A new FDTD method for the study of MRI pulsed field gradient-induced fields in the human body

Author

Crozier, Stuart ; Zhao, Huawei ; Feng, Liu

Author_Institution

Centre For Magnetic Resonance, Queensland Univ., St. Lucia, Qld., Australia

fYear

2001

fDate

18-21 Nov. 2001

Firstpage

7

Lastpage

10

Abstract

In modern MRI, patients are exposed to strong, rapidly switched magnetic field gradients that may be able to elicit nerve stimulation. This paper provides the numerical results of an investigation into induced current spatial distributions inside human tissue when exposed to these pulsed magnetic field gradients. Conventional FDTD methods are unable to model these effects as the effective frequencies of the input source are less than 100 kHz or so, relatively low for FDTD calculations. A new high definition FDTD variant was developed to operate over this bandwidth and a number. of body and gradient models are analysed using the new method.

Keywords

biological tissues; biomagnetism; biomedical MRI; finite difference time-domain analysis; medical computing; MRI pulsed field gradient-induced fields; high definition FDTD; human tissue; induced current spatial distributions; nerve stimulation; strong rapidly switched magnetic field gradients; Australia; Biological system modeling; Coils; Finite difference methods; Frequency conversion; Humans; Magnetic fields; Magnetic resonance imaging; Magnetic switching; Time domain analysis;

fLanguage

English

Publisher

ieee

Conference_Titel

Intelligent Information Systems Conference, The Seventh Australian and New Zealand 2001

Print_ISBN

1-74052-061-0

Type

conf

DOI

10.1109/ANZIIS.2001.974039

Filename

974039