The fractionated dipole antenna: A new antenna for body imaging at 7 Tesla

AJE Raaijmakers; Michel Italiaander; Ingmar J Voogt; Peter R Luijten; JM Hoogduin; DWJ Klomp; CAT van den Berg

doi:10.1002/mrm.25596

The fractionated dipole antenna: A new antenna for body imaging at 7 Tesla

AJE Raaijmakers, Michel Italiaander, Ingmar J Voogt, Peter R Luijten, JM Hoogduin, DWJ Klomp, CAT van den Berg

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

PURPOSE: Dipole antennas in ultrahigh field MRI have demonstrated advantages over more conventional designs. In this study, the fractionated dipole antenna is presented: a dipole where the legs are split into segments that are interconnected by capacitors or inductors.

METHODS: A parameter study has been performed on dipole antenna length using numerical simulations. A subsequent simulation study investigates the optimal intersegment capacitor/inductor value. The resulting optimal design has been constructed and compared to a previous design, the single-side adapted dipole (SSAD) by simulations and measurements. An array of eight elements has been constructed for prostate imaging on four subjects (body mass index 20-27.5) using 8 × 2 kW amplifiers.

RESULTS: For prostate imaging at 7T, lowest peak local specific-absorption rate (SAR) levels are achieved if the antenna is 30 cm or longer. A fractionated dipole antenna design with inductors between segments has been chosen to achieve even lower SAR levels and more homogeneous receive sensitivities.

CONCLUSION: With the new design, good quality prostate images are acquired. SAR levels are reduced by 41% to 63% in comparison to the SSAD. Coupling levels are moderate (average nearest neighbor: -14.6 dB) for each subject and prostate B1+ levels range from 12 to 18 μT.

Original language	English
Pages (from-to)	1366-1374
Number of pages	9
Journal	Magnetic Resonance in Medicine
Volume	75
Issue number	3
DOIs	https://doi.org/10.1002/mrm.25596
Publication status	Published - 2016

Keywords

Adult
Computer Simulation
Equipment Design
Humans
Magnetic Resonance Imaging
Male
Phantoms, Imaging
Prostate
Signal-To-Noise Ratio
Young Adult
Ultrahigh field
Transceive array
Dipole antenna
Body imaging
Prostate imaging

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10.1002/mrm.25596

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title = "The fractionated dipole antenna: A new antenna for body imaging at 7 Tesla",

abstract = "PURPOSE: Dipole antennas in ultrahigh field MRI have demonstrated advantages over more conventional designs. In this study, the fractionated dipole antenna is presented: a dipole where the legs are split into segments that are interconnected by capacitors or inductors.METHODS: A parameter study has been performed on dipole antenna length using numerical simulations. A subsequent simulation study investigates the optimal intersegment capacitor/inductor value. The resulting optimal design has been constructed and compared to a previous design, the single-side adapted dipole (SSAD) by simulations and measurements. An array of eight elements has been constructed for prostate imaging on four subjects (body mass index 20-27.5) using 8 × 2 kW amplifiers.RESULTS: For prostate imaging at 7T, lowest peak local specific-absorption rate (SAR) levels are achieved if the antenna is 30 cm or longer. A fractionated dipole antenna design with inductors between segments has been chosen to achieve even lower SAR levels and more homogeneous receive sensitivities.CONCLUSION: With the new design, good quality prostate images are acquired. SAR levels are reduced by 41% to 63% in comparison to the SSAD. Coupling levels are moderate (average nearest neighbor: -14.6 dB) for each subject and prostate B1+ levels range from 12 to 18 μT.",

keywords = "Adult, Computer Simulation, Equipment Design, Humans, Magnetic Resonance Imaging, Male, Phantoms, Imaging, Prostate, Signal-To-Noise Ratio, Young Adult, Ultrahigh field, Transceive array, Dipole antenna, Body imaging, Prostate imaging",

author = "AJE Raaijmakers and Michel Italiaander and Voogt, {Ingmar J} and Luijten, {Peter R} and JM Hoogduin and DWJ Klomp and {van den Berg}, CAT",

note = "{\textcopyright} 2015 Wiley Periodicals, Inc.",

year = "2016",

doi = "10.1002/mrm.25596",

language = "English",

volume = "75",

pages = "1366--1374",

journal = "Magnetic Resonance in Medicine",

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T2 - A new antenna for body imaging at 7 Tesla

AU - Raaijmakers, AJE

AU - Italiaander, Michel

AU - Voogt, Ingmar J

AU - Luijten, Peter R

AU - Hoogduin, JM

AU - Klomp, DWJ

AU - van den Berg, CAT

PY - 2016

Y1 - 2016

N2 - PURPOSE: Dipole antennas in ultrahigh field MRI have demonstrated advantages over more conventional designs. In this study, the fractionated dipole antenna is presented: a dipole where the legs are split into segments that are interconnected by capacitors or inductors.METHODS: A parameter study has been performed on dipole antenna length using numerical simulations. A subsequent simulation study investigates the optimal intersegment capacitor/inductor value. The resulting optimal design has been constructed and compared to a previous design, the single-side adapted dipole (SSAD) by simulations and measurements. An array of eight elements has been constructed for prostate imaging on four subjects (body mass index 20-27.5) using 8 × 2 kW amplifiers.RESULTS: For prostate imaging at 7T, lowest peak local specific-absorption rate (SAR) levels are achieved if the antenna is 30 cm or longer. A fractionated dipole antenna design with inductors between segments has been chosen to achieve even lower SAR levels and more homogeneous receive sensitivities.CONCLUSION: With the new design, good quality prostate images are acquired. SAR levels are reduced by 41% to 63% in comparison to the SSAD. Coupling levels are moderate (average nearest neighbor: -14.6 dB) for each subject and prostate B1+ levels range from 12 to 18 μT.

AB - PURPOSE: Dipole antennas in ultrahigh field MRI have demonstrated advantages over more conventional designs. In this study, the fractionated dipole antenna is presented: a dipole where the legs are split into segments that are interconnected by capacitors or inductors.METHODS: A parameter study has been performed on dipole antenna length using numerical simulations. A subsequent simulation study investigates the optimal intersegment capacitor/inductor value. The resulting optimal design has been constructed and compared to a previous design, the single-side adapted dipole (SSAD) by simulations and measurements. An array of eight elements has been constructed for prostate imaging on four subjects (body mass index 20-27.5) using 8 × 2 kW amplifiers.RESULTS: For prostate imaging at 7T, lowest peak local specific-absorption rate (SAR) levels are achieved if the antenna is 30 cm or longer. A fractionated dipole antenna design with inductors between segments has been chosen to achieve even lower SAR levels and more homogeneous receive sensitivities.CONCLUSION: With the new design, good quality prostate images are acquired. SAR levels are reduced by 41% to 63% in comparison to the SSAD. Coupling levels are moderate (average nearest neighbor: -14.6 dB) for each subject and prostate B1+ levels range from 12 to 18 μT.

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KW - Male

KW - Phantoms, Imaging

KW - Prostate

KW - Signal-To-Noise Ratio

KW - Young Adult

KW - Ultrahigh field

KW - Transceive array

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KW - Prostate imaging

U2 - 10.1002/mrm.25596

DO - 10.1002/mrm.25596

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JO - Magnetic Resonance in Medicine

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The fractionated dipole antenna: A new antenna for body imaging at 7 Tesla

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