Calculation of nanoparticle capture efficiency in magnetic drug targeting

P. J. Cregg; Kieran Murphy; Adil Mardinoglu

doi:10.1016/j.jmmm.2008.06.021

Calculation of nanoparticle capture efficiency in magnetic drug targeting

P. J. Cregg, Kieran Murphy, Adil Mardinoglu

Research output: Contribution to journal › Article › peer-review

37 Citations (Scopus)

Abstract

The implant assisted magnetic targeted drug delivery system of Avilés, Ebner and Ritter, which uses high gradient magnetic separation (HGMS) is considered. In this 2D model large ferromagnetic particles are implanted as seeds to aid collection of multiple domain nanoparticles (radius ≈ 200 nm). Here, in contrast, single domain magnetic nanoparticles (radius in 20-100 nm) are considered and the Langevin function is used to describe the magnetization. Simulations based on this model were performed using the open source C ++ finite volume library OpenFOAM. The simulations indicate that use of the Langevin function predicts greater collection efficiency than might be otherwise expected.

Original language	English
Pages (from-to)	3272-3275
Number of pages	4
Journal	Journal of Magnetism and Magnetic Materials
Volume	320
Issue number	23
DOIs	https://doi.org/10.1016/j.jmmm.2008.06.021
Publication status	Published - Dec 2008

Keywords

High gradient magnetic separation (HGMS)
Magnetic drug targeting
Magnetic nanoparticle
Magnetic seed
Simulation

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title = "Calculation of nanoparticle capture efficiency in magnetic drug targeting",

abstract = "The implant assisted magnetic targeted drug delivery system of Avil{\'e}s, Ebner and Ritter, which uses high gradient magnetic separation (HGMS) is considered. In this 2D model large ferromagnetic particles are implanted as seeds to aid collection of multiple domain nanoparticles (radius ≈ 200 nm). Here, in contrast, single domain magnetic nanoparticles (radius in 20-100 nm) are considered and the Langevin function is used to describe the magnetization. Simulations based on this model were performed using the open source C ++ finite volume library OpenFOAM. The simulations indicate that use of the Langevin function predicts greater collection efficiency than might be otherwise expected.",

keywords = "High gradient magnetic separation (HGMS), Magnetic drug targeting, Magnetic nanoparticle, Magnetic seed, Simulation",

author = "Cregg, {P. J.} and Kieran Murphy and Adil Mardinoglu",

note = "Funding Information: This work was funded by Enterprise Ireland under the Applied Research Enhancement (ARE) program as part of the South Eastern Applied Materials (SEAM) Research Centre at Waterford Institute of Technology. AM is grateful to Cancer Research Ireland (Irish Cancer Society) for an Oncology Scholars Travel Award to attend the 6th International Conference on the Scientific and Clinical Applications of Magnetic Carriers , May 2006 in Krems, Austria. PJC and AM thank Armin Ebner, Axel Rosengart & Misael Avil{\'e}s for helpful conversations at Krems. ",

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doi = "10.1016/j.jmmm.2008.06.021",

language = "English",

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journal = "Journal of Magnetism and Magnetic Materials",

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AU - Cregg, P. J.

AU - Murphy, Kieran

AU - Mardinoglu, Adil

N1 - Funding Information: This work was funded by Enterprise Ireland under the Applied Research Enhancement (ARE) program as part of the South Eastern Applied Materials (SEAM) Research Centre at Waterford Institute of Technology. AM is grateful to Cancer Research Ireland (Irish Cancer Society) for an Oncology Scholars Travel Award to attend the 6th International Conference on the Scientific and Clinical Applications of Magnetic Carriers , May 2006 in Krems, Austria. PJC and AM thank Armin Ebner, Axel Rosengart & Misael Avilés for helpful conversations at Krems.

PY - 2008/12

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N2 - The implant assisted magnetic targeted drug delivery system of Avilés, Ebner and Ritter, which uses high gradient magnetic separation (HGMS) is considered. In this 2D model large ferromagnetic particles are implanted as seeds to aid collection of multiple domain nanoparticles (radius ≈ 200 nm). Here, in contrast, single domain magnetic nanoparticles (radius in 20-100 nm) are considered and the Langevin function is used to describe the magnetization. Simulations based on this model were performed using the open source C ++ finite volume library OpenFOAM. The simulations indicate that use of the Langevin function predicts greater collection efficiency than might be otherwise expected.

AB - The implant assisted magnetic targeted drug delivery system of Avilés, Ebner and Ritter, which uses high gradient magnetic separation (HGMS) is considered. In this 2D model large ferromagnetic particles are implanted as seeds to aid collection of multiple domain nanoparticles (radius ≈ 200 nm). Here, in contrast, single domain magnetic nanoparticles (radius in 20-100 nm) are considered and the Langevin function is used to describe the magnetization. Simulations based on this model were performed using the open source C ++ finite volume library OpenFOAM. The simulations indicate that use of the Langevin function predicts greater collection efficiency than might be otherwise expected.

KW - High gradient magnetic separation (HGMS)

KW - Magnetic drug targeting

KW - Magnetic nanoparticle

KW - Magnetic seed

KW - Simulation

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JF - Journal of Magnetism and Magnetic Materials

IS - 23

ER -

Calculation of nanoparticle capture efficiency in magnetic drug targeting

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