AI Article Synopsis
- Magnetic nanoparticles used in magnetic hyperthermia therapy have been mainly limited to iron oxides like magnetite and maghemite due to biocompatibility issues.
- ε-FeO, a lesser-known iron oxide, has unique properties such as giant coercivity, but its performance is found to be slightly inferior to that of γ-FeO, particularly in human applications.
- However, ε-FeO nanoparticles exhibit a preference for heating in lower frequency ranges and could enable switchable magnetic heating, offering potential avenues for future research in this field.
Article Abstract
Biocompatibility restrictions have limited the use of magnetic nanoparticles for magnetic hyperthermia therapy to iron oxides, namely magnetite (FeO) and maghemite (γ-FeO). However, there is yet another magnetic iron oxide phase that has not been considered so far, in spite of its unique magnetic properties: ε-FeO. Indeed, whereas FeO and γ-FeO have a relatively low magnetic coercivity, ε-FeO exhibits a giant coercivity. In this report, the heating power of ε-FeO nanoparticles in comparison with γ-FeO nanoparticles of similar size (∼20 nm) was measured in a wide range of field frequencies and amplitudes, in uncoated and polymer-coated samples. It was found that ε-FeO nanoparticles primarily heat in the low-frequency regime (20-100 kHz) in media whose viscosity is similar to that of cell cytoplasm. In contrast, γ-FeO nanoparticles heat more effectively in the high frequency range (400-900 kHz). Cell culture experiments exhibited no toxicity in a wide range of nanoparticle concentrations and a high internalization rate. In conclusion, the performance of ε-FeO nanoparticles is slightly inferior to that of γ-FeO nanoparticles in human magnetic hyperthermia applications. However, these ε-FeO nanoparticles open the way for switchable magnetic heating owing to their distinct response to frequency.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9055867 | PMC |
| http://dx.doi.org/10.1039/d0ra04361c | DOI Listing |
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