Interaction Between 3-T MRI Systems and Patients with an Implanted Pacemaker
Keywords:
Cardiac pacemakers, dosimetry, magnetic resonance imaging (MRI), temperatureAbstract
In this paper, a transverse electro-magnetic (TEM) coil operating at 128 MHz in a 3-T magnetic resonance imaging system has been studied in terms of the interaction with patients with or without an implanted pacemaker. The pacemaker has been simulated as a copper box with a catheter constituted by an insulated copper wire with an uncapped tip and it has been placed inside either box or anatomical models of the thorax. Electromagnetic and thermal simulations have been performed by using finite difference time domain codes. The obtained results show that in the absence of the pacemaker, and for a radiated power producing in the box a whole body specific absorption rate (SAR) of 1 W/kg, that is a typical value for MRI examinations, the coil produces in the anatomical models peak temperature values lower than the limits issued by the International Electrotechnical Commission (IEC). In the presence of the pacemaker, temperature increments at the catheter tip in excess of those issued by the IEC standard are obtained when the MRI scanned area involves the pacemaker region. The 3-T coil produces lower SAR and temperature increments with respect to a 64-MHz (1.5-T system) birdcage antenna in patients with implanted pacemaker.
Downloads
References
ICNIRP Statement on: “Medical magnetic resonance (MR) procedures: protection of patients,” Health Phys., vol. 87, pp. 197-216, 2004.
J. R. Gimbel and E. Kanal, “Can patients with implantable pacemakers safely undergo magnetic resonance imaging?,” J. Am. Coll. Cardiol., vol. 43, pp. 1325-1327, 2004.
M. H. Schoenfeld, “Contemporary pacemaker and defibrillator device therapy: challenges confronting the general cardiologist,” Circulation, vol. 115, pp. 638-653, 2007.
S. Achenbach, B. Moshage, W. Diem, T. Bieberle, V. Schibgilla, and K. Bachmann “Effects of magnetic resonance imaging on cardiac pacemakers and electrodes,” Am. Heart. J., vol. 134, pp. 467-473, 1997.
T. Sommer, C. Vahlhaus, G. Lauck, A. von Smekal, M. Reinke, U. Hofer, W. Bloch, F. Traber, C. Schneider, J. Gieseke, W. Jung, and H. Schild, “MR imaging and cardiac pacemaker: invitro evaluation and in-vivo studies in 51 patients at 0.5 T,” Radiology, vol. 215, pp. 869-879, 2000.
A. Roguin, M. M. Zviman, G. R. Meininger, E. R. Rodrigues, T. M. Dickfeld, D. A. Bluemke, A. Lardo, R. D. Berger, H. Calkins, and H. R. Halperin, “Modern pacemaker and implantable cardioverter/defibrillator systems can be magnetic resonance imaging safe, in vitro and in vivo assessment of safety and function at 1.5 T,” Circulation, vol. 110, pp. 475-482, 2004.
International Electrotechnical Commission, International Standard, Medical Electrical Equipment–IEC 60601-2-33, Particular Requirements for the Basic Safety and Essential Performance of Magnetic Resonance Equipment for Medical Diagnosis, 3rd edition, Geneva: IEC, 2010.
U. D. Nguyen, S. Brown, I. A. Chang, J. K. Krycia, and M. S. Mirotznik, “Numerical evaluation of heating of the human head due to magnetic resonance imaging,” IEEE Trans. Biomed. Eng., vol. 51, pp. 1301-1309, 2004.
W. Liu, C. M. Collins, and M. B. Smith, “Calculations of B1 distribution, specific energy absorption rate, and intrinsic signal-to-noise ratio for a body-size birdcage coil loaded with different human subjects at 64 and 128 MHz,” Appl. Magn. Reson., vol. 29, pp. 5-18, 2005.
C. M. Collins, S. Li, and M. B. Smith, “SAR and B1 field distributions in a heterogeneous human head model within a birdcage coil,” Magnetic Resonance in Medicine, vol. 40, pp. 847-856, 1998.
Z. Wang and J. C. Lin, “SAR calculations in MRI scanning systems,” IEEE Microwave Magazine, vol. 13, pp. 22-29, 2012.
H. S. Ho, “Safety of metallic implants in magnetic resonance imaging,” J. Magn. Reson. Imaging, vol. 14, pp. 472-477, 2001.
J. A. Nyenhuis, S. M. Park, and R. Kamondetdacha, “MRI and implanted medical devices: basic interactions with an emphasis on heating,” IEEE Trans. Dev. Mat. Reliab., vol. 5, pp. 467-480, 2005.
S. M. Park, R. Kamondetdacha, A. Amjad, and J. A. Nyenhuis, “MRI safety: RF induced heating on straight wires,” IEEE Trans. Magn., vol. 41, pp. 4197-4199, 2005.
M. A. Stuchly, H. Abrishamkar, and M. L. Strydom, “Numerical evaluation of radio frequency power deposition in human models during MRI,” Proc. IEEE EMBS Int. Conf., New York City, USA, pp. 272-275, 2006.
S. Pisa, G. Calcagnini, M. Cavagnaro, E. Piuzzi, E. Mattei, and P. Bernardi, “A study of the interaction between implanted pacemakers and the radio frequency field produced by magnetic resonance imaging apparatus,” IEEE Trans. Electromag. Compat., vol. 50, pp. 35-42, 2008.
S. Pisa, P. Bernardi, M. Cavagnaro, and E. Piuzzi, “Power absorption and temperature elevation produced by magnetic resonance apparatus in the thorax of patients with implanted pacemakers,” IEEE Trans. Electromag. Compat., vol. 52, pp. 32-40, 2010.
J. T. Vaughan, G. Adriany, M. Garwood, E. Yacoub, T. Duong, L. Dela Barre, P. Andersen, and K. Ugurbil, “Detunable transverse electromagnetic (TEM) volume coil for high-field NMR,” Magnetic Resonance in Medicine, vol. 47, pp. 990-1000, 2002.
G. Bodganov and R. Ludwing, “Coupled microstrip line transverse electromagnetic resonator model for high-field magnetic resonance imaging,” Magnetic Resonance in Medicine, vol. 47, pp. 579-593, 2002.
M. Alecci, C. M. Collins, M. B. Smith, and P. Jezzard, “Radio frequency magnetic field mapping of a 3 tesla birdcage coil: experimental and theoretical dependence on sample properties,” Magnetic Resonance in Medicine, vol. 46, pp. 379-385, 2001.
J. R. Gimbel, “Magnetic resonance imaging of implantable cardiac rhythm devices at 3.0 tesla,” Pacing Clin. Electrophysiol, vol. 31, pp. 795-801, 2008.
F. G. Shellock, J. Begnaud, and D. M. Inman, “Vagus nerve stimulation therapy system: in vitro evaluation of magnetic resonance imaging-related heating and function at 1.5 and 3 tesla,” Neuromodulation, vol. 9, pp. 204-213, 2006.
M-A. Golombeck and O. Dossel, “MRtomography on patients with heart pacemakers – a numerical study,” Proc. IEEE EMBS Int. Conf., San Francisco, USA, pp. 1076-1079, 2004.
J. C. Lin, P. Bernardi, S. Pisa, M. Cavagnaro, and E. Piuzzi, “Antennas for medical therapy and diagnostics,” in Modern Antenna Handbook, ed. C. Balanis, Wiley, pp. 1377-1428, 2008.
A. Christ, W. Kainz, E. G. Hahn, K. Honegger, M. Zefferer, E. Neufeld, W. Rascher, R. Janka, W. Bautz, J. Chen, B. Kiefer, P. Schmitt, H-P. Hollenbach, J. Shen, M. Oberle, D. Szczerba, A. Kam, J. W. Guag, and N. Kuster, “The virtual family development of surface-based anatomical models of two adults and two children for dosimetric simulations,” Phys. Med. Biol., vol. 55, pp. 23-38, 2010.
E. Mattei, M. Triventi, G. Calcagnini, F. Censi, W. Kainz, G. Mendoza, H. I. Bassen, and P. Bartolini, “Complexity of MRI induced heating on metallic leads: experimental measurements of 374 configurations,” Biomedical Engineering OnLine, 7: 11, 2008.
A. L. Aguilera, Y. V. Volokhina, and K. L. Fisher, “Radiography of cardiac conduction devices: a comprehensive review,” RadioGraphics, vol. 31, pp. 1669-1682, 2011.
S. Pisa, M. Cavagnaro, E. Piuzzin, and V. Lopresto, “Numerical-experimental validation of a GM-FDTD code for the study of cellular phones,” Microwave Opt. Technol. Lett., vol. 47, pp. 396-400, 2005.
A. Taflove and S. C. Hagness, Computational Electrodynamics: The Finite-Difference TimeDomain Method, Boston, MA: Artech House, 2000.
D. Andreuccetti, R. Fossi, and C. Petrucci, “An internet resource for the calculation of the dielectric properties of body tissues in the frequency range 10 Hz - 100 GHz,” Internet document; URL:http://niremf.ifac.cnr.it/tissprop/.
H. H. Pennes, “Analysis of tissue and arterial blood temperatures in resting forearm,” J. Appl. Physiol., vol. 1, pp. 93-122, 1948.
P. Bernardi, M. Cavagnaro, S. Pisa, and E. Piuzzi, “Specific absorption rate and temperature elevation in a subject exposed in the far-field of radio-frequency sources operating in the 10-900 MHz range,” IEEE Trans. Biomed. Eng., vol. 50, pp. 295-304, 2003.
S. Pisa, M. Cavagnaro, E. Piuzzi, P. Bernardi, and J. C. Lin, “Power density and temperature distributions produced by interstitial arrays of sleeved-slot antennas for hyperthermic cancer therapy,” IEEE Trans. Microwave Theory Tech., vol. 51, pp. 2418-2426, 2003.
URL: http://www.itis.ethz.ch/itis-for-health/tissueproperties/database/.
S. Oh, Y-C. Ryu, G. Carluccio, C. T. Sica, and C. M. Collins, “Measurement of SAR-induced temperature increase in a phantom and in vivo with comparison to numerical simulation,” Magnetic Resonance in Medicine, vol. 71, pp. 1923-1931, 2014.
F. G. Shellock, S. Valencerina, and L. Fischer, “MRI-related heating of pacemaker at 1.5- and 3- tesla: evaluation with and without pulse generator attached to leads,” Circulation, vol. 112: Supplement II, pp. 561, 2005.
S. Tungjitkusolmun, V. R. Vorperian, N. Bhavaraju, H. Cao, J. Z. Tsai, and J. G. Webster, “Guidelines for predicting lesion size at common endocardial locations during radio-frequency ablation,” IEEE Trans. Biomed. Eng., vol. 48, pp. 194-201, 2001.
Z. Cao, J. Park, Z-H. Cho, and C. M. Collins, “Numerical evaluation of image homogeneity, signal-to-noise ratio, and specific absorption rate for human brain imaging at 1.5, 3, 7, 10.5, and 14 T in an 8-channel transmit/receive array,” J. Magn. Reson. Imaging, DOI 10.1002/jmri.24689, pp. 1- 7, 2014.