Magnetic Particle Imaging for High Temporal Resolution Assessment of Aneurysm Hemodynamics

Jan Sedlacik; Andreas Frölich; Johanna Spallek; Nils D Forkert; Tobias D Faizy; Franziska Werner; Tobias Knopp; Dieter Krause; Jens Fiehler; Jan-Hendrik Buhk

doi:10.1371/journal.pone.0160097

Magnetic Particle Imaging for High Temporal Resolution Assessment of Aneurysm Hemodynamics

Standard

Magnetic Particle Imaging for High Temporal Resolution Assessment of Aneurysm Hemodynamics. / Sedlacik, Jan; Frölich, Andreas; Spallek, Johanna; Forkert, Nils D; Faizy, Tobias D; Werner, Franziska; Knopp, Tobias; Krause, Dieter; Fiehler, Jens; Buhk, Jan-Hendrik.

in: PLOS ONE, Jahrgang 11, Nr. 8, 2016, S. e0160097.

Publikationen: SCORING: Beitrag in Fachzeitschrift/Zeitung › SCORING: Zeitschriftenaufsatz › Forschung › Begutachtung

Harvard

Sedlacik, J, Frölich, A, Spallek, J, Forkert, ND, Faizy, TD, Werner, F, Knopp, T, Krause, D, Fiehler, J & Buhk, J-H 2016, 'Magnetic Particle Imaging for High Temporal Resolution Assessment of Aneurysm Hemodynamics', PLOS ONE, Jg. 11, Nr. 8, S. e0160097. https://doi.org/10.1371/journal.pone.0160097

APA

Sedlacik, J., Frölich, A., Spallek, J., Forkert, N. D., Faizy, T. D., Werner, F., Knopp, T., Krause, D., Fiehler, J., & Buhk, J-H. (2016). Magnetic Particle Imaging for High Temporal Resolution Assessment of Aneurysm Hemodynamics. PLOS ONE, 11(8), e0160097. https://doi.org/10.1371/journal.pone.0160097

Vancouver

Sedlacik J, Frölich A, Spallek J, Forkert ND, Faizy TD, Werner F et al. Magnetic Particle Imaging for High Temporal Resolution Assessment of Aneurysm Hemodynamics. PLOS ONE. 2016;11(8):e0160097. https://doi.org/10.1371/journal.pone.0160097

Bibtex

@article{6168b9e92d0e469c98a478bbc08d49c0,

title = "Magnetic Particle Imaging for High Temporal Resolution Assessment of Aneurysm Hemodynamics",

abstract = "PURPOSE: The purpose of this work was to demonstrate the capability of magnetic particle imaging (MPI) to assess the hemodynamics in a realistic 3D aneurysm model obtained by additive manufacturing. MPI was compared with magnetic resonance imaging (MRI) and dynamic digital subtraction angiography (DSA).MATERIALS AND METHODS: The aneurysm model was of saccular morphology (7 mm dome height, 5 mm cross-section, 3-4 mm neck, 3.5 mm parent artery diameter) and connected to a peristaltic pump delivering a physiological flow (250 mL/min) and pulsation rate (70/min). High-resolution (4 h long) 4D phase contrast flow quantification (4D pc-fq) MRI was used to directly assess the hemodynamics of the model. Dynamic MPI, MRI, and DSA were performed with contrast agent injections (3 mL volume in 3 s) through a proximally placed catheter.RESULTS AND DISCUSSION: 4D pc-fq measurements showed distinct pulsatile flow velocities (20-80 cm/s) as well as lower flow velocities and a vortex inside the aneurysm. All three dynamic methods (MPI, MRI, and DSA) also showed a clear pulsation pattern as well as delayed contrast agent dynamics within the aneurysm, which is most likely caused by the vortex within the aneurysm. Due to the high temporal resolution of MPI and DSA, it was possible to track the contrast agent bolus through the model and to estimate the average flow velocity (about 60 cm/s), which is in accordance with the 4D pc-fq measurements.CONCLUSIONS: The ionizing radiation free, 4D high resolution MPI method is a very promising tool for imaging and characterization of hemodynamics in human. It carries the possibility of overcoming certain disadvantages of other modalities like considerably lower temporal resolution of dynamic MRI and limited 2D characteristics of DSA. Furthermore, additive manufacturing is the key for translating powerful pre-clinical techniques into the clinic.",

keywords = "Journal Article",

author = "Jan Sedlacik and Andreas Fr{\"o}lich and Johanna Spallek and Forkert, {Nils D} and Faizy, {Tobias D} and Franziska Werner and Tobias Knopp and Dieter Krause and Jens Fiehler and Jan-Hendrik Buhk",

year = "2016",

doi = "10.1371/journal.pone.0160097",

language = "English",

volume = "11",

pages = "e0160097",

journal = "PLOS ONE",

issn = "1932-6203",

publisher = "Public Library of Science",

number = "8",

}

RIS

TY - JOUR

T1 - Magnetic Particle Imaging for High Temporal Resolution Assessment of Aneurysm Hemodynamics

AU - Sedlacik, Jan

AU - Frölich, Andreas

AU - Spallek, Johanna

AU - Forkert, Nils D

AU - Faizy, Tobias D

AU - Werner, Franziska

AU - Knopp, Tobias

AU - Krause, Dieter

AU - Fiehler, Jens

AU - Buhk, Jan-Hendrik

PY - 2016

Y1 - 2016

N2 - PURPOSE: The purpose of this work was to demonstrate the capability of magnetic particle imaging (MPI) to assess the hemodynamics in a realistic 3D aneurysm model obtained by additive manufacturing. MPI was compared with magnetic resonance imaging (MRI) and dynamic digital subtraction angiography (DSA).MATERIALS AND METHODS: The aneurysm model was of saccular morphology (7 mm dome height, 5 mm cross-section, 3-4 mm neck, 3.5 mm parent artery diameter) and connected to a peristaltic pump delivering a physiological flow (250 mL/min) and pulsation rate (70/min). High-resolution (4 h long) 4D phase contrast flow quantification (4D pc-fq) MRI was used to directly assess the hemodynamics of the model. Dynamic MPI, MRI, and DSA were performed with contrast agent injections (3 mL volume in 3 s) through a proximally placed catheter.RESULTS AND DISCUSSION: 4D pc-fq measurements showed distinct pulsatile flow velocities (20-80 cm/s) as well as lower flow velocities and a vortex inside the aneurysm. All three dynamic methods (MPI, MRI, and DSA) also showed a clear pulsation pattern as well as delayed contrast agent dynamics within the aneurysm, which is most likely caused by the vortex within the aneurysm. Due to the high temporal resolution of MPI and DSA, it was possible to track the contrast agent bolus through the model and to estimate the average flow velocity (about 60 cm/s), which is in accordance with the 4D pc-fq measurements.CONCLUSIONS: The ionizing radiation free, 4D high resolution MPI method is a very promising tool for imaging and characterization of hemodynamics in human. It carries the possibility of overcoming certain disadvantages of other modalities like considerably lower temporal resolution of dynamic MRI and limited 2D characteristics of DSA. Furthermore, additive manufacturing is the key for translating powerful pre-clinical techniques into the clinic.

AB - PURPOSE: The purpose of this work was to demonstrate the capability of magnetic particle imaging (MPI) to assess the hemodynamics in a realistic 3D aneurysm model obtained by additive manufacturing. MPI was compared with magnetic resonance imaging (MRI) and dynamic digital subtraction angiography (DSA).MATERIALS AND METHODS: The aneurysm model was of saccular morphology (7 mm dome height, 5 mm cross-section, 3-4 mm neck, 3.5 mm parent artery diameter) and connected to a peristaltic pump delivering a physiological flow (250 mL/min) and pulsation rate (70/min). High-resolution (4 h long) 4D phase contrast flow quantification (4D pc-fq) MRI was used to directly assess the hemodynamics of the model. Dynamic MPI, MRI, and DSA were performed with contrast agent injections (3 mL volume in 3 s) through a proximally placed catheter.RESULTS AND DISCUSSION: 4D pc-fq measurements showed distinct pulsatile flow velocities (20-80 cm/s) as well as lower flow velocities and a vortex inside the aneurysm. All three dynamic methods (MPI, MRI, and DSA) also showed a clear pulsation pattern as well as delayed contrast agent dynamics within the aneurysm, which is most likely caused by the vortex within the aneurysm. Due to the high temporal resolution of MPI and DSA, it was possible to track the contrast agent bolus through the model and to estimate the average flow velocity (about 60 cm/s), which is in accordance with the 4D pc-fq measurements.CONCLUSIONS: The ionizing radiation free, 4D high resolution MPI method is a very promising tool for imaging and characterization of hemodynamics in human. It carries the possibility of overcoming certain disadvantages of other modalities like considerably lower temporal resolution of dynamic MRI and limited 2D characteristics of DSA. Furthermore, additive manufacturing is the key for translating powerful pre-clinical techniques into the clinic.

KW - Journal Article

U2 - 10.1371/journal.pone.0160097

DO - 10.1371/journal.pone.0160097

M3 - SCORING: Journal article

C2 - 27494610

VL - 11

SP - e0160097

JO - PLOS ONE

JF - PLOS ONE

SN - 1932-6203

IS - 8

ER -