Using Gradient Magnetic Fields to Control the Size and Uniformity of Iron Oxide Nanoparticles for Magnetic Resonance Imaging
journal contributionposted on 18.04.2022, 21:05 authored by Kun Ma, Ze Wang, Tongxiang Tao, Shuai Xu, Sajid ur Rehman, Xu Yan, Jun Fang, Ruiguo Chen, Hui Wang, Xin Zhang, Can Xie, Yang Lu, Qingyou Lu, Junfeng Wang
The size and uniformity of magnetic nanoparticles are essential for biomedical performance. In this study, we successfully controlled the size and uniformity of magnetic nanomaterials by applying gradient magnetic fields during the solvothermal method. This regulation method conforms to the following laws: the size of the synthesized magnetic nanoparticles (MNPs) is smaller when the applied magnetic field is stronger, and the synthesized uniformity is better when the product of the applied field and its gradient is greater. In vitro and in vivo magnetic resonance imaging experiments show that magnetic field treatment resulted in uniform MNPs of 4.5 nm, which can significantly improve the T1 contrast performance. We further propose a dynamic process of field-induced reconfiguration for reverse micelles (re-micelles) to analyze how the gradient magnetic field affects MNP synthesis.
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iron oxide nanoparticlesmagnetic resonance imagingregulation method conformssynthesized magnetic nanoparticles1 </ subapplied magnetic fieldmagnetic nanoparticlesmagnetic nanomaterialssolvothermal methodapplied field>< subvivo </vitro </synthesized uniformitysuccessfully controlledsignificantly improveinduced reconfigurationfollowing lawsdynamic processcontrast performancebiomedical performance5 nm