Development of a Trimodal Contrast Agent for Acoustic and Magnetic Particle Imaging of Stem Cells

Lemaster, Jeanne E.; Chen, Fang; Kim, Taeho; Hariri, Ali; Jokerst, Jesse V.

doi:10.1021/acsanm.8b00063

Cited by 66 publications

(70 citation statements)

References 78 publications

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“…For PTX‐MB, the depth of imaging is currently limited by the penetration of 680 nm light in tissue, but photoacoustics can be coupled with other modalities such as ultrasound or magnetic resonance to locate the drug delivery site . This is a powerful tool to monitor the location and concentration of drugs and determine whether they remain encapsulated in nanocarriers.…”

Section: Resultsmentioning

confidence: 99%

Photoacoustic Imaging Quantifies Drug Release from Nanocarriers via Redox Chemistry of Dye‐Labeled Cargo

et al. 2020

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We report a new approach to monitor drug release from nanocarriers via a paclitaxel–methylene blue conjugate (PTX‐MB) with redox activity. This construct is in a photoacoustically silent reduced state inside poly(lactic‐co‐glycolic acid) (PLGA) nanoparticles (PTX‐MB@PLGA NPs). During release, PTX‐MB is spontaneously oxidized to produce a concentration‐dependent photoacoustic signal. An in vitro drug‐release study showed an initial burst release (25 %) between 0–24 h and a sustained release between 24–120 h with a cumulative release of 40.6 % and a 670‐fold increase in photoacoustic signal. An in vivo murine drug release showed a photoacoustic signal enhancement of up to 649 % after 10 hours. PTX‐MB@PLGA NPs showed an IC50 of 78 μg mL−1 and 44.7±4.8 % decrease of tumor burden in an orthotopic model of colon cancer via luciferase‐positive CT26 cells.

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Section: Resultsmentioning

confidence: 99%

Photoacoustic Imaging Quantifies Drug Release from Nanocarriers via Redox Chemistry of Dye‐Labeled Cargo

et al. 2020

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“…Since these studies have used very small FOV’s for brain or liver (not whole mouse FOV), with each cell containing >100-fold iron content, these MRI studies do not allow a proper comparison for its sensitivity of MPI. Multi-modal MPI cell tracking agents are now also being developed, although at the cost of a lower sensitivity in the order of 1 million cells [29]. …”

Section: Spios As Mpi Tracersmentioning

confidence: 99%

Superparamagnetic iron oxides as MPI tracers: A primer and review of early applications

Bulte

2019

Advanced Drug Delivery Reviews

149

123

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Magnetic particle imaging (MPI) has recently emerged as a non-invasive, whole body imaging technique that detects superparamagnetic iron oxide (SPIO) nanoparticles similar as those used in magnetic resonance imaging (MRI). Based on tracer “hot spot” detection instead of providing contrast on MRI scans, MPI has already proven to be truly quantitative. Without the presence of endogenous background signal, MPI can also be used in certain tissues where the endogenous MRI signal is too low to provide contrast. After an introduction to the history and simplified principles of MPI, this review focuses on early MPI applications including MPI cell tracking, multiplexed MPI, perfusion and tumor MPI, lung MPI, functional MPI, and MPI-guided hyperthermia. While it is too early to tell if MPI will become a mainstay imaging technique with the (theoretical) sensitivity that it promises, and if it can successfully compete with SPIO-based 1H MRI and perfluorocarbon-based 19F MRI, it provides unprecedented opportunities for exploring new nanoparticle-based imaging applications.

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“…Moreover, the neural implant work imaged stem cells over 87 days, a study which would not be possible with the clinical tracer modalities today due to the need for radioactively decaying tracers. These early studies on stem cell lines have sparked further interest in the field of MPI stem cell tracking, leading to work demonstrating that MPI can be used to image pancreatic islet transplants in mice and work developing new nanoparticle agents for multimodal imaging of stem cells, including via MPI 29,30 . These studies demonstrated up to 200-cell sensitivity, which is far more sensitive than other medical imaging modalities 31 .…”

Section: Cell Trackingmentioning

confidence: 99%

Magnetic particle imaging for radiation-free, sensitive and high-contrast vascular imaging and cell tracking

Zhou

Tay

Chandrasekharan

et al. 2018

Current Opinion in Chemical Biology

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Magnetic particle imaging (MPI) is an emerging ionizing radiation-free biomedical tracer imaging technique that directly images the intense magnetization of superparamagnetic iron oxide nanoparticles (SPIOs). MPI offers ideal image contrast because MPI shows zero signal from background tissues. Moreover, there is zero attenuation of the signal with depth in tissue, allowing for imaging deep inside the body quantitatively at any location. Recent work has demonstrated the potential of MPI for robust, sensitive vascular imaging and cell tracking with high contrast and dose-limited sensitivity comparable to nuclear medicine. To foster future applications in MPI, this new biomedical imaging field is welcoming researchers with expertise in imaging physics, magnetic nanoparticle synthesis and functionalization, nanoscale physics, and small animal imaging applications.

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Development of a Trimodal Contrast Agent for Acoustic and Magnetic Particle Imaging of Stem Cells

Cited by 66 publications

References 78 publications

Photoacoustic Imaging Quantifies Drug Release from Nanocarriers via Redox Chemistry of Dye‐Labeled Cargo

Photoacoustic Imaging Quantifies Drug Release from Nanocarriers via Redox Chemistry of Dye‐Labeled Cargo

Superparamagnetic iron oxides as MPI tracers: A primer and review of early applications

Magnetic particle imaging for radiation-free, sensitive and high-contrast vascular imaging and cell tracking

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