Understanding the physical relations governing the noise navigator

R J M Navest; S Mandija; A Andreychenko; A J E Raaijmakers; J J W Lagendijk; C A T van den Berg

doi:10.1002/mrm.27906

Understanding the physical relations governing the noise navigator

R J M Navest, S Mandija, A Andreychenko, A J E Raaijmakers, J J W Lagendijk, C A T van den Berg

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Abstract

PURPOSE: The noise navigator is a passive way to detect physiological motion occurring in a patient through thermal noise modulations measured by standard clinical radiofrequency receive coils. The aim is to gain a deeper understanding of the potential and applications of physiologically induced thermal noise modulations.

METHODS: Numerical electromagnetic simulations and MR measurements were performed to investigate the relative contribution of tissue displacement versus modulation of the dielectric lung properties over the respiratory cycle, the impact of coil diameter and position with respect to the body. Furthermore, the spatial motion sensitivity of specific noise covariance matrix elements of a receive array was investigated.

RESULTS: The influence of dielectric lung property variations on the noise variance is negligible compared to tissue displacement. Coil size affected the thermal noise variance modulation, but the location of the coil with respect to the body had a larger impact. The modulation depth of a 15 cm diameter stationary coil approximately 3 cm away from the chest (i.e. radiotherapy setup) was 39.7% compared to 4.2% for a coil of the same size on the chest, moving along with respiratory motion. A combination of particular noise covariance matrix elements creates a specific spatial sensitivity for motion.

CONCLUSIONS: The insight gained on the physical relations governing the noise navigator will allow for optimized use and development of new applications. An optimized combination of elements from the noise covariance matrix offer new ways of performing, e.g. motion tracking.

Original language	English
Pages (from-to)	2236-2247
Number of pages	12
Journal	Magnetic Resonance in Medicine
Volume	82
Issue number	6
Early online date	17 Jul 2019
DOIs	https://doi.org/10.1002/mrm.27906
Publication status	Published - Dec 2019

Keywords

body resistance
magnetic resonance imaging
physiological motion
radiofrequency receive coil
thermal noise

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title = "Understanding the physical relations governing the noise navigator",

abstract = "PURPOSE: The noise navigator is a passive way to detect physiological motion occurring in a patient through thermal noise modulations measured by standard clinical radiofrequency receive coils. The aim is to gain a deeper understanding of the potential and applications of physiologically induced thermal noise modulations.METHODS: Numerical electromagnetic simulations and MR measurements were performed to investigate the relative contribution of tissue displacement versus modulation of the dielectric lung properties over the respiratory cycle, the impact of coil diameter and position with respect to the body. Furthermore, the spatial motion sensitivity of specific noise covariance matrix elements of a receive array was investigated.RESULTS: The influence of dielectric lung property variations on the noise variance is negligible compared to tissue displacement. Coil size affected the thermal noise variance modulation, but the location of the coil with respect to the body had a larger impact. The modulation depth of a 15 cm diameter stationary coil approximately 3 cm away from the chest (i.e. radiotherapy setup) was 39.7% compared to 4.2% for a coil of the same size on the chest, moving along with respiratory motion. A combination of particular noise covariance matrix elements creates a specific spatial sensitivity for motion.CONCLUSIONS: The insight gained on the physical relations governing the noise navigator will allow for optimized use and development of new applications. An optimized combination of elements from the noise covariance matrix offer new ways of performing, e.g. motion tracking.",

keywords = "body resistance, magnetic resonance imaging, physiological motion, radiofrequency receive coil, thermal noise",

author = "Navest, {R J M} and S Mandija and A Andreychenko and Raaijmakers, {A J E} and Lagendijk, {J J W} and {van den Berg}, {C A T}",

note = "Publisher Copyright: {\textcopyright} 2019 The Authors. Magnetic Resonance in Medicine published by Wiley Periodicals, Inc. on behalf of International Society for Magnetic Resonance in Medicine Copyright: Copyright 2021 Elsevier B.V., All rights reserved.",

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AU - Mandija, S

AU - Andreychenko, A

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AU - Lagendijk, J J W

AU - van den Berg, C A T

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Understanding the physical relations governing the noise navigator

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