Abstract
Magnetic resonance imaging (MRI) cell tracking of cancer cells labeled with superparamagnetic iron oxides (SPIO) allows visualizing metastatic cells in preclinical models. However, previous works showed that the signal void induced by SPIO on T2(*)-weighted images decreased over time. Here, we aim at characterizing the fate of iron oxide nanoparticles used in cell tracking studies and the role of macrophages in SPIO metabolism.In vivo MRI cell tracking of SPIO positive 4T1 breast cancer cells revealed a quick loss of T2* contrast after injection. We next took advantage of electron paramagnetic resonance (EPR) spectroscopy and inductively coupled plasma mass spectroscopy (ICP-MS) for characterizing the evolution of superparamagnetic and non-superparamagnetic iron pools in 4T1 breast cancer cells and J774 macrophages after SPIO labeling. These in vitro experiments and histology studies performed on 4T1 tumors highlighted the quick degradation of iron oxides by macrophages in SPIO-based cell tracking experiments.In conclusion, the release of SPIO by dying cancer cells and the subsequent uptake of iron oxides by tumor macrophages are limiting factors in MRI cell tracking experiments that plead for the use of (MR) reporter-gene based imaging methods for the long-term tracking of metastatic cells.
Highlights
Metastasis is the leading cause of cancer-related death [1]
Using magnetic resonance imaging (MRI) (11.7 T), we first tracked green fluorescent protein-tagged 4T1 (4T1-Green fluorescent protein (GFP)) cells labeled with Modlay Ion Rhodamine B (MIRB) superparamagnetic iron oxides (SPIO) in vivo
SPIO-based MRI cell tracking can be used for monitoring the fate of cancer and tumor-associated cells
Summary
Metastasis is the leading cause of cancer-related death [1]. Despite the development of new effective anticancer treatments, metastases are still difficult to treat. It is crucial to develop preclinical imaging tools for monitoring the metastatic cascade and for understanding its features in vivo. Cell tracking or cellular imaging is defined as the “non-invasive and repetitive imaging of targeted cells and cellular processes in living organisms” [2]. Applications of cellular imaging include the monitoring of stem cells in cell-based therapies and the visualization of metastatic cancer cells in small animals [3]. In magnetic resonance imaging (MRI) cell tracking studies, cells are first labeled in vitro with contrast agents prior to their injection in vivo
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