MRI Scan Time Reduction through K-Space Data Sharing in Combo Acquisitions with a Spin Echo Sequence

We propose a technique to reduce scan time for magnetic resonance imaging (MRI) through sharing of k-space data between images, As a proof of concept, we ran simulations of MRI experiments based on Bloch equations using a spin echo sequence. We generated images of a realistic brain phantom containin...

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Hauptverfasser:	Mekle, R, Wu, E X, Laine, A F
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Sprache:	eng
Schlagworte:	ACQUISITION CEREBROSPINAL FLUID CODING CONTRAST DATA BASES DEGRADATION ECHOES EQUATIONS FOURIER ANALYSIS GRAY(COLOR) MAGNETIC RESONANCE IMAGING Nuclear Physics & Elementary Particle Physics OPTIMIZATION PARAMETERS PRESERVATION PROFILES REPETITION RATE SCANNING SEQUENCES SIGNALS SPINNING(MOTION) Theoretical Mathematics TIME VALUE VARIABLES VARIATIONS
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creator	Mekle, R Wu, E X Laine, A F
description	We propose a technique to reduce scan time for magnetic resonance imaging (MRI) through sharing of k-space data between images, As a proof of concept, we ran simulations of MRI experiments based on Bloch equations using a spin echo sequence. We generated images of a realistic brain phantom containing the tissues: white matter, gray matter, and cerebrospinal fluid, A set of k-space data was acquired while varying,' two acquisition parameters: repetition time (TR) and echo time (TE), This data set was then used to reconstruct multiple images of different contrast, Customized variation of TR and TE allowed us to obtain different contrast weightings of signal values, We present results for 2-contrast and 3-contrast combo acquisitions and compare them with images from acquisitions with fixed TR and TE, Scan time reductions of 30%- 52% were achieved, Artifacts stemming from non-uniform and tissue-dependent data weighting in the Fourier domain were minimized through systematic optimization of the order of phase encoding and of variation schemes for TR and TE, No obvious degradation of image quality and resolution was observed, In addition, we quantitatively analyzed preservation of contrast, image profiles of sharp tissue boundaries, and signal-to-noise- ratio, Papers from the 23rd Annual International Conference of the IEEE Engineering in Medicine and Biology Society, October 25-28, 2001, held in Istanbul, Turkey. See also ADM001351 for entire conference on cd-rom.
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We generated images of a realistic brain phantom containing the tissues: white matter, gray matter, and cerebrospinal fluid, A set of k-space data was acquired while varying,' two acquisition parameters: repetition time (TR) and echo time (TE), This data set was then used to reconstruct multiple images of different contrast, Customized variation of TR and TE allowed us to obtain different contrast weightings of signal values, We present results for 2-contrast and 3-contrast combo acquisitions and compare them with images from acquisitions with fixed TR and TE, Scan time reductions of 30%- 52% were achieved, Artifacts stemming from non-uniform and tissue-dependent data weighting in the Fourier domain were minimized through systematic optimization of the order of phase encoding and of variation schemes for TR and TE, No obvious degradation of image quality and resolution was observed, In addition, we quantitatively analyzed preservation of contrast, image profiles of sharp tissue boundaries, and signal-to-noise- ratio, Papers from the 23rd Annual International Conference of the IEEE Engineering in Medicine and Biology Society, October 25-28, 2001, held in Istanbul, Turkey. 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subjects	ACQUISITION CEREBROSPINAL FLUID CODING CONTRAST DATA BASES DEGRADATION ECHOES EQUATIONS FOURIER ANALYSIS GRAY(COLOR) MAGNETIC RESONANCE IMAGING Nuclear Physics & Elementary Particle Physics OPTIMIZATION PARAMETERS PRESERVATION PROFILES REPETITION RATE SCANNING SEQUENCES SIGNALS SPINNING(MOTION) Theoretical Mathematics TIME VALUE VARIABLES VARIATIONS
title	MRI Scan Time Reduction through K-Space Data Sharing in Combo Acquisitions with a Spin Echo Sequence
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