NDLI: FEM Optimization of Energy Density in Tumor Hyperthermia Using Time-Dependent Magnetic Nanoparticle Power Dissipation

Content Provider	IEEE Xplore Digital Library
Author	Koch, C.M. Winfrey, A.L.
Copyright Year	1965
Abstract	General principles are developed using a finite element model regarding how time-dependent power dissipation of magnetic nanoparticles can be used to optimize hyperthermia selectivity. To make the simulation more realistic, the finite size and spatial location of each individual nanoparticle is taken into consideration. When energy input into the system and duration of treatment is held constant, increasing the maximum power dissipation of nanoparticles increases concentrations of energy in the tumor. Furthermore, when the power dissipation of magnetic nanoparticles rises linearly, the temperature gradient on the edge of the tumor increases exponentially. With energy input held constant, the location and duration of maximum power dissipation in the treatment time scheme will affect the final energy concentration inside the tumor. Finally, connections are made between the simulation results and optimization of the design of nanoparticle power dissipation time-schemes for hyperthermia.
Sponsorship	IEEE Magnetics Society
Starting Page	1
Ending Page	7
Page Count	7
File Size	1071280
File Format	PDF
ISSN	00189464
Volume Number	50
Issue Number	10
Language	English
Publisher	Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Publisher Date	2014-01-01
Publisher Place	U.S.A.
Access Restriction	One Nation One Subscription (ONOS)
Rights Holder	Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subject Keyword	Hyperthermia Power dissipation Tumors Heating Finite element analysis Nanoparticles Mathematical model treatment planning Hyperthermia optimization finite-element modeling magnetic nanoparticles
Content Type	Text
Resource Type	Article
Subject	Electronic, Optical and Magnetic Materials Electrical and Electronic Engineering

Sl.	Authority	Responsibilities	Communication Details
1	Ministry of Education (GoI), Department of Higher Education	Sanctioning Authority	https://www.education.gov.in/ict-initiatives
2	Indian Institute of Technology Kharagpur	Host Institute of the Project: The host institute of the project is responsible for providing infrastructure support and hosting the project	https://www.iitkgp.ac.in
3	National Digital Library of India Office, Indian Institute of Technology Kharagpur	The administrative and infrastructural headquarters of the project	Dr. B. Sutradhar bsutra@ndl.gov.in
4	Project PI / Joint PI	Principal Investigator and Joint Principal Investigators of the project	Dr. B. Sutradhar bsutra@ndl.gov.in Prof. Saswat Chakrabarti will be added soon
5	Website/Portal (Helpdesk)	Queries regarding NDLI and its services	support@ndl.gov.in
6	Contents and Copyright Issues	Queries related to content curation and copyright issues	content@ndl.gov.in
7	National Digital Library of India Club (NDLI Club)	Queries related to NDLI Club formation, support, user awareness program, seminar/symposium, collaboration, social media, promotion, and outreach	clubsupport@ndl.gov.in
8	Digital Preservation Centre (DPC)	Assistance with digitizing and archiving copyright-free printed books	dpc@ndl.gov.in
9	IDR Setup or Support	Queries related to establishment and support of Institutional Digital Repository (IDR) and IDR workshops	idr@ndl.gov.in

Synthesizing Distributions of Magnetic Nanoparticles for Clinical Hyperthermia

Numerical FEM Models for the Planning of Magnetic Induction Hyperthermia Treatments With Nanoparticles

Localized heating of tumor cells utilizing superparamagnetic nanoparticles

Numerical Analysis of Electromagnetically Induced Heating and Bioheat Transfer for Magnetic Fluid Hyperthermia

Theoretical assessment of FePt nanoparticles as heating elements for magnetic hyperthermia

Hysteresis Loss of Fractionated Magnetic Nanoparticles for Hyperthermia Application

Design and Analysis of Novel Focused Hyperthermia Devices

Study on the Thermal Characteristics of Fe₃O₄ Nanoparticles and Gelatin Compound for Magnetic Fluid Hyperthermia in Radiofrequency Magnetic Field

Determining the optimal operative conditions in Magnetic NanoParticle Hyperthermia

FEM Optimization of Energy Density in Tumor Hyperthermia Using Time-Dependent Magnetic Nanoparticle Power Dissipation

Similar Documents

Synthesizing Distributions of Magnetic Nanoparticles for Clinical Hyperthermia

Numerical FEM Models for the Planning of Magnetic Induction Hyperthermia Treatments With Nanoparticles

Localized heating of tumor cells utilizing superparamagnetic nanoparticles

Numerical Analysis of Electromagnetically Induced Heating and Bioheat Transfer for Magnetic Fluid Hyperthermia

Theoretical assessment of FePt nanoparticles as heating elements for magnetic hyperthermia

Hysteresis Loss of Fractionated Magnetic Nanoparticles for Hyperthermia Application

Design and Analysis of Novel Focused Hyperthermia Devices

Study on the Thermal Characteristics of Fe3O4 Nanoparticles and Gelatin Compound for Magnetic Fluid Hyperthermia in Radiofrequency Magnetic Field

Determining the optimal operative conditions in Magnetic NanoParticle Hyperthermia

FEM Optimization of Energy Density in Tumor Hyperthermia Using Time-Dependent Magnetic Nanoparticle Power Dissipation

Study on the Thermal Characteristics of Fe₃O₄ Nanoparticles and Gelatin Compound for Magnetic Fluid Hyperthermia in Radiofrequency Magnetic Field