Anisotropic magnetic nanoparticles for biomedicine: bridging frequency separated AC-field controlled domains of actuation
David Serantes, Roy Chantrell, Helena Gavil\'an, Mar\'ia del Puerto, Morales, Oksana Chubykalo-Fesenko, Daniel Baldomir, and Akira Satoh

TL;DR
This study uses simulations to analyze how anisotropic magnetic nanoparticles can be controlled by AC fields for either mechanical actuation or heat release, advancing their application in biomedicine.
Contribution
The paper demonstrates that hexagonal nanodisks can switch between actuation and heating modes by adjusting AC field parameters, supported by Brownian and micromagnetic simulations.
Findings
Negligible hysteresis losses at high and low frequencies.
Efficient magneto-mechanical actuation with minimal heating.
Potential for dual-function nanomedicine agents.
Abstract
Magnetic nanoparticles constitute potential nanomedicine tools based on the possibility to obtain different responses triggered by safe remote stimulus. However, such richness can be detrimental if the different performances are not accurately differentiated (and controlled). An example of this is the reorientation of magnetic nanoparticles under the influence of AC fields, which can be exploited for either magneto-mechanical actuation (MMA) at low frequencies (tens of Hz); or heat release at large ones (MHz range). While it is clear that Brownian rotation is responsible for MMA, its heating role in the high-frequency regime is not clear. In this work we aim to shed light on this issue, which needs to be well understood for applications in magnetic fluid hyperthermia (MFH) or heat triggered drug release. Using a Brownian dynamics (BD) simulation technique, we have theoretically…
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