Your search keyword '"Chikan, Viktor"' showing total 4 results

1. Cell-delivered magnetic nanoparticles caused hyperthermia-mediated increased survival in a murine pancreatic cancer model.

Author

Basel MT, Balivada S, Wang H, Shrestha TB, Seo GM, Pyle M, Abayaweera G, Dani R, Koper OB, Tamura M, Chikan V, Bossmann SH, and Troyer DL

Subjects

Animals, Disease Models, Animal, Magnetics, Mice, Survival Rate, Ferric Compounds administration & dosage, Hyperthermia, Induced methods, Macrophages transplantation, Magnetic Fields, Nanoparticles therapeutic use, Pancreatic Neoplasms therapy, Transplants

Abstract

Using magnetic nanoparticles to absorb alternating magnetic field energy as a method of generating localized hyperthermia has been shown to be a potential cancer treatment. This report demonstrates a system that uses tumor homing cells to actively carry iron/iron oxide nanoparticles into tumor tissue for alternating magnetic field treatment. Paramagnetic iron/ iron oxide nanoparticles were synthesized and loaded into RAW264.7 cells (mouse monocyte/ macrophage-like cells), which have been shown to be tumor homing cells. A murine model of disseminated peritoneal pancreatic cancer was then generated by intraperitoneal injection of Pan02 cells. After tumor development, monocyte/macrophage-like cells loaded with iron/ iron oxide nanoparticles were injected intraperitoneally and allowed to migrate into the tumor. Three days after injection, mice were exposed to an alternating magnetic field for 20 minutes to cause the cell-delivered nanoparticles to generate heat. This treatment regimen was repeated three times. A survival study demonstrated that this system can significantly increase survival in a murine pancreatic cancer model, with an average post-tumor insertion life expectancy increase of 31%. This system has the potential to become a useful method for specifically and actively delivering nanoparticles for local hyperthermia treatment of cancer.

Published

2012

2. Pulse Magnetic Fields Induced Drug Release from Gold Coated Magnetic Nanoparticle Decorated Liposomes.

Author

Acharya, Basanta and Chikan, Viktor

Subjects

MAGNETIC fields, MAGNETIC nanoparticles, LIPOSOMES, DIPALMITOYL lecithin, IRON oxide nanoparticles

Abstract

Magnetic nanoparticle-assisted drug release from liposomes is an important way to enhance the functionality/usefulness of liposomes. This work demonstrates an approach how to integrate magnetic nanoparticles with liposomes with the assistance of gold-thiol chemistry. The gold coated magnetic particles cover the thiolated liposomes from the outside, which removes the competition of the drug molecules and the triggering magnetic particles to free the inner space of the liposomes when compared to previous magneto liposome formulations. The liposome consists of dipalmitoyl phosphatidylcholine (DPPC) combined with distearoylphosphatidylcholine (DSPC) in addition to regular cholesterol or cholesterol-PEG-SH. Permeability assays and electron microscopy images show efficient coupling between the liposomes and nanoparticles in the presence of thiol groups without compromising the functionality of the liposomes. The nanoparticles such as gold nanoparticles, gold coated iron oxide nanoparticles and bare iron oxide nanoparticles are added following the model drug encapsulation. The efficient coupling between the gold coated nanoparticles (NPs) and the thiolate liposomes is evidenced by the shift in transition temperature of the thiolated liposomes. The addition of magnetically triggerable nanoparticles externally makes the entire interior of liposomes available for drug loading. The drug release efficiencies of these liposomes/NPs complexes were compared under exposure to pulsed magnetic fields. The results indicate up to 20% of the drug can be released in short time, which is comparable in efficiency to previous studies performed when magnetic NPs were located inside liposomes. Interestingly, the liposomes were found to exhibit variations in release efficiency based on different dilution media which is attributed to an osmotic pressure effect on liposomal stability. [ABSTRACT FROM AUTHOR]

Published

2020

3. Nested Helmholtz coil design for producing homogeneous transient rotating magnetic fields.

Author

Podaru, George, Moore, John, Dani, Raj Kumar, Prakash, Punit, and Chikan, Viktor

Subjects

ELECTROMAGNETS, MAGNETIC fields, MAGNETIC nanoparticles, CAPACITORS, ELECTRIC spark gaps

Abstract

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. [ABSTRACT FROM AUTHOR]

Published

2015

4. PulsedMagnetic Field Induced Fast Drug Release fromMagneto Liposomes via Ultrasound Generation.

Author

Podaru, George, Ogden, Saralyn, Baxter, Amanda, Shrestha, Tej, Ren, Shenqiang, Thapa, Prem, Dani, Raj Kumar, Wang, Hongwang, Basel, Matthew T., Prakash, Punit, Bossmann, Stefan H., and Chikan, Viktor

Subjects

*LIPOSOMES, *MAGNETIC fields, *MAGNETO, *ULTRASONICS, *DRUG delivery systems, *PHARMACOKINETICS

Abstract

Fastdrug delivery is very important to utilize drug moleculesthat are short-lived under physiological conditions. Techniques thatcan release model molecules under physiological conditions could playan important role to discover the pharmacokinetics of short-livedsubstances in the body. Here an experimental method is developed forthe fast release of the liposomes’ payload without a significantincrease in (local) temperatures. This goal is achieved by using shortmagnetic pulses to disrupt the lipid bilayer of liposomes loaded withmagnetic nanoparticles. The drug release has been tested by two independentassays. The first assay relies on the AC impedance measurements ofMgSO4released from the magnetic liposomes. The secondstandard release assay is based on the increase of the fluorescencesignal from 5(6)-carboxyfluorescein dye when the dye is released fromthe magneto liposomes. The efficiency of drug release ranges froma few percent to up to 40% in the case of the MgSO4. Theexperiments also indicate that the magnetic nanoparticles generateultrasound, which is assumed to have a role in the release of themodel drugs from the magneto liposomes. [ABSTRACT FROM AUTHOR]

Published

2014