Real Time MR Thermometry Using Tm-DOTMA

Bu S Park,Sunder S Rajan,Martin J Lizak,Leonardo M Angelone

doi:10.4236/jemaa.2015.74013

Abstract

We present results of real-time and sensitive MR Thermometry (MRT) using a paramagnetic lanthanide complex thulium 1,4,7,10-tetraazacyclododecane-1,4,7,10-tetramethyl-1,4,7,10-tetraa-cetate (Tm-DOTMA) to study radio frequency (RF) heating induced by a copper wire and a titanium bone screw in an agarose gel phantom. The temperature dependent chemical shift coefficient (TDCSC) of the methyl resonance was found to be 0.7 ± 0.03 ppm/°;C in agarose gel. The methyl protons of Tm-DOTMA were imaged using 2D chemical shift imaging (CSI) and 3D phase mapping methods (PMM), approximately 7 sec long, and compared with conventional water proton resonance frequency (PRF) method. Two RF-induced heating approaches were tested: 1) using a prescan before the MRT; or 2) using the heating caused by the imaging pulse during continuous imaging. Both approaches allowed detection of temperature changes which are less than 1°;C and continuously mapping temperature changes around the copper wire. Using a heating pre-scan, the Tm-DOTMA 2D-CSI allowed better qualitative visualization of the temperature changes around the titanium screw compared with water phase shift thermometry. Numerical electromagnetic field simulations were also conducted for the evaluation of orientation dependency using the copper wire in 4.7 T (200 MHz). Thermometry approach using Tm-DOTMA can detect smaller temperature changes with decreased scanning time resulting in real-time and sensitive temperature mapping.

Highlights

How to cite this paper: Park, B.S., Lizak, M.J., Angelone, L.M. and Rajan, S.S. (2015) Real Time MR Thermometry Using Tm-DOTMA
In order to facilitate the development of medical implants that are safe for Magnetic resonance imaging (MRI) use, there is a need to design real time and robust methods to test the extent of radio frequency (RF)-induced heating of tissue generated during an MRI scan
TDCSC measurement and chemical shift imaging (CSI) implementation Temperature dependent chemical shift coefficient (TDCSC) measurements of Tm-DOTMA were performed in agarose gel

Summary

Introduction

How to cite this paper: Park, B.S., Lizak, M.J., Angelone, L.M. and Rajan, S.S. (2015) Real Time MR Thermometry Using Tm-DOTMA. While MRI is considered to be a safe technology, there are possible risks, such as tissue heating caused by the radio frequency (RF) electromagnetic energy used to elicit the MRI signal [1]-[10]. This issue may be exacerbated in patients with metallic implants, because of the RF currents induced along the implant and the related electric field enhancement at the interface between implant and tissue [11]. In order to facilitate the development of medical implants that are safe for MRI use, there is a need to design real time and robust methods to test the extent of RF-induced heating of tissue generated during an MRI scan. These measurements are inherently difficult due to the need for precise probe positioning related to the highly geometry-dependent and spatially inhomogeneous RF-induced heating [12]

Methods

Results

Conclusion