Magnetic Particle Imaging (MPI): Experimental Quantification of Vascular Stenosis Using Stationary Stenosis Phantoms

Vaalma, Sarah; Rahmer, Jürgen; Panagiotopoulos, Nikolaos; Duschka, R. L.; Borgert, J.; Barkhausen, Jörg; Vogt, Florian; Haegele, Julian

doi:10.1371/journal.pone.0168902

Cited by 66 publications

(50 citation statements)

References 53 publications

(61 reference statements)

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“…In contrast to magnetic resonance imaging, the contrast in MPI is positive and the reconstructed images are quantitative. With these properties MPI is an interesting candidate for various medical applications ranging from vascular imaging [2][3][4][5] to targeted imaging [6].…”

Section: Introductionmentioning

confidence: 99%

Towards accurate modeling of the multidimensional magnetic particle imaging physics

2019

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The image reconstruction problem of the tomographic imaging technique magnetic particle imaging (MPI) requires the solution of a linear inverse problem. One prerequisite for this task is that the imaging operator that describes the mapping between the tomographic image and the measured signal is accurately known. For 2D and 3D excitation patterns, it is common to measure the system matrix in a calibration procedure, that is both, very time consuming and adds noise to the operator. The need for measuring the system matrix is due to the lack of an accurate model that is capable of describing the nanoparticles' magnetization behavior in the MPI setup. Within this work we exploit a physical model that is based on Néel rotation for large particle ensembles and we find model parameters that describe measured 2D MPI data with much higher precision than state of the art MPI models. With phantom experiments we show that the simulated system matrix can be used for image reconstruction and reduces artifacts due to model-mismatch considerably.

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Section: Introductionmentioning

confidence: 99%

Towards accurate modeling of the multidimensional magnetic particle imaging physics

2019

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“…An advanced biplane DSA measurements can be post-processed to gain a 3D information over time, which however leads to a doubled radiation exposure. Further, MPI has demonstrated its beneficial usage in several interventional applications such as catheter tracking, stenosis identification and stenosis clearing [26][27][28]. Catheters and guide wires are coated with magnetic markers to track their position with MPI in real time [29][30][31][32][33].…”

Section: Introductionmentioning

confidence: 99%

In-Vitro MPI-guided IVOCT catheter tracking in real time for motion artifact compensation

Griese¹,

Latus²,

Schlüter³

et al. 2020

PLoS ONE

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Using 4D magnetic particle imaging (MPI), intravascular optical coherence tomography (IVOCT) catheters are tracked in real time in order to compensate for image artifacts related to relative motion. Our approach demonstrates the feasibility for bimodal IVOCT and MPI invitro experiments. Material and methods During IVOCT imaging of a stenosis phantom the catheter is tracked using MPI. A 4D trajectory of the catheter tip is determined from the MPI data using center of mass sub-voxel strategies. A custom built IVOCT imaging adapter is used to perform different catheter motion profiles: no motion artifacts, motion artifacts due to catheter bending, and heart beat motion artifacts. Two IVOCT volume reconstruction methods are compared qualitatively and quantitatively using the DICE metric and the known stenosis length. Results The MPI-tracked trajectory of the IVOCT catheter is validated in multiple repeated measurements calculating the absolute mean error and standard deviation. Both volume reconstruction methods are compared and analyzed whether they are capable of compensating the motion artifacts. The novel approach of MPI-guided catheter tracking corrects motion artifacts leading to a DICE coefficient with a minimum of 86% in comparison to 58% for a standard reconstruction approach. Conclusions IVOCT catheter tracking with MPI in real time is an auspicious method for radiation free MPIguided IVOCT interventions. The combination of MPI and IVOCT can help to reduce motion artifacts due to catheter bending and heart beat for optimized IVOCT volume reconstructions.

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“…MPI has proven to be suited for vascular imaging while offering a spatial resolution in the range of 0.5–5 mm. This suffices to quantify vascular stenosis . Catheters and guide wires can be coated with magnetic nanoparticles enabling their visualization in MPI .…”

Section: Introductionmentioning

confidence: 99%

“…This suffices to quantify vascular stenosis. 22,23 Catheters and guide wires can be coated with magnetic nanoparticles enabling their visualization in MPI. 24 Using multispectral reconstruction techniques, 25 it is even possible to simultaneously image the coated instrument/catheter and the blood pool tracer making navigation tasks possible.…”

Section: Introductionmentioning

confidence: 99%

Bimodal intravascular volumetric imaging combining OCT and MPI

et al. 2019

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Purpose Intravascular optical coherence tomography (IVOCT) is a catheter‐based image modality allowing for high‐resolution imaging of vessels. It is based on a fast sequential acquisition of A‐scans with an axial spatial resolution in the range of 5–10 μm, that is, one order of magnitude higher than in conventional methods like intravascular ultrasound or computed tomography angiography. However, position and orientation of the catheter in patient coordinates cannot be obtained from the IVOCT measurements alone. Hence, the pose of the catheter needs to be established to correctly reconstruct the three‐dimensional vessel shape. Magnetic particle imaging (MPI) is a three‐dimensional tomographic, tracer‐based, and radiation‐free image modality providing high temporal resolution with unlimited penetration depth. Volumetric MPI images are angiographic and hence suitable to complement IVOCT as a comodality. We study simultaneous bimodal IVOCT MPI imaging with the goal of estimating the IVOCT pullback path based on the 3D MPI data. Methods We present a setup to study and evaluate simultaneous IVOCT and MPI image acquisition of differently shaped vessel phantoms. First, the influence of the MPI tracer concentration on the optical properties required for IVOCT is analyzed. Second, using a concentration allowing for simultaneous imaging, IVOCT and MPI image data are acquired sequentially and simultaneously. Third, the luminal centerline is established from the MPI image volumes and used to estimate the catheter pullback trajectory for IVOCT image reconstruction. The image volumes are compared to the known shape of the phantoms. Results We were able to identify a suitable MPI tracer concentration of 2.5 mmol/L with negligible influence on the IVOCT signal. The pullback trajectory estimated from MPI agrees well with the centerline of the phantoms. Its mean absolute error ranges from 0.27 to 0.28 mm and from 0.25 mm to 0.28 mm for sequential and simultaneous measurements, respectively. Likewise, reconstructing the shape of the vessel phantoms works well with mean absolute errors for the diameter ranging from 0.11 to 0.21 mm and from 0.06 to 0.14 mm for sequential and simultaneous measurements, respectively. Conclusions Magnetic particle imaging can be used in combination with IVOCT to estimate the catheter trajectory and the vessel shape with high precision and without ionizing radiation.

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Magnetic Particle Imaging (MPI): Experimental Quantification of Vascular Stenosis Using Stationary Stenosis Phantoms

Cited by 66 publications

References 53 publications

Towards accurate modeling of the multidimensional magnetic particle imaging physics

Towards accurate modeling of the multidimensional magnetic particle imaging physics

In-Vitro MPI-guided IVOCT catheter tracking in real time for motion artifact compensation

Bimodal intravascular volumetric imaging combining OCT and MPI

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