A novel magnetic resonance elastography transducer concept based on a rotational eccentric mass: preliminary experiences with the gravitational transducer

Jurgen Henk Runge; Stefan Heinz Hoelzl; Jelizaveta Sudakova; Ayse Sila Dokumaci; Jules Laurent Nelissen; Christian Guenthner; Jack Lee; Marian Troelstra; Daniel Fovargue; Jaap Stoker; Aart Johannes Nederveen; David Nordsletten; Ralph Sinkus

doi:https://doi.org/10.1088/1361-6560/aaf9f8

A novel magnetic resonance elastography transducer concept based on a rotational eccentric mass: preliminary experiences with the gravitational transducer

Jurgen Henk Runge, Stefan Heinz Hoelzl, Jelizaveta Sudakova, Ayse Sila Dokumaci, Jules Laurent Nelissen, Christian Guenthner, Jack Lee, Marian Troelstra, Daniel Fovargue, Jaap Stoker, Aart Johannes Nederveen, David Nordsletten, Ralph Sinkus

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

23 Citations (Scopus)

Abstract

BACKGROUND: Magnetic resonance elastography (MRE) is used to non-invasively estimate biomechanical tissue properties via the imaging of propagating mechanical shear waves. Several factors including mechanical transducer design, MRI sequence design and viscoelastic reconstruction influence data quality and hence the reliability of the derived biomechanical properties.

PURPOSE: To design and characterize a novel mechanical MRE transducer concept based on a rotational eccentric mass, coined the gravitational transducer.

MATERIALS AND METHODS: Table top measurements were performed using accelerometers to characterize the frequency response of the new transducer concept at different driving frequencies (f VIB) and different rotating masses. These were compared to a commercially available pneumatically driven MRE transducer. MR data were acquired on a 3T scanner using a fractionally encoded gradient echo MRE sequence in three healthy volunteers. Acceleration and displacement spectra were plotted in units of g and mm, respectively, and visually compared, emphasizing the ratio between the peaks at f VIB and its 2nd harmonic, a known cause of error in the reconstruction of biomechanical properties as is explored in more detail in numerical simulations here. No formal statistical testing was performed in this proof-of-principle paper.

RESULTS: The new transducer concept shows-as expected from theory-a quadratic or linear increase of acceleration amplitude with increase in f VIB or mass, respectively. Furthermore, different versions of the transducer show markedly lower 2nd harmonic-to-f VIB ratios compared to the commercially available pneumatically driven transducer. Displacement was constant over a range of f VIB, in accordance with theory. Phantom and in vivo data show low nonlinearity and excellent data quality.

CONCLUSION: The table top measurements are in concordance with the theory behind a transducer based on a rotational eccentric mass. The resulting constant displacement amplitude irrespective of f VIB and low 2nd harmonic-to-f VIB ratio result in low nonlinearity and high data fidelity in both phantom and in vivo examples.

Original language	English
Pages (from-to)	045007
Journal	Physics in medicine and biology
Volume	64
Issue number	4
DOIs	https://doi.org/10.1088/1361-6560/aaf9f8
Publication status	Published - 6 Feb 2019

Keywords

Computer Simulation
Elasticity Imaging Techniques/methods
Gravitation
Healthy Volunteers
Humans
Liver/diagnostic imaging
Magnetic Resonance Imaging/methods
Models, Theoretical
Phantoms, Imaging
Transducers

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https://doi.org/10.1088/1361-6560/aaf9f8

https://iopscience.iop.org/article/10.1088/1361-6560/aaf9f8/pdf

Cite this

Runge, J. H., Hoelzl, S. H., Sudakova, J., Dokumaci, A. S., Nelissen, J. L., Guenthner, C., Lee, J., Troelstra, M., Fovargue, D., Stoker, J., Nederveen, A. J., Nordsletten, D., & Sinkus, R. (2019). A novel magnetic resonance elastography transducer concept based on a rotational eccentric mass: preliminary experiences with the gravitational transducer. Physics in medicine and biology, 64(4), 045007. https://doi.org/10.1088/1361-6560/aaf9f8

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title = "A novel magnetic resonance elastography transducer concept based on a rotational eccentric mass: preliminary experiences with the gravitational transducer",

abstract = "BACKGROUND: Magnetic resonance elastography (MRE) is used to non-invasively estimate biomechanical tissue properties via the imaging of propagating mechanical shear waves. Several factors including mechanical transducer design, MRI sequence design and viscoelastic reconstruction influence data quality and hence the reliability of the derived biomechanical properties.PURPOSE: To design and characterize a novel mechanical MRE transducer concept based on a rotational eccentric mass, coined the gravitational transducer.MATERIALS AND METHODS: Table top measurements were performed using accelerometers to characterize the frequency response of the new transducer concept at different driving frequencies (f VIB) and different rotating masses. These were compared to a commercially available pneumatically driven MRE transducer. MR data were acquired on a 3T scanner using a fractionally encoded gradient echo MRE sequence in three healthy volunteers. Acceleration and displacement spectra were plotted in units of g and mm, respectively, and visually compared, emphasizing the ratio between the peaks at f VIB and its 2nd harmonic, a known cause of error in the reconstruction of biomechanical properties as is explored in more detail in numerical simulations here. No formal statistical testing was performed in this proof-of-principle paper.RESULTS: The new transducer concept shows-as expected from theory-a quadratic or linear increase of acceleration amplitude with increase in f VIB or mass, respectively. Furthermore, different versions of the transducer show markedly lower 2nd harmonic-to-f VIB ratios compared to the commercially available pneumatically driven transducer. Displacement was constant over a range of f VIB, in accordance with theory. Phantom and in vivo data show low nonlinearity and excellent data quality.CONCLUSION: The table top measurements are in concordance with the theory behind a transducer based on a rotational eccentric mass. The resulting constant displacement amplitude irrespective of f VIB and low 2nd harmonic-to-f VIB ratio result in low nonlinearity and high data fidelity in both phantom and in vivo examples.",

keywords = "Computer Simulation, Elasticity Imaging Techniques/methods, Gravitation, Healthy Volunteers, Humans, Liver/diagnostic imaging, Magnetic Resonance Imaging/methods, Models, Theoretical, Phantoms, Imaging, Transducers",

author = "Runge, {Jurgen Henk} and Hoelzl, {Stefan Heinz} and Jelizaveta Sudakova and Dokumaci, {Ayse Sila} and Nelissen, {Jules Laurent} and Christian Guenthner and Jack Lee and Marian Troelstra and Daniel Fovargue and Jaap Stoker and Nederveen, {Aart Johannes} and David Nordsletten and Ralph Sinkus",

year = "2019",

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doi = "https://doi.org/10.1088/1361-6560/aaf9f8",

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Runge, JH, Hoelzl, SH, Sudakova, J, Dokumaci, AS, Nelissen, JL, Guenthner, C, Lee, J, Troelstra, M, Fovargue, D, Stoker, J, Nederveen, AJ, Nordsletten, D & Sinkus, R 2019, 'A novel magnetic resonance elastography transducer concept based on a rotational eccentric mass: preliminary experiences with the gravitational transducer', Physics in medicine and biology, vol. 64, no. 4, pp. 045007. https://doi.org/10.1088/1361-6560/aaf9f8

A novel magnetic resonance elastography transducer concept based on a rotational eccentric mass: preliminary experiences with the gravitational transducer. / Runge, Jurgen Henk; Hoelzl, Stefan Heinz; Sudakova, Jelizaveta et al.
In: Physics in medicine and biology, Vol. 64, No. 4, 06.02.2019, p. 045007.

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

TY - JOUR

T1 - A novel magnetic resonance elastography transducer concept based on a rotational eccentric mass

T2 - preliminary experiences with the gravitational transducer

AU - Runge, Jurgen Henk

AU - Hoelzl, Stefan Heinz

AU - Sudakova, Jelizaveta

AU - Dokumaci, Ayse Sila

AU - Nelissen, Jules Laurent

AU - Guenthner, Christian

AU - Lee, Jack

AU - Troelstra, Marian

AU - Fovargue, Daniel

AU - Stoker, Jaap

AU - Nederveen, Aart Johannes

AU - Nordsletten, David

AU - Sinkus, Ralph

PY - 2019/2/6

Y1 - 2019/2/6

N2 - BACKGROUND: Magnetic resonance elastography (MRE) is used to non-invasively estimate biomechanical tissue properties via the imaging of propagating mechanical shear waves. Several factors including mechanical transducer design, MRI sequence design and viscoelastic reconstruction influence data quality and hence the reliability of the derived biomechanical properties.PURPOSE: To design and characterize a novel mechanical MRE transducer concept based on a rotational eccentric mass, coined the gravitational transducer.MATERIALS AND METHODS: Table top measurements were performed using accelerometers to characterize the frequency response of the new transducer concept at different driving frequencies (f VIB) and different rotating masses. These were compared to a commercially available pneumatically driven MRE transducer. MR data were acquired on a 3T scanner using a fractionally encoded gradient echo MRE sequence in three healthy volunteers. Acceleration and displacement spectra were plotted in units of g and mm, respectively, and visually compared, emphasizing the ratio between the peaks at f VIB and its 2nd harmonic, a known cause of error in the reconstruction of biomechanical properties as is explored in more detail in numerical simulations here. No formal statistical testing was performed in this proof-of-principle paper.RESULTS: The new transducer concept shows-as expected from theory-a quadratic or linear increase of acceleration amplitude with increase in f VIB or mass, respectively. Furthermore, different versions of the transducer show markedly lower 2nd harmonic-to-f VIB ratios compared to the commercially available pneumatically driven transducer. Displacement was constant over a range of f VIB, in accordance with theory. Phantom and in vivo data show low nonlinearity and excellent data quality.CONCLUSION: The table top measurements are in concordance with the theory behind a transducer based on a rotational eccentric mass. The resulting constant displacement amplitude irrespective of f VIB and low 2nd harmonic-to-f VIB ratio result in low nonlinearity and high data fidelity in both phantom and in vivo examples.

AB - BACKGROUND: Magnetic resonance elastography (MRE) is used to non-invasively estimate biomechanical tissue properties via the imaging of propagating mechanical shear waves. Several factors including mechanical transducer design, MRI sequence design and viscoelastic reconstruction influence data quality and hence the reliability of the derived biomechanical properties.PURPOSE: To design and characterize a novel mechanical MRE transducer concept based on a rotational eccentric mass, coined the gravitational transducer.MATERIALS AND METHODS: Table top measurements were performed using accelerometers to characterize the frequency response of the new transducer concept at different driving frequencies (f VIB) and different rotating masses. These were compared to a commercially available pneumatically driven MRE transducer. MR data were acquired on a 3T scanner using a fractionally encoded gradient echo MRE sequence in three healthy volunteers. Acceleration and displacement spectra were plotted in units of g and mm, respectively, and visually compared, emphasizing the ratio between the peaks at f VIB and its 2nd harmonic, a known cause of error in the reconstruction of biomechanical properties as is explored in more detail in numerical simulations here. No formal statistical testing was performed in this proof-of-principle paper.RESULTS: The new transducer concept shows-as expected from theory-a quadratic or linear increase of acceleration amplitude with increase in f VIB or mass, respectively. Furthermore, different versions of the transducer show markedly lower 2nd harmonic-to-f VIB ratios compared to the commercially available pneumatically driven transducer. Displacement was constant over a range of f VIB, in accordance with theory. Phantom and in vivo data show low nonlinearity and excellent data quality.CONCLUSION: The table top measurements are in concordance with the theory behind a transducer based on a rotational eccentric mass. The resulting constant displacement amplitude irrespective of f VIB and low 2nd harmonic-to-f VIB ratio result in low nonlinearity and high data fidelity in both phantom and in vivo examples.

KW - Computer Simulation

KW - Elasticity Imaging Techniques/methods

KW - Gravitation

KW - Healthy Volunteers

KW - Humans

KW - Liver/diagnostic imaging

KW - Magnetic Resonance Imaging/methods

KW - Models, Theoretical

KW - Phantoms, Imaging

KW - Transducers

U2 - https://doi.org/10.1088/1361-6560/aaf9f8

DO - https://doi.org/10.1088/1361-6560/aaf9f8

M3 - Article

C2 - 30566925

SN - 0031-9155

VL - 64

SP - 045007

JO - Physics in medicine and biology

JF - Physics in medicine and biology

IS - 4

ER -