Simulation of the Motion of Magnetic Nanoparticles in Human Tissues

Peter Andriushenko; Leonid L. Afremov; Maria Chernova

doi:10.4028/www.scientific.net/SSP.215.284

Paper Titles

Influence of Heating Temperature on the ΔЕ-Effect of Amorphous Fe₇₅Si₁₀B₁₅ Wires
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Definition of Amorphous Tapes Magnetic Condition Using Temperature Dependence of the Saturation Magnetic Moment
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Magnetic and Magnetoresonance Properties of Multilayered Systems Based on (CoFeB)_x-(SiO₂)_100-x Composite Layers
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Effect of Substrate RF-Bias on Exchange Coupling in Fe₂₀Ni₈₀/Fe₅₀Mn₅₀ Films
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Simulation of the Motion of Magnetic Nanoparticles in Human Tissues
p.284

Magnetic Properties of Co Thin Films Evaporated under Normal and Oblique Incidence
p.288

Temperature Dependence of Magnetic Saturation in Electrodeposited Nanocrystalline Nickel Films
p.292

Magnetic Behavior of Single Ni Nanowires and its Arrays Embedded in Highly Ordered Nanoporous Alumina Templates
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Spin Injection Mechanisms for Radiation and Detection of Terahertz Waves Based on Magnetic Nano Junction
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HomeSolid State PhenomenaSolid State Phenomena Vol. 215Simulation of the Motion of Magnetic Nanoparticles...

Simulation of the Motion of Magnetic Nanoparticles in Human Tissues

Abstract:

In this paper an attempt on the basis of the theory of mobile cellular automata to develop a model of motion of magnetic nanoparticles in human organs and tissues. In the framework of the method of movable cellular automata, the simulated system (tissues and organs) is represented by an assembly of interacting automata (elements of finite size). The concept of the method is based on the introduction of a new state type – the state of a pair of automata. Setting various parameters of the medium (tissues and organs). We can vary behavior of these particles in these mediums.

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Periodical:

Solid State Phenomena (Volume 215)

Pages:

284-287

DOI:

https://doi.org/10.4028/www.scientific.net/SSP.215.284

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Online since:

April 2014

Authors:

Peter Andriushenko, Leonid L. Afremov, Maria Chernova*

Keywords:

Magnetic Nanoparticles, Method of Movable Cellular Automata, Targeted Delivery

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References

[1] Q A Pankhurst, J Connolly, S K Jones and J Dobson. J. Phys. D: Appl. Phys. 36 (2003) R167–R181.

DOI: 10.1088/0022-3727/36/13/201

Google Scholar

[2] Christian Plank. Trends in Biotechnology Vol. 26 No. 2.

Google Scholar

[3] A.I. Galanov, T.A. Yurmazova1, G.G. Saveliev, M.A. Buldakov, Y. Rudyk, N.V. Litvyakov, K.A. Nechayev, S.A. Tuzikov2, N.V. Cherdyntseva, N.A. Jaworowski. Development of magnetically controlled delivery system of chemotherapy based on nanoscale iron particles. / / Siberian Journal of Oncology, (2008).

Google Scholar

[4] I.A. Hlusov, V.S. Gray, E.P. Nayden. Nanosystems, Nanomaterials, Nanotechnologies (2008).

Google Scholar

[5] Murali M. Yallapu , Shadi F. Othman, Evan T. Curtis, Brij K. Gupta, Meena Jaggi, Subhash C. Chauhan . Biomaterials 32 (2011) 1890e1905.

Google Scholar

[6] B. A. Larsen, M. A. Haag, N. J. Serkova, K. R. Shroyer and C.R. Stoldt. . J Nanotechnology 19 (2008) 265102 (7pp).

Google Scholar

[7] Z.P. Shulman, V.I. Kordonsky. Magneto-rheological effect. / / E: Science and Technology, 1982. -184s; silt.

Google Scholar

[8] A.N. Zakhlevny, D.A. Petrov. Journal of Applied Physics (2012), vol 82, no. 9.

Google Scholar

[9] Psakhie SG, Korostylev SY, A. Smolin etc. Physical Mesomechanics 1 (1998) 95-108.

Google Scholar