Our paper entitled "The magnetic field of magnetic resonance imaging systems does not affect cells labeled with micrometer-sized iron oxide particles," has been accepted for publication in Tissue Engineering, Part C: Methods. Authors are Martin Kluge, Annekatrin Leder, Karl H. Hillebrandt, Benjamin Struecker, Dominik Geisel, Timm Denecke, Rebeka D. Major, Anja Reutzel-Selke, Peter Tang, Steffen Lippert, Christian Schmidt, Johann Pratschke, Igor M. Sauer, and Nathanael Raschzok.

Labeling using iron oxide particles enables cell tracking via magnetic resonance imaging (MRI). However, the magnetic field can affect the particle-labeled cells. Here, we investigated the effects of a clinical MRI system on primary human hepatocytes labeled using micrometer-sized iron oxide particles (MPIOs).  HuH7 tumor cells were incubated with increasing concentrations of biocompatible, silica-based, micron-sized iron oxide-containing particles (sMPIO; 40 – 160 particles/cell). Primary human hepatocytes were incubated with 100 sMPIOs/cell. The particle-labeled cells and the native cells were imaged using a clinical 3.0-T MRI system, whereas the control groups of the labeled and unlabeled cells were kept at room temperature without exposure to a magnetic field. Viability, formation of reactive oxygen species, aspartate aminotransferase leakage, and urea and albumin synthesis were assessed over a culture period of 5 days. 
The dose finding study showed no adverse effects of the sMPIO labeling on HuH7 cells. MRI had no adverse effects on the morphology of the sMPIO-labeled primary human hepatocytes. Imaging using the T1- and T2-weighted sequences did not affect the viability, transaminase leakage, formation of reactive oxygen species, or metabolic activity of the sMPIO-labeled cells or the unlabeled, primary human hepatocytes. sMPIOs did not induce adverse effects on the labeled cells under the conditions of the magnetic field of a clinical MRI system.