed. Further improvement is achieved by recasting the B1$$ {\mathrm{B}}_1 $$‐field model as a “magnitude squared least squares” problem. The proposed reconstruction method is used to determine transfer functions of various copper wire lengths up to 40 cm inside an elliptical ASTM phantom. The method is first tested on EM‐simulated data and subsequently phantom and bench measurements are used to determine transfer functions experimentally. Results In silica reconstructions demonstrate the validity of the proposed B1$$ {\mathrm{B}}_1 $$‐field model resulting in highly accurate reconstructed B1$$ {\mathrm{B}}_1 $$‐fields, currents, incident electric fields and transfer functions. The experimental results show slight deviations in the field model, however, resulting transfer functions are accurately determined with high similarity to simulations and comparable to bench measurements. Conclusion A more generally applicable method for MRI‐based transfer function assessment is presented. The proposed method circumvents phase assumptions making it applicable for longer objects and/or higher field strengths. Additional improvements are implemented in the B1$$ {\mathrm{B}}_1 $$‐mapping method and the solution algorithm. A previously published method for MRI-based transfer function assessment makes use of the so-called transceive phase assumption (TPA). This limits its applicability to shorter leads and/or lower field strengths. A new method is presented where the background electric field is determined from both - and -field distributions, avoiding the TPA and making it more generally applicable. These -distributions are determined from a spoiled gradient echo multiflip angle acquisition. From the separated -components the background electrical field and the induced current are computed. Further improvement is achieved by recasting the -field model as a "magnitude squared least squares" problem. The proposed reconstruction method is used to determine transfer functions of various copper wire lengths up to 40 cm inside an elliptical ASTM phantom. The method is first tested on EM-simulated data and subsequently phantom and bench measurements are used to determine transfer functions experimentally. In silica reconstructions demonstrate the validity of the proposed -field model resulting in highly accurate reconstructed -fields, currents, incident electric fields and transfer functions. The experimental results show slight deviations in the field model, however, resulting transfer functions are accurately determined with high similarity to simulations and comparable to bench measurements. A more generally applicable method for MRI-based transfer function assessment is presented. The proposed method circumvents phase assumptions making it applicable for longer objects and/or higher field strengths. Additional improvements are implemented in the -mapping method and the solution algorithm. PurposeA previously published method for MRI‐based transfer function assessment makes use of the so‐called transceive phase assumption (TPA). This limits its applicability to shorter leads and/or lower field strengths. A new method is presented where the background electric field is determined from both B1+$$ {\mathrm{B}}_1^{+} $$‐ and B1−$$ {\mathrm{B}}_1^{-} $$‐field distributions, avoiding the TPA and making it more generally applicable.Theory and MethodsThese B1$$ {\mathrm{B}}_1 $$‐distributions are determined from a spoiled gradient echo multiflip angle acquisition. From the separated B1$$ {\mathrm{B}}_1 $$‐components the background electrical field and the induced current are computed. Further improvement is achieved by recasting the B1$$ {\mathrm{B}}_1 $$‐field model as a “magnitude squared least squares” problem. The proposed reconstruction method is used to determine transfer functions of various copper wire lengths up to 40 cm inside an elliptical ASTM phantom. The method is first tested on EM‐simulated data and subsequently phantom and bench measurements are used to determine transfer functions experimentally.ResultsIn silica reconstructions demonstrate the validity of the proposed B1$$ {\mathrm{B}}_1 $$‐field model resulting in highly accurate reconstructed B1$$ {\mathrm{B}}_1 $$‐fields, currents, incident electric fields and transfer functions. The experimental results show slight deviations in the field model, however, resulting transfer functions are accurately determined with high similarity to simulations and comparable to bench measurements.ConclusionA more generally applicable method for MRI‐based transfer function assessment is presented. The proposed method circumvents phase assumptions making it applicable for longer objects and/or higher field strengths. Additional improvements are implemented in the B1$$ {\mathrm{B}}_1 $$‐mapping method and the solution algorithm. A previously published method for MRI-based transfer function assessment makes use of the so-called transceive phase assumption (TPA). This limits its applicability to shorter leads and/or lower field strengths. A new method is presented where the background electric field is determined from both B 1 + $$ {\mathrm{B}}_1^{+} $$ - and B 1 - $$ {\mathrm{B}}_1^{-} $$ -field distributions, avoiding the TPA and making it more generally applicable.PURPOSEA previously published method for MRI-based transfer function assessment makes use of the so-called transceive phase assumption (TPA). This limits its applicability to shorter leads and/or lower field strengths. A new method is presented where the background electric field is determined from both B 1 + $$ {\mathrm{B}}_1^{+} $$ - and B 1 - $$ {\mathrm{B}}_1^{-} $$ -field distributions, avoiding the TPA and making it more generally applicable.These B 1 $$ {\mathrm{B}}_1 $$ -distributions are determined from a spoiled gradient echo multiflip angle acquisition. From the separated B 1 $$ {\mathrm{B}}_1 $$ -components the background electrical field and the induced current are computed. Further improvement is achieved by recasting the B 1 $$ {\mathrm{B}}_1 $$ -field model as a "magnitude squared least squares" problem. The proposed reconstruction method is used to determine transfer functions of various copper wire lengths up to 40 cm inside an elliptical ASTM phantom. The method is first tested on EM-simulated data and subsequently phantom and bench measurements are used to determine transfer functions experimentally.THEORY AND METHODSThese B 1 $$ {\mathrm{B}}_1 $$ -distributions are determined from a spoiled gradient echo multiflip angle acquisition. From the separated B 1 $$ {\mathrm{B}}_1 $$ -components the background electrical field and the induced current are computed. Further improvement is achieved by recasting the B 1 $$ {\mathrm{B}}_1 $$ -field model as a "magnitude squared least squares" problem. The proposed reconstruction method is used to determine transfer functions of various copper wire lengths up to 40 cm inside an elliptical ASTM phantom. The method is first tested on EM-simulated data and subsequently phantom and bench measurements are used to determine transfer functions experimentally.In silica reconstructions demonstrate the validity of the proposed B 1 $$ {\mathrm{B}}_1 $$ -field model resulting in highly accurate reconstructed B 1 $$ {\mathrm{B}}_1 $$ -fields, currents, incident electric fields and transfer functions. The experimental results show slight deviations in the field model, however, resulting transfer functions are accurately determined with high similarity to simulations and comparable to bench measurements.RESULTSIn silica reconstructions demonstrate the validity of the proposed B 1 $$ {\mathrm{B}}_1 $$ -field model resulting in highly accurate reconstructed B 1 $$ {\mathrm{B}}_1 $$ -fields, currents, incident electric fields and transfer functions. The experimental results show slight deviations in the field model, however, resulting transfer functions are accurately determined with high similarity to simulations and comparable to bench measurements.A more generally applicable method for MRI-based transfer function assessment is presented. The proposed method circumvents phase assumptions making it applicable for longer objects and/or higher field strengths. Additional improvements are implemented in the B 1 $$ {\mathrm{B}}_1 $$ -mapping method and the solution algorithm.CONCLUSIONA more generally applicable method for MRI-based transfer function assessment is presented. The proposed method circumvents phase assumptions making it applicable for longer objects and/or higher field strengths. Additional improvements are implemented in the B 1 $$ {\mathrm{B}}_1 $$ -mapping method and the solution algorithm.
Author	Berg, Cornelis A. T. Raaijmakers, Alexander J. E. Steensma, Bart R. Eijbersen, Michael A.
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Snippet	Purpose A previously published method for MRI‐based transfer function assessment makes use of the so‐called transceive phase assumption (TPA). This limits its... A previously published method for MRI-based transfer function assessment makes use of the so-called transceive phase assumption (TPA). This limits its... PurposeA previously published method for MRI‐based transfer function assessment makes use of the so‐called transceive phase assumption (TPA). This limits its...
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SubjectTerms	Algorithms Computer Simulation Copper wire Electric fields Humans Image Processing, Computer-Assisted - methods Jefimenko's equation Magnetic resonance imaging Magnetic Resonance Imaging - methods magnitude squared least squares (MSLS) Maxwell's equations Phantoms, Imaging Reproducibility of Results RF heating safety Thrombolytic drugs transfer function/matrix Transfer functions
Title	An improved method to measure transfer functions using MRI
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