George Podaru scite author profile

George Podaru

4Publications

70Citation Statements Received

89Citation Statements Given

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Kansas State University

Publications

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Pulsed Magnetic Field Induced Fast Drug Release from Magneto Liposomes via Ultrasound Generation

Podaru¹,

Ogden²,

Baxter³

et al. 2014

J. Phys. Chem. B

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Fast drug delivery is very important to utilize drug molecules that are short-lived under physiological conditions. Techniques that can release model molecules under physiological conditions could play an important role to discover the pharmacokinetics of short-lived substances in the body. Here an experimental method is developed for the fast release of the liposomes' payload without a significant increase in (local) temperatures. This goal is achieved by using short magnetic pulses to disrupt the lipid bilayer of liposomes loaded with magnetic nanoparticles. The drug release has been tested by two independent assays. The first assay relies on the AC impedance measurements of MgSO4 released from the magnetic liposomes. The second standard release assay is based on the increase of the fluorescence signal from 5(6)-carboxyfluorescein dye when the dye is released from the magneto liposomes. The efficiency of drug release ranges from a few percent to up to 40% in the case of the MgSO4. The experiments also indicate that the magnetic nanoparticles generate ultrasound, which is assumed to have a role in the release of the model drugs from the magneto liposomes.

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Magnetic Field Induced Ultrasound from Colloidal Superparamagnetic Nanoparticles

2016

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Generating ultrasound remotely by means of magnetic fields is an important technological development to circumvent the drawbacks of the traditional means of ultrasound generation techniques. In this report, it is demonstrated that ultrasound is generated from colloidal superparamagnetic nanoparticles when exposed to pulsed and alternating magnetic fields. Comparison of the inhomogeneous and homogeneous magnetic fields indicates that both homogeneous and inhomogeneous magnetic fields could be important for efficient ultrasound generation; however, the latter is more important for dilute colloidal dispersion of magnetic nanoparticles. In strong magnetic fields, the ultrasound generated from the colloidal magnetic nanoparticles shows reasonable agreement with the magnetostriction effect commonly observed for bulk ferromagnetic materials. At low magnetic fields, the colloidal magnetic nanoparticle dispersion produces considerable amount of ultrasound when exposed to ac magnetic fields in the 20–5000 kHz frequency range. From these experiments, the measured force/magnetic particle is found to be in the range 1 × 10–18–1 × 10–21 N for magnetic field gradients from a few hundred T/m to a few hundred mT/m, respectively. It is expected that the ultrasound generated from magnetic nanoparticles will have applications toward the acoustic induction of bioeffects in cells and manipulating the permeability of biological membranes.

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CHAPTER 1. Magnetism in Nanomaterials: Heat and Force from Colloidal Magnetic Particles

Podaru¹,

Chikán²

2017

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Nested Helmholtz coil design for producing homogeneous transient rotating magnetic fields

Podaru

Moore

Dani

et al. 2015

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Electromagnets that can produce strong rotating magnetic fields at kHz frequencies are potentially very useful to exert rotating force on magnetic nanoparticles as small as few nanometers in size. In this article, the construction of a pulsed high-voltage rotating electromagnet is demonstrated based on a nested Helmholtz coil design. The energy for the coils is provided by two high-voltage discharge capacitors. The triggered spark gaps used in the experiments show sufficient accuracy to achieve the high frequency rotating magnetic field. The measured strength of the rotating magnetic field is 200 mT. This magnetic field is scalable by increasing the number of turns on the coils, by reducing the dimensions of the coils and by increasing the discharge current/voltage of the capacitors.

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George Podaru

Pulsed Magnetic Field Induced Fast Drug Release from Magneto Liposomes via Ultrasound Generation

Magnetic Field Induced Ultrasound from Colloidal Superparamagnetic Nanoparticles

CHAPTER 1. Magnetism in Nanomaterials: Heat and Force from Colloidal Magnetic Particles

Nested Helmholtz coil design for producing homogeneous transient rotating magnetic fields

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