Fernando Herraiz García scite author profile

Magnetic nanomaterials in magnetic fields can serve as versatile transducers for remote interrogation of cell functions. In this study, we leveraged the transition from vortex to in-plane magnetization in iron oxide nanodiscs to modulate the activity of mechanosensory cells. When a vortex configuration of spins is present in magnetic nanomaterials, it enables rapid control over their magnetization direction and magnitude. The vortex configuration manifests in near zero net magnetic moment in the absence of a magnetic field, affording greater colloidal stability of magnetic nanomaterials in suspensions. Together, these properties invite the application of magnetic vortex particles as transducers of externally applied minimally invasive magnetic stimuli in biological systems. Using magnetic modeling and electron holography, we predict and experimentally demonstrate magnetic vortex states in an array of colloidally synthesized magnetite nanodiscs 98–226 nm in diameter. The magnetic nanodiscs applied as transducers of torque for remote control of mechanosensory neurons demonstrated the ability to trigger Ca2+ influx in weak (≤28 mT), slowly varying (≤5 Hz) magnetic fields. The extent of cellular response was determined by the magnetic nanodisc volume and magnetic field conditions. Magnetomechanical activation of a mechanosensitive cation channel TRPV4 (transient receptor potential vanilloid family member 4) exogenously expressed in the nonmechanosensitive HEK293 cells corroborated that the stimulation is mediated by mechanosensitive ion channels. With their large magnetic torques and colloidal stability, magnetic vortex particles may facilitate basic studies of mechanoreception and its applications to control electroactive cells with remote magnetic stimuli.

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Localized Excitation of Neural Activity via Rapid Magnetothermal Drug Release

Romero

Christiansen

Barbosa

et al. 2016

Adv Funct Materials

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Hysteretic heat dissipation by magnetic nanoparticles (MNPs) in alternating magnetic fields (AMFs) allows these materials to act as local transducers of external stimuli. Commonly employed in cancer research, MNPs have recently found applications in remote control of heat‐dependent cellular pathways. Here, a thermally labile linker chemistry is adapted for the release of neuromodulatory compounds from the surfaces of MNPs via local nanoscale heating. By examining a range of MNP sizes, and considering individual particle loss powers, AMF conditions and nanomaterials suitable for rapid and complete release of a payload from MNP surfaces are selected. Local release of allyl isothiocyanate, an agonist of the Ca2+ channel TRPV1 (transient receptor potential vanilloid cation channel subfamily member 1), from iron oxide MNPs results in pharmacological excitation of neurons with latencies of ≈12 s. When targeted to neuronal membranes, these MNPs trigger Ca2+ influx and action potential firing at particle concentrations three orders of magnitude less than those previously used for magnetothermal neuromodulation accomplished with bulk heating.

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The Synthesis of Thienopyrroles

García¹,

Gálvez²

1985

Synthesis

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