Magnetic-Responsive Release Controlled by Hot Spot Effect

Guisasola, Eduardo; Baeza, Alejandro; Talelli, Marina; Arcos, Daniel; Moros, María; Fuente, Jesús M. de la; Vallet‐Regí, María

doi:10.1021/acs.langmuir.5b03470

Cited by 97 publications

(83 citation statements)

References 32 publications

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“…This "hot spot" or "local magnetic hyperthermia" effect has already been observed for other DDS based on polymers (e.g. MNPs coated with polymers13,18 ; MIP-…”

supporting

confidence: 62%

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Doxorubicin Intracellular Remote Release from Biocompatible Oligo(ethylene glycol) Methyl Ether Methacrylate-Based Magnetic Nanogels Triggered by Magnetic Hyperthermia

Cazares-Cortes

Espinosa

Guigner

et al. 2017

ACS Appl. Mater. Interfaces

111

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Hybrid nanogels, composed of thermoresponsive polymers and superparamagnetic nanoparticles, are attractive nanocarriers for biomedical applications, being able-as a polymer matrix-to uptake and release high quantities of chemotherapeutic agents and-as magnetic nanoparticles-to be heated when exposed to an alternative magnetic field (AMF), better known as magnetic hyperthermia. Herein, biocompatible, pH-responsive, magnetoresponsive, and thermoresponsive nanogels, based on oligo(ethylene glycol) methyl ether methacrylate monomers and a methacrylic acid comonomer were prepared by conventional precipitation radical copolymerization in water, post-assembled by complexation with iron oxide magnetic nanoparticles (MNPs) of maghemite (γ-FeO), and loaded with an anticancer drug (doxorubicin, DOX), for remotely controlled drug release by a "hot spot", as an athermal magnetic hyperthermia strategy against cancer. These nanogels, denoted MagNanoGels, with a hydrodynamic diameter from 328 to 460 nm, as a function of the MNP content, have a swelling-deswelling behavior at their volume phase temperature transition around 47 °C in a physiological medium (pH 7.5), which is above the human body temperature (37 °C). Applying an alternative magnetic field increases the release of DOX by 2-fold, while no macroscopic heating was recorded. This enhanced drug release is due to a shrinking of the polymer network by local heating, as illustrated by the MagNanoGel size decrease under an AMF. In cancer cells, not only do the DOX-MagNanoGels internalize DOX more efficiently than free DOX, but also DOX intracellular release can be remotely triggered under an AMF, in athermal conditions, thus enhancing DOX cytotoxicity.

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“…This "hot spot" or "local magnetic hyperthermia" effect has already been observed for other DDS based on polymers (e.g. MNPs coated with polymers13,18 ; MIP-…”

supporting

confidence: 62%

“…Recently, some research groups have demonstrated that polymeric-MNPs nanocarriers (Magnetic Molecularly Imprinted Polymer Nanoparticles 16 , polymer coated MNPs [17][18][19] ) can release their payload without macroscopic heating (athermal conditions). In this case, MNPs act as individual "hot spots" and generate a localized heating, i.e.…”

Section: Introductionmentioning

confidence: 99%

Doxorubicin Intracellular Remote Release from Biocompatible Oligo(ethylene glycol) Methyl Ether Methacrylate-Based Magnetic Nanogels Triggered by Magnetic Hyperthermia

Cazares-Cortes

Espinosa

Guigner

et al. 2017

ACS Appl. Mater. Interfaces

111

View full text Add to dashboard Cite

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“…For example, in one study by Rühle et al, it was reported that the temperature 20 nm from the SPION surface could be as high as 65 C, under conditions where there is no increase in the global temperature of the sample (Rühle, Datz, Argyo, Bein, & Zink, 2016). Others have reported similar findings, with temperatures reaching >43 C and triggering drug release at distance~20 nm from the SPION surface (Guisasola et al, 2015). However, some studies have reported more modest findings, with temperatures reaching only 45 C within 0.5 nm of the SPION surface and dropping off exponentially with distance (Riedinger et al, 2013).…”

Section: Magnetically Induced Drug Releasementioning

confidence: 86%

Use of magnetic fields and nanoparticles to trigger drug release and improve tumor targeting

Liu

Jang

Issadore

et al. 2019

WIREs Nanomed Nanobiotechnol

129

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Drug delivery strategies aim to maximize a drug's therapeutic index by increasing the concentration of drug at target sites while minimizing delivery to off‐target tissues. Because biological tissues are minimally responsive to magnetic fields, there has been a great deal of interest in using magnetic nanoparticles in combination with applied magnetic fields to selectively control the accumulation and release of drug in target tissues while minimizing the impact on surrounding tissue. In particular, spatially variant magnetic fields have been used to encourage accumulation of drug‐loaded magnetic nanoparticles at target sites, while time‐variant magnetic fields have been used to induce drug release from thermally sensitive nanocarriers. In this review, we discuss nanoparticle formulations and approaches that have been developed for magnetic targeting and/or magnetically induced drug release, as well as ongoing challenges in using magnetism for therapeutic applications. This article is categorized under: Diagnostic Tools > in vivo Nanodiagnostics and Imaging Therapeutic Approaches and Drug Discovery > Emerging Technologies Therapeutic Approaches and Drug Discovery > Nanomedicine for Oncologic Disease

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“…The resulting particles exhibit a discoid or lens shape depending on the chemical properties of the grafted layer. The interfacial behavior of polymer ligands can be tuned in situ by altering solvent properties, such as temperature and pH . Soft particles composed of polymer gels have also been observed to deform upon adsorption, where the extent of particle deformation at the interface is governed by a competition between particle elasticity and surface tension .…”

Section: Assembly Dynamics and In Situ Characterization Of Nanomatementioning

confidence: 99%

Building Reconfigurable Devices Using Complex Liquid–Fluid Interfaces

et al. 2019

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imparts novel mechanical and functional properties to the macroscopic interface itself. These properties include size-and charge-selective pathways for molecules and particulates, shear and compressive moduli, and selective binding and reaction sites. Complex interfaces can then be used to generate complex, macroscopic, all-liquid materials with very high surface areas that have unique properties, such as compartmentalization, communication between compartments, and the ability to move and reconfigure. With the rapid growth in the study of complex materials made from interfacially structured liquids, there is a need to review the field from the funda-Liquid-fluid interfaces provide a platform both for structuring liquids into complex shapes and assembling dimensionally confined, functional nanomaterials. Historically, attention in this area has focused on simple emulsions and foams, in which surface-active materials such as surfactants or colloids stabilize structures against coalescence and alter the mechanical properties of the interface. In recent decades, however, a growing body of work has begun to demonstrate the full potential of the assembly of nanomaterials at liquid-fluid interfaces to generate functionally advanced, biomimetic systems. Here, a broad overview is given, from fundamentals to applications, of the use of liquid-fluid interfaces to generate complex, all-liquid devices with a myriad of potential applications. Figure 2.Interactions between particles attached to liquid-fluid interfaces. a) Dipole-dipole interactions between adsorbed particles due to asymmetric charge distributions near the surface of particles at interfaces. Reproduced with permission. [34] Copyright 1980, American Physical Society. b) Dipole-dipole interactions give rise to 2D colloidal crystals with large lattice spacings. Scale bar, 50 µm. Reproduced with permission. [36]

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Magnetic-Responsive Release Controlled by Hot Spot Effect

Cited by 97 publications

References 32 publications

Doxorubicin Intracellular Remote Release from Biocompatible Oligo(ethylene glycol) Methyl Ether Methacrylate-Based Magnetic Nanogels Triggered by Magnetic Hyperthermia

Doxorubicin Intracellular Remote Release from Biocompatible Oligo(ethylene glycol) Methyl Ether Methacrylate-Based Magnetic Nanogels Triggered by Magnetic Hyperthermia

Use of magnetic fields and nanoparticles to trigger drug release and improve tumor targeting

Building Reconfigurable Devices Using Complex Liquid–Fluid Interfaces

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