MR Contrast in Mouse Lymph Nodes with Subcutaneous Administration of Iron Oxide Particles: Size Dependency

Mori, Yutaka; Umeda, Masahiro; Fukunaga, Masaki; Ogasawara, Kuniaki; Yoshioka, Yoshichika

doi:10.2463/mrms.10.219

Cited by 23 publications

(16 citation statements)

References 27 publications

(38 reference statements)

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“…To overcome inherent limitations in the signal to noise ratio (SNR) of conventional in vivo MRI, a stronger magnetic field can be applied. In addition, super-paramagnetic nanoparticles of iron oxide (SPIO), a contrast agent for MRI, improves MRI contrast to noise ratio (CNR) and detectability in the stronger magnetic fields by shortening the T 2 /T 2 * relaxation time, further advancing MRI application in cell imaging and tracking789. Combining high-magnetic-field strength with high-sensitivity radio-frequency (RF) coils and optimal contrast agents enables the visualisation of cell populations and molecular events in vivo in both animals and humans910.…”

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confidence: 99%

From cartoon to real time MRI: in vivo monitoring of phagocyte migration in mouse brain

Mori

Chen

Fujisawa

et al. 2014

Sci Rep

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Recent studies have demonstrated that immune cells play an important role in the pathogenesis of many neurological conditions. Immune cells constantly survey the brain microvasculature for irregularities in levels of factors that signal homeostasis. Immune responses are initiated when necessary, resulting in mobilisation of the microglial cells resident in the central nervous system (CNS) and/or of infiltrating peripheral cells. However, little is known about the kinetics of immune cells in healthy and diseased CNS, because it is difficult to perform long-term visualisation of cell motility in live tissue with minimal invasion. Here, we describe highly sensitive in vivo MRI techniques for sequential monitoring of cell migration in the CNS at the single-cell level. We show that MRI combined with intravenous administration of super-paramagnetic particles of iron oxide (SPIO) can be used to monitor the transmigration of peripheral phagocytes into healthy or LPS-treated mouse brains. We also demonstrate dynamic cell migration in live animal brains with time-lapse MRI videos. Time-lapse MRI was used to visualise and track cells with low motility in a control mouse brain. High-sensitivity MRI cell tracking using SPIO offers new insights into immune cell kinetics in the brain and the mechanisms of CNS homeostasis.

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From cartoon to real time MRI: in vivo monitoring of phagocyte migration in mouse brain

Mori

Chen

Fujisawa

et al. 2014

Sci Rep

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“…The purpose of these studies was to optimize tracer uptake in the SLNs to facilitate preoperative localization with MRI, rather than intraoperative detection. Mori et al 30 used 50 nm, 100 nm, 200 nm, and 1,000 nm-sized particles and concluded that particles of 200 nm and larger are not suitable in view of lack of uptake within 24 hours. Iida et al 28 compared the performance of 4 nm, 8 nm, and 20 nm citrate-coated nanoparticles and concluded that the 20 nm particles were best retained in the SLNs and accumulated in the highest concentration.…”

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confidence: 99%

“…[28][29][30] Tracers with particle sizes ranging from 4 to 1,000 nm were used in these studies. The purpose of these studies was to optimize tracer uptake in the SLNs to facilitate preoperative localization with MRI, rather than intraoperative detection.…”

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confidence: 99%

Comparison of three magnetic nanoparticle tracers for sentinel lymph node biopsy in an in vivo porcine model

Pouw¹,

Ahmed²,

Anninga³

et al. 2015

IJN

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Introduction Breast cancer staging with sentinel lymph node biopsy relies on the use of radioisotopes, which limits the availability of the procedure worldwide. The use of a magnetic nanoparticle tracer and a handheld magnetometer provides a radiation-free alternative, which was recently evaluated in two clinical trials. The hydrodynamic particle size of the used magnetic tracer differs substantially from the radioisotope tracer and could therefore benefit from optimization. The aim of this study was to assess the performance of three different-sized magnetic nanoparticle tracers for sentinel lymph node biopsy within an in vivo porcine model. Materials and methods Sentinel lymph node biopsy was performed within a validated porcine model using three magnetic nanoparticle tracers, approved for use in humans (ferumoxytol, with hydrodynamic diameter d H =32 nm; Sienna+ ® , d H =59 nm; and ferumoxide, d H =111 nm), and a handheld magnetometer. Magnetometer counts (transcutaneous and ex vivo), iron quantification (vibrating sample magnetometry), and histopathological assessments were performed on all ex vivo nodes. Results Transcutaneous “hotspots” were present in 12/12 cases within 30 minutes of injection for the 59 nm tracer, compared to 7/12 for the 32 nm tracer and 8/12 for the 111 nm tracer, at the same time point. Ex vivo magnetometer counts were significantly greater for the 59 nm tracer than for the other tracers. Significantly more nodes per basin were excised for the 32 nm tracer compared to other tracers, indicating poor retention of the 32 nm tracer. Using the 59 nm tracer resulted in a significantly higher iron accumulation compared to the 32 nm tracer. Conclusion The 59 nm tracer demonstrated rapid lymphatic uptake, retention in the first nodes reached, and accumulation in high concentration, making it the most suitable tracer for intraoperative sentinel lymph node localization.

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“…Mori et al developed a novel method for monitoring single cell dynamics of macrophages using a high tesla magnetic resonance imaging (MRl) system [3] [4]. It acquires time series sectional macrophage images with contrast using 11.7 T MRI.…”

Section: Introductionmentioning

confidence: 99%

Image alignment for single-cell imaging of macrophage in the mouse brain using 11.7T MRI

Kobashi

Mori

Yoshioka

et al. 2014

2014 World Automation Congress (WAC)

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Macrophage is one of white blood cells, and plays an important role of the immune system. Tracking the single macrophage cells in vivo will be a powerful tool for immunology studies. State-of-the-arts imaging using magnetic resonance imaging (MRI) enables us to acquire images of 3-D dynamic single macrophage cells in vivo. However, due to motion artifacts and magnetic field fluctuations, a post-processing is required to observe macrophage cells. This paper proposes an image analysis method for 11.7T animal MRI images of macro phages in the mouse brain. The method adjusts the motion artifacts by a rigid image registration technique, and calibrates MR signal intensity fluctuation by using an optimization technique. The method was applied to mouse brain MR images, and the results were validated by observers. IndexTerms-Magnetic resonance imaging, Single macrophage cells, in vivo, image alignment, image registration

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MR Contrast in Mouse Lymph Nodes with Subcutaneous Administration of Iron Oxide Particles: Size Dependency

Cited by 23 publications

References 27 publications

From cartoon to real time MRI: in vivo monitoring of phagocyte migration in mouse brain

From cartoon to real time MRI: in vivo monitoring of phagocyte migration in mouse brain

Comparison of three magnetic nanoparticle tracers for sentinel lymph node biopsy in an in vivo porcine model

Image alignment for single-cell imaging of macrophage in the mouse brain using 11.7T MRI

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MR Contrast in Mouse Lymph Nodes with Subcutaneous Administration of Iron Oxide Particles: Size Dependency

Cited by 23 publications

References 27 publications

From cartoon to real time MRI: in vivo monitoring of phagocyte migration in mouse brain

From cartoon to real time MRI: in vivo monitoring of phagocyte migration in mouse brain

Comparison of three magnetic nanoparticle tracers for sentinel lymph node biopsy in an in&nbsp;vivo porcine model

Image alignment for single-cell imaging of macrophage in the mouse brain using 11.7T MRI

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Comparison of three magnetic nanoparticle tracers for sentinel lymph node biopsy in an in vivo porcine model