An in silico model of the capturing of magnetic nanoparticles in tumour spheroids in the presence of flow

Wirthl, Barbara; Janko, Christina; Lyer, Stefan; Schrefler, Bernhard A.; Alexiou, Christoph; Wall, Wolfgang A.

doi:10.1007/s10544-023-00685-9

Biomed Microdevices

2023

DOI: 10.1007/s10544-023-00685-9

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An in silico model of the capturing of magnetic nanoparticles in tumour spheroids in the presence of flow

Barbara Wirthl,

Christina Janko,

Stefan Lyer

et al.

Abstract: One of the main challenges in improving the efficacy of conventional chemotherapeutic drugs is that they do not reach the cancer cells at sufficiently high doses while at the same time affecting healthy tissue and causing significant side effects and suffering in cancer patients. To overcome this deficiency, magnetic nanoparticles as transporter systems have emerged as a promising approach to achieve more specific tumour targeting. Drug-loaded magnetic nanoparticles can be directed to the target tissue by appl… Show more

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2024

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Cited by 3 publications

References 87 publications

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Magnetic nanoparticle detection methods in the context of complex fluids

Orujov,

Pikal,

Chien

et al. 2024

Int J Coal Sci Technol

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Foams improve mobility control in injection operations within geological settings. Nanoparticles, such as iron-oxide, have been shown to enhance the stability of foams when combined with surfactants. In this research, we leverage the magnetic properties of these nanoparticles to detect their presence as a surrogate for monitoring the geologic extent of injected fluids in the subsurface. The feasibility of using these nanoparticles for monitoring purposes stems from their detectability at low concentrations in subsurface environments. We developed two distinct methods to detect the presence of magnetite nanoparticles in complex fluids. To simulate complex subsurface fluids in a laboratory setting, we included various ions and surfactants and investigated their effects on the detection of nanoparticles. To this end, we designed an experimental setup and tested two magnetic detection methods: Induction Heating (IH) and Oscillator Frequency Shift (OFS). The IH method involves applying a high-frequency alternating magnetic field to a solution containing small amounts of magnetic nanoparticles and measuring the temperature response. We built an experimental setup to generate this magnetic field for different samples, with temperature changes recorded by an infrared camera. The results indicate that nanoparticle concentrations linearly affect the solution's temperature rise. However, the presence of ions and surfactants also influences the temperature response. The OFS method measures shifts in the resonance frequency of a circuit caused by changes in magnetic permeability inside a coil. This coil is part of a transistor oscillator circuit that produces a sinusoidal voltage waveform, with the oscillation frequency depending on the coil’s inductance. The presence of nanoparticles causes a shift in resonance frequency, which were precisely measured for various samples. The drop in resonance frequency is a linear function of nanoparticle concentration, and both methods detect concentrations as low as 150 mg/L of Fe3O4 nanoparticles.

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Magnetic nanoparticle detection methods in the context of complex fluids

Orujov,

Pikal,

Chien

et al. 2024

Int J Coal Sci Technol

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Efficient computational model of the in-flow capturing of magnetic nanoparticles by a cylindrical magnet for cancer nanomedicine

Wirthl,

Wall

2024

Phys. Rev. E

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Enhancing Drug Solubility, Bioavailability, and Targeted Therapeutic Applications through Magnetic Nanoparticles

Zhuo,

Zhao,

Zhang

2024

Molecules

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Biological variability poses significant challenges in the development of effective therapeutics, particularly when it comes to drug solubility and bioavailability. Poor solubility across varying physiological conditions often leads to reduced absorption and inconsistent therapeutic outcomes. This review examines how nanotechnology, especially through the use of nanomaterials and magnetic nanoparticles, offers innovative solutions to enhance drug solubility and bioavailability. This comprehensive review focuses on recent advancements and approaches in nanotechnology. We highlight both the successes and remaining challenges in this field, emphasizing the role of continued innovation. Future research should prioritize developing universal therapeutic solutions, conducting interdisciplinary research, and leveraging personalized nanomedicine to address biological variability.

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An in silico model of the capturing of magnetic nanoparticles in tumour spheroids in the presence of flow

Cited by 3 publications

References 87 publications

Magnetic nanoparticle detection methods in the context of complex fluids

Magnetic nanoparticle detection methods in the context of complex fluids

Efficient computational model of the in-flow capturing of magnetic nanoparticles by a cylindrical magnet for cancer nanomedicine

Enhancing Drug Solubility, Bioavailability, and Targeted Therapeutic Applications through Magnetic Nanoparticles

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