Optimizing Magnetic Fields and Coil Designs for Magnetic Hyperthermia – Breast Cancer Treatment

Mehul Chauhan; Xianghong Ma; Yu Jia

doi:10.1007/978-3-031-62502-2_1

Optimizing Magnetic Fields and Coil Designs for Magnetic Hyperthermia – Breast Cancer Treatment

Mehul Chauhan, Xianghong Ma^*, Yu Jia

^*Corresponding author for this work

Research output: Chapter in Book/Published conference output › Conference publication

Abstract

Magnetic hyperthermia is an emerging method that can be utilized in the medical world to treat cancer. The concept revolves around heating magnetic nanoparticles to approximately 45 °C. The magnetic field is central to this process and plays a vital role in achieving the desired therapeutic effects. This study looks at optimizing the coil geometry to enhance magnetic field strengths whilst simultaneously ensuring safety. Coil geometries influence the field produced significantly. Traditional coil designs are based on conventional helical solenoids that produce fields up to 20 kA/m. To further develop the geometry, FEA simulations were employed to analyze different coil geometries. Research indicated that conventional pancake coils were ineffective unless the cancer was close to the surface of the skin. Contrary to this, the conical frustum shaped coil, tailored to fit around the human breast displayed advantageous results, even when compared to the standard solenoid. The conical frustum shaped coil was validated to ensure that safety and comfort tolerances were adhered to. Within 10 min of hyperthermia treatment, the proposed geometry would be able to produce field strengths (9 kA/m) that lead to sufficient temperature increase for effective breast cancer treatment. Magnetic hyperthermia is a concept with significant scope in the medical world. The magnetic field is pivotal, and the study demonstrates the advantages of tailoring the geometry to enhance the fields produced. Through optimizing the magnetic field strength intensity and targeting ability, whilst maintaining patient comfort and safety, the research advances the prospects of magnetic hyperthermia as a cancer treatment process.

Original language	English
Title of host publication	Advances in Digital Health and Medical Bioengineering: Proceedings of the 11th International Conference on E-Health and Bioengineering, EHB-2023
Subtitle of host publication	Volume 1: Medical Devices, Measurements, and Artificial Intelligence Applications
Editors	Hariton-Nicolae Costin, Gladiola Gabriela Petroiu, Ratko Magjarevic
Pages	3-12
Number of pages	10
Edition	1
ISBN (Electronic)	9783031625022
DOIs	https://doi.org/10.1007/978-3-031-62502-2_1
Publication status	E-pub ahead of print - 30 Aug 2024
Event	11th International Conference on E-Health and Bioengineering, EHB 2023 - Bucharest, Romania Duration: 9 Nov 2023 → 10 Nov 2023

Publication series

Name	IFMBE Proceedings
Volume	109
ISSN (Print)	1680-0737
ISSN (Electronic)	1433-9277

Conference

Conference	11th International Conference on E-Health and Bioengineering, EHB 2023
Country/Territory	Romania
City	Bucharest
Period	9/11/23 → 10/11/23

Keywords

Coil
Conical Frustum
Hyperthermia
Magnetic Field
Simulations

Access to Document

10.1007/978-3-031-62502-2_1

Cite this

Chauhan, M., Ma, X., & Jia, Y. (2024). Optimizing Magnetic Fields and Coil Designs for Magnetic Hyperthermia – Breast Cancer Treatment. In H.-N. Costin, G. G. Petroiu, & R. Magjarevic (Eds.), Advances in Digital Health and Medical Bioengineering: Proceedings of the 11th International Conference on E-Health and Bioengineering, EHB-2023: Volume 1: Medical Devices, Measurements, and Artificial Intelligence Applications (1 ed., pp. 3-12). (IFMBE Proceedings; Vol. 109). Advance online publication. https://doi.org/10.1007/978-3-031-62502-2_1

Chauhan, Mehul ; Ma, Xianghong ; Jia, Yu. / Optimizing Magnetic Fields and Coil Designs for Magnetic Hyperthermia – Breast Cancer Treatment. Advances in Digital Health and Medical Bioengineering: Proceedings of the 11th International Conference on E-Health and Bioengineering, EHB-2023: Volume 1: Medical Devices, Measurements, and Artificial Intelligence Applications. editor / Hariton-Nicolae Costin ; Gladiola Gabriela Petroiu ; Ratko Magjarevic. 1. ed. 2024. pp. 3-12 (IFMBE Proceedings).

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abstract = "Magnetic hyperthermia is an emerging method that can be utilized in the medical world to treat cancer. The concept revolves around heating magnetic nanoparticles to approximately 45 °C. The magnetic field is central to this process and plays a vital role in achieving the desired therapeutic effects. This study looks at optimizing the coil geometry to enhance magnetic field strengths whilst simultaneously ensuring safety. Coil geometries influence the field produced significantly. Traditional coil designs are based on conventional helical solenoids that produce fields up to 20 kA/m. To further develop the geometry, FEA simulations were employed to analyze different coil geometries. Research indicated that conventional pancake coils were ineffective unless the cancer was close to the surface of the skin. Contrary to this, the conical frustum shaped coil, tailored to fit around the human breast displayed advantageous results, even when compared to the standard solenoid. The conical frustum shaped coil was validated to ensure that safety and comfort tolerances were adhered to. Within 10 min of hyperthermia treatment, the proposed geometry would be able to produce field strengths (9 kA/m) that lead to sufficient temperature increase for effective breast cancer treatment. Magnetic hyperthermia is a concept with significant scope in the medical world. The magnetic field is pivotal, and the study demonstrates the advantages of tailoring the geometry to enhance the fields produced. Through optimizing the magnetic field strength intensity and targeting ability, whilst maintaining patient comfort and safety, the research advances the prospects of magnetic hyperthermia as a cancer treatment process.",

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author = "Mehul Chauhan and Xianghong Ma and Yu Jia",

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booktitle = "Advances in Digital Health and Medical Bioengineering: Proceedings of the 11th International Conference on E-Health and Bioengineering, EHB-2023",

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Chauhan, M, Ma, X & Jia, Y 2024, Optimizing Magnetic Fields and Coil Designs for Magnetic Hyperthermia – Breast Cancer Treatment. in H-N Costin, GG Petroiu & R Magjarevic (eds), Advances in Digital Health and Medical Bioengineering: Proceedings of the 11th International Conference on E-Health and Bioengineering, EHB-2023: Volume 1: Medical Devices, Measurements, and Artificial Intelligence Applications. 1 edn, IFMBE Proceedings, vol. 109, pp. 3-12, 11th International Conference on E-Health and Bioengineering, EHB 2023, Bucharest, Romania, 9/11/23. https://doi.org/10.1007/978-3-031-62502-2_1

Optimizing Magnetic Fields and Coil Designs for Magnetic Hyperthermia – Breast Cancer Treatment. / Chauhan, Mehul; Ma, Xianghong ; Jia, Yu.
Advances in Digital Health and Medical Bioengineering: Proceedings of the 11th International Conference on E-Health and Bioengineering, EHB-2023: Volume 1: Medical Devices, Measurements, and Artificial Intelligence Applications. ed. / Hariton-Nicolae Costin; Gladiola Gabriela Petroiu; Ratko Magjarevic. 1. ed. 2024. p. 3-12 (IFMBE Proceedings; Vol. 109).

Research output: Chapter in Book/Published conference output › Conference publication

TY - GEN

T1 - Optimizing Magnetic Fields and Coil Designs for Magnetic Hyperthermia – Breast Cancer Treatment

AU - Chauhan, Mehul

AU - Ma, Xianghong

AU - Jia, Yu

PY - 2024/8/30

Y1 - 2024/8/30

N2 - Magnetic hyperthermia is an emerging method that can be utilized in the medical world to treat cancer. The concept revolves around heating magnetic nanoparticles to approximately 45 °C. The magnetic field is central to this process and plays a vital role in achieving the desired therapeutic effects. This study looks at optimizing the coil geometry to enhance magnetic field strengths whilst simultaneously ensuring safety. Coil geometries influence the field produced significantly. Traditional coil designs are based on conventional helical solenoids that produce fields up to 20 kA/m. To further develop the geometry, FEA simulations were employed to analyze different coil geometries. Research indicated that conventional pancake coils were ineffective unless the cancer was close to the surface of the skin. Contrary to this, the conical frustum shaped coil, tailored to fit around the human breast displayed advantageous results, even when compared to the standard solenoid. The conical frustum shaped coil was validated to ensure that safety and comfort tolerances were adhered to. Within 10 min of hyperthermia treatment, the proposed geometry would be able to produce field strengths (9 kA/m) that lead to sufficient temperature increase for effective breast cancer treatment. Magnetic hyperthermia is a concept with significant scope in the medical world. The magnetic field is pivotal, and the study demonstrates the advantages of tailoring the geometry to enhance the fields produced. Through optimizing the magnetic field strength intensity and targeting ability, whilst maintaining patient comfort and safety, the research advances the prospects of magnetic hyperthermia as a cancer treatment process.

AB - Magnetic hyperthermia is an emerging method that can be utilized in the medical world to treat cancer. The concept revolves around heating magnetic nanoparticles to approximately 45 °C. The magnetic field is central to this process and plays a vital role in achieving the desired therapeutic effects. This study looks at optimizing the coil geometry to enhance magnetic field strengths whilst simultaneously ensuring safety. Coil geometries influence the field produced significantly. Traditional coil designs are based on conventional helical solenoids that produce fields up to 20 kA/m. To further develop the geometry, FEA simulations were employed to analyze different coil geometries. Research indicated that conventional pancake coils were ineffective unless the cancer was close to the surface of the skin. Contrary to this, the conical frustum shaped coil, tailored to fit around the human breast displayed advantageous results, even when compared to the standard solenoid. The conical frustum shaped coil was validated to ensure that safety and comfort tolerances were adhered to. Within 10 min of hyperthermia treatment, the proposed geometry would be able to produce field strengths (9 kA/m) that lead to sufficient temperature increase for effective breast cancer treatment. Magnetic hyperthermia is a concept with significant scope in the medical world. The magnetic field is pivotal, and the study demonstrates the advantages of tailoring the geometry to enhance the fields produced. Through optimizing the magnetic field strength intensity and targeting ability, whilst maintaining patient comfort and safety, the research advances the prospects of magnetic hyperthermia as a cancer treatment process.

KW - Coil

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KW - Hyperthermia

KW - Magnetic Field

KW - Simulations

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Chauhan M, Ma X , Jia Y. Optimizing Magnetic Fields and Coil Designs for Magnetic Hyperthermia – Breast Cancer Treatment. In Costin HN, Petroiu GG, Magjarevic R, editors, Advances in Digital Health and Medical Bioengineering: Proceedings of the 11th International Conference on E-Health and Bioengineering, EHB-2023: Volume 1: Medical Devices, Measurements, and Artificial Intelligence Applications. 1 ed. 2024. p. 3-12. (IFMBE Proceedings). Epub 2024 Aug 30. doi: 10.1007/978-3-031-62502-2_1

Optimizing Magnetic Fields and Coil Designs for Magnetic Hyperthermia – Breast Cancer Treatment

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