Abstract
Growth factors play an important role in nerve regeneration and repair. An attractive drug delivery strategy, termed “magnetic targeting”, aims to enhance therapeutic efficiency by directing magnetic drug carriers specifically to selected cell populations that are suitable for the nervous tissues. Here, we covalently conjugated nerve growth factor to iron oxide nanoparticles (NGF-MNPs) and used controlled magnetic fields to deliver the NGF–MNP complexes to target sites. In order to actuate the magnetic fields a modular magnetic device was designed and fabricated. PC12 cells that were plated homogenously in culture were differentiated selectively only in targeted sites out of the entire dish, restricted to areas above the magnetic “hot spots”. To examine the ability to guide the NGF-MNPs towards specific targets in vivo, we examined two model systems. First, we injected and directed magnetic carriers within the sciatic nerve. Second, we injected the MNPs intravenously and showed a significant accumulation of MNPs in mouse retina while using an external magnet that was placed next to one of the eyes. We propose a novel approach to deliver drugs selectively to injured sites, thus, to promote an effective repair with minimal systemic side effects, overcoming current challenges in regenerative therapeutics.
Original language | English |
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Article number | 707 |
Journal | Nanomaterials |
Volume | 8 |
Issue number | 9 |
DOIs | |
State | Published - 10 Sep 2018 |
Bibliographical note
Publisher Copyright:© 2018 by the authors. Licensee MDPI, Basel, Switzerland.
Funding
Acknowledgments: The authors thank Ronen Yehuda for his invaluable help with the in vivo Maestro imaging and Avi Jacob for his help with the time-lapse imaging. The authors thank Cecile Yehezkel for her help with the 3D printing of the device. The authors thank Moshe Karni for his help with the magnetic simulations. The authors thank Noa Alon for her assistance with the graphic illustration. M.M. gratefully acknowledges the Israeli Ministry of Science, Technology and Space for the Scholarship for Women in Science. The authors thank Ronen Yehuda for his invaluable help with the in vivo Maestro imaging and Avi Jacob for his help with the time-lapse imaging. The authors thank Cecile Yehezkel for her help with the 3D printing of the device. The authors thank Moshe Karni for his help with the magnetic simulations. The authors thank Noa Alon for her assistance with the graphic illustration. M.M. gratefully acknowledges the Israeli Ministry of Science, Technology and Space for the Scholarship for Women in Science.
Funders | Funder number |
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Ministry of Science, Technology and Space | |
Ministry of science and technology, Israel |
Keywords
- Magnetic nanoparticles
- Magnetic targeting
- Nerve growth factor
- Neuronal regeneration
- Sciatic nerve injury