Dynamic Magnetic Fields Remote-Control Apoptosis<i>via</i>Nanoparticle Rotation

Zhang, Enming; Kircher, Moritz F.; Koch, Martin; Eliasson, Lena; Goldberg, S. Nahum; Renström, Erik

doi:10.1021/nn406302j

Cited by 191 publications

(218 citation statements)

References 45 publications

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“…Nanocarriers combine chemotherapy with physically destructive modalities that induce tumor ablation (photothermal/magnetic) [218][219][220][221][222][223][224][225][226][227][228][229][230][231][232][233][234][235][236]245,246], generate reactive oxygen species (photodynamic) [232][233][234][235][236][237][238][239][240][241][242], and form of free radicals (radiotherapy) to maximize cancer eradication [243]. [246] and demonstrated higher anticancer activity in vitro and in vivo than PTX/PLGA/HAuNPs microspheres alone (no NIR-irradiation) or PLGA/HAuNPs microspheres (no PTX) with NIR irradiation. DOXloaded, PEG-conjugated hollow gold nanoparticles (DOX/PEG/ HAuNPs) demonstrated NIR-triggered, pH-dependent DOX release led to greater antitumor activity and decreased systemic toxicity than free DOX or liposomal DOX [218,219].…”

Section: Combined Photothermal and Chemotherapymentioning

confidence: 99%

“…The pairing led to complete tumor eradication in vivo but the individual treatments only inhibited tumor growth, indicating the strong synergistic effect. In another approach, superparamagnetic iron oxide NPs (SPIONs) conjugated with lysosomal protein LAMP1-targeting antibodies induced apoptosis upon rotation activation by exposure to a magnetic field [246]. The NPs accumulated along the membrane in lysosomes due to the conjugated antibodies in rat insulinoma tumor cells and human pancreatic beta cells.…”

Section: Further Modes Of Physical Ablationmentioning

confidence: 99%

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“Combo” nanomedicine: Co-delivery of multi-modal therapeutics for efficient, targeted, and safe cancer therapy

Kemp

Shim

Heo

et al. 2016

Advanced Drug Delivery Reviews

423

258

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a b s t r a c t a r t i c l e i n f oThe dynamic and versatile nature of diseases such as cancer has been a pivotal challenge for developing efficient and safe therapies. Cancer treatments using a single therapeutic agent often result in limited clinical outcomes due to tumor heterogeneity and drug resistance. Combination therapies using multiple therapeutic modalities can synergistically elevate anti-cancer activity while lowering doses of each agent, hence, reducing side effects. Co-administration of multiple therapeutic agents requires a delivery platform that can normalize pharmacokinetics and pharmacodynamics of the agents, prolong circulation, selectively accumulate, specifically bind to the target, and enable controlled release in target site. Nanomaterials, such as polymeric nanoparticles, gold nanoparticles/cages/shells, and carbon nanomaterials, have the desired properties, and they can mediate therapeutic effects different from those generated by small molecule drugs (e.g., gene therapy, photothermal therapy, photodynamic therapy, and radiotherapy). This review aims to provide an overview of developing multi-modal therapies using nanomaterials ("combo" nanomedicine) along with the rationale, up-to-date progress, further considerations, and the crucial roles of interdisciplinary approaches.

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Section: Combined Photothermal and Chemotherapymentioning

confidence: 99%

Section: Further Modes Of Physical Ablationmentioning

confidence: 99%

“Combo” nanomedicine: Co-delivery of multi-modal therapeutics for efficient, targeted, and safe cancer therapy

Kemp

Shim

Heo

et al. 2016

Advanced Drug Delivery Reviews

423

258

View full text Add to dashboard Cite

show abstract

“…Zhang et al demonstrated that isotropous Fe 3 O 4 nanoparticles could be rotationally activated in a unique dynamic magnetic field (20 Hz) and after MNPs were internalized into cells and bound to lysosomes, the rotationally activated MNPs generated shear forces which resulted in rapid decrease in size and number of lysosomes, attributable to tearing of the lysosomal membrane [41]. With regard to the effect induced by rotating MNPs under the magnetic field, Yue et al theoretically investigated the interaction mechanism between lipid membranes and rotating MNPs through simulation and found that the rotating nanoparticles promoted cell uptake and also induced the mechanical membrane rupture [89].…”

Section: Under Constant or Low Frequency Magnetic Fieldmentioning

confidence: 99%

Mechanisms of Cellular Effects Directly Induced by Magnetic Nanoparticles under Magnetic Fields

Chen

Wang

et al. 2017

Journal of Nanomaterials

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The interaction of magnetic nanoparticles (MNPs) with various magnetic fields could directly induce cellular effects. Many scattered investigations have got involved in these cellular effects, analyzed their relative mechanisms, and extended their biomedical uses in magnetic hyperthermia and cell regulation. This review reports these cellular effects and their important applications in biomedical area. More importantly, we highlight the underlying mechanisms behind these direct cellular effects in the review from the thermal energy and mechanical force. Recently, some physical analyses showed that the mechanisms of heat and mechanical force in cellular effects are controversial. Although the physical principle plays an important role in these cellular effects, some chemical reactions such as free radical reaction also existed in the interaction of MNPs with magnetic fields, which provides the possible explanation for the current controversy. It is anticipated that the review here could provide readers with a deeper understanding of mechanisms of how MNPs contribute to the direct cellular effects and thus their biomedical applications under various magnetic fields.

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“…On the other hand, magnetic nanoparticles, especially of iron oxides, are being used in biomedicine for treatment as hyperthermia or drug delivery [6][7][8][9]. Recently, the possibility of using nickel nanowires in biomedicine has been also proposed [10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Electrochemical preparation and characterization of magnetic core–shell nanowires for biomedical applications

Gispert¹,

Serrà²,

Alea³

et al. 2016

Electrochemistry Communications

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Magnetic CoNi@Au core-shell nanorods have been electrochemically synthesized, characterized and functionalized to test their inherent cytotoxicity in order to assess their potential use for biomedical applications. The initially electrodeposited CoNi nanorods have been covered with a gold layer by means of galvanic displacement to minimize the nanowires toxicity and their aggregation, and favour the functionalization. The presence of a gold layer on the nanorod surface slightly modifies the magnetic behaviour of the as-deposited nanorods, maintaining their soft-magnetic behaviour and high magnetization of saturation. The complete covering of the nanorods with the gold shell favours a good functionalization with a layer of (11-Mercaptoundecyl)hexa(ethylene glycol) molecules, in order to create a hydrophilic coating to avoid the aggregation of nanorods, keeping them in suspension and give them stability in biological media. The presence of the organic layer incorporated was detected by means of electrochemical probe experiments. A cytotoxicity test of functionalized core-shell nanorods, carried out with adherent HeLa cells, showed that cell viability was higher than 80% for amounts of nanorods up to 10 μg mL −1 . These results make functionalized nanorods promising vehicles for targeted drug delivery in medicine, which gives a complementary property to the magnetic nanoparticles.

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Dynamic Magnetic Fields Remote-Control ApoptosisviaNanoparticle Rotation

Cited by 191 publications

References 45 publications

“Combo” nanomedicine: Co-delivery of multi-modal therapeutics for efficient, targeted, and safe cancer therapy

“Combo” nanomedicine: Co-delivery of multi-modal therapeutics for efficient, targeted, and safe cancer therapy

Mechanisms of Cellular Effects Directly Induced by Magnetic Nanoparticles under Magnetic Fields

Electrochemical preparation and characterization of magnetic core–shell nanowires for biomedical applications

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