Clinical imaging in regenerative medicine

Naumova, Anna V.; Modo, Michel; Moore, Anna; Murry, Charles E.; Frank, Joseph A.

doi:10.1038/nbt.2993

Cited by 210 publications

(235 citation statements)

References 162 publications

(209 reference statements)

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“…Reduction of extracellular NPs is essential for the correct interpretation of downstream cell toxicity assays 66,67 and for improving MRI single-cell detection, because extracellular NPs will be most probably lost during cell migration.…”

Section: Discussionmentioning

confidence: 99%

Labeling of mesenchymal stem cells for MRI with single-cell sensitivity

Schellenberger¹,

Kratz²,

Farr³

et al. 2016

IJN

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Sensitive cell detection by magnetic resonance imaging (MRI) is an important tool for the development of cell therapies. However, clinically approved contrast agents that allow single-cell detection are currently not available. Therefore, we compared very small iron oxide nanoparticles (VSOP) and new multicore carboxymethyl dextran-coated iron oxide nanoparticles (multicore particles, MCP) designed by our department for magnetic particle imaging (MPI) with discontinued Resovist ® regarding their suitability for detection of single mesenchymal stem cells (MSC) by MRI. We achieved an average intracellular nanoparticle (NP) load of >10 pg Fe per cell without the use of transfection agents. NP loading did not lead to significantly different results in proliferation, colony formation, and multilineage in vitro differentiation assays in comparison to controls. MRI allowed single-cell detection using VSOP, MCP, and Resovist ® in conjunction with high-resolution T2*-weighted imaging at 7 T with postprocessing of phase images in agarose cell phantoms and in vivo after delivery of 2,000 NP-labeled MSC into mouse brains via the left carotid artery. With optimized labeling conditions, a detection rate of ~45% was achieved; however, the experiments were limited by nonhomogeneous NP loading of the MSC population. Attempts should be made to achieve better cell separation for homogeneous NP loading and to thus improve NP-uptake-dependent biocompatibility studies and cell detection by MRI and future MPI. Additionally, using a 7 T MR imager equipped with a cryocoil resulted in approximately two times higher detection. In conclusion, we established labeling conditions for new high-relaxivity MCP, VSOP, and Resovist ® for improved MRI of MSC with single-cell sensitivity.

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Section: Discussionmentioning

confidence: 99%

Labeling of mesenchymal stem cells for MRI with single-cell sensitivity

Schellenberger¹,

Kratz²,

Farr³

et al. 2016

IJN

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“…The most commonly used methods are summarized in Table 2 and have been thoroughly reviewed in studies by Kircher et al, 9 Hong et al, 21 Naumova et al, 22 James and Gambhir, 34 Chen et al, 35 and Zhang et al 36 For preclinical or clinical studies, it is essential to consider the advantages and disadvantages of each molecular imaging modality. The challenge is to develop effective imaging strategies with a combination of imaging modalities, labeling reporter systems, and probes.…”

Section: Labeling Stem Cells and Molecular Imaging Methodsmentioning

confidence: 99%

“…SPIONs, fluorescent dyes, or radionuclides can be used as probes to directly prelabel stem cells for noninvasive tracking. 9,[21][22][23] Standardized protocols used for labeling stem cells with SPIONs were previously compiled by us, 15,24 and other direct-labeling reagents were reviewed by Marks and Nolan 25 and Progatzky et al 26 Indirect labeling is a considerably different method, which includes genetic modification in order to either produce an appropriate signal-generating molecule or increase the affinity of cells to contrast agents. 9,21,[27][28][29][30][31][32] Transient expression of reporter proteins by DNA vector transfection is often included in this set of cell labeling.…”

Section: Labeling Stem Cells and Molecular Imaging Methodsmentioning

confidence: 99%

Tracking stem cells with superparamagnetic iron oxide nanoparticles: perspectives and considerations

Jasmin¹,

Souza²,

Louzada³

et al. 2017

IJN

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Superparamagnetic iron oxide nanoparticles (SPIONs) have been used for diagnoses in biomedical applications, due to their unique properties and their apparent safety for humans. In general, SPIONs do not seem to produce cell damage, although their long-term in vivo effects continue to be investigated. The possibility of efficiently labeling cells with these magnetic nanoparticles has stimulated their use to noninvasively track cells by magnetic resonance imaging after transplantation. SPIONs are attracting increasing attention and are one of the preferred methods for cell labeling and tracking in preclinical and clinical studies. For clinical protocol approval of magnetic-labeled cell tracking, it is essential to expand our knowledge of the time course of SPIONs after cell incorporation and transplantation. This review focuses on the recent advances in tracking SPION-labeled stem cells, analyzing the possibilities and limitations of their use, not only focusing on myocardial infarction but also discussing other models.

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“…Indeed, cell therapy in a clinical setting is likely to require the use of diagnostic imaging to define patients who will benefit from the intervention and also to guide and monitor the effects of cell therapy. Clinical imaging techniques, such as computer tomography (CT), positron emission tomography (PET), and magnetic resonance imaging (MRI), have all been incorporated in early translational trials [8]. For instance, PET imaging of dopaminergic receptor binding has been crucial to demonstrate the functional activity of fetal tissue transplants in animal models [9], as well as patients with Parkinson's disease [10].…”

Section: Introductionmentioning

confidence: 99%

Gaining Mechanistic Insights into Cell Therapy Using Magnetic Resonance Imaging

Modo

2016

Curr Stem Cell Rep

Self Cite

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Cell therapy remains a promising approach to treat neurological disorders with evidence of clinical efficacy emerging. However, the mechanisms underlying recovery and the conditions to achieve therapeutic success are poorly understood. Uncovering putative mechanisms and their interaction is essential to progress cell therapy from an interesting and promising possibility to a robust and consistent treatment that can be used to treat large cohorts of patients. Although there is a heavy focus on stem cell biology, relatively little effort has been dedicated to understanding the in vivo mechanisms that underlie efficacy. In vivo imaging and the development of appropriate biomarkers will be essential to gain a better mechanistic understanding of cell therapy in the treatment of neurological disease. The availability of magnetic resonance imaging in a clinical setting and its use in animal models allow for its use as a unique platform for mechanistic studies of cell therapy in a translational context.

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Clinical imaging in regenerative medicine

Cited by 210 publications

References 162 publications

Labeling of mesenchymal stem cells for MRI with single-cell sensitivity

Labeling of mesenchymal stem cells for MRI with single-cell sensitivity

Tracking stem cells with superparamagnetic iron oxide nanoparticles: perspectives and considerations

Gaining Mechanistic Insights into Cell Therapy Using Magnetic Resonance Imaging

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