Improvement of 19F MR image uniformity in a mouse model of cellular therapy using inductive coupling.

OBJECTIVE: Improve 19F magnetic resonance imaging uniformity of perfluorocarbon (PFC)-labeled cells by using a secondary inductive resonator tuned to 287 MHz to enhance the induced radio frequency (RF) magnetic field (B1) at 7.05 T. MATERIALS AND METHODS: Following Faraday's induction law, the sign of induced B1 made by the secondary resonator can be changed depending on the tuning of the resonator. A secondary resonator located on the opposite side of the phantom of the 19F surface coil can be shown to enhance or subtract the induced B1 field, depending upon its tuning. RESULTS: The numerical simulation results of rotating transmit B1 magnitude (|B 1 + |) and corresponding experimental 19F images were compared without and with the secondary resonator. With the secondary resonator tuned to 287 MHz, improvements of |B 1 + | and 19F image uniformity were demonstrated. The use of the secondary resonator improved our ability to visualize transplanted cell location non-invasively over a period of 6 weeks. CONCLUSION: The secondary resonator tuned to enhance the induced B1 results in improved image uniformity in a pre-clinical application, enabling cell tracking of PFC-labeled cells with the secondary resonator.

Evaluation of the differentiation status of neural stem cells based on cell morphology and the expression of Notch and Sox2.

Neural stem cells (NSCs) isolated from a variety of sources are being developed as cellular therapies aimed at treating neurodegenerative diseases. During NSC culture and expansion it is important the cells do not differentiate prematurely because this may have an unfavorable effect on product quality and yield. In our study, we evaluated the use of Notch and Sox2 as markers for undifferentiated human and mouse NSCs. The expression of Notch2 and Sox2 during extensive-passage, low-oxygen culture and differentiation conditions were analyzed to confirm that the presence of these signature proteins directly correlates with the ability of NSCs to form new neurospheres and differentiate into multiple cell types. Using expression of Notch1, Notch2 and Sox2 as a reference, we then used flow cytometry to identify a specific morphological profile for undifferentiated murine and human NSCs. Our studies show that Notch and Sox2 expression, along with flow cytometry analysis, can be used to monitor the differentiation status of NSCs grown in culture for use in cellular therapies.