A study of magnetic shielding design for a magnetic resonance imaging linac system_Journal of Biomedical Engineering

Authors：

ZHANG Zheshun , CHEN Wenjing , QIU Yang ,  ZHU Jianming

School of Information Engineering, China Jiliang University, Hangzhou 310018, P.R.China;

Corresponding author：

ZHU Jianming, Email: drzhulab@gmail.com

Keywords：

magnetic resonance imaging linear accelerator system; magnetic field shielding; simulation

DOI：

10.7507/1001-5515.201611027

Video：

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One of the main technical challenges when integrating magnetic resonance imaging (MRI) systems with medical linear accelerator is the strong interference of fringe magnetic fields from the MRI system with the electron beams of linear accelerator, making the linear accelerator not to work properly. In order to minimize the interference of magnetic fields, a magnetic shielding cylinder with an open structure made of high permeability materials is designed. ANSYS Maxwell was used to simulate Helmholtz coil which generate uniform magnetic field instead of the fringe magnetic fields which affect accelerator gun. The parameters of shielding tube, such as permeability, radius, length, side thickness, bottom thickness and fringe magnetic fields strength are simulated, and the data is processed by MATLAB to compare the shielding performance. This article gives out a list of magnetic shielding effectiveness with different side thickness and bottom thickness under the optimal radius and length, which showes that this design can meet the shielding requirement for the MRI-linear accelerator system.

Citation： ZHANG Zheshun, CHEN Wenjing, QIU Yang, ZHU Jianming. A study of magnetic shielding design for a magnetic resonance imaging linac system. Journal of Biomedical Engineering, 2017, 34(6): 889-894. doi: 10.7507/1001-5515.201611027 Copy

1.	Lagendijk J J, Raaymakers B W, Van den Berg C A, et al. MR guidance in radiotherapy. Phys Med Biol, 2014, 59(21): R349-R369.
2.	St Aubin J, Steciw S, Fallone B G. Effect of transverse magnetic fields on a simulated in-line 6 MV linac. Phys Med Biol, 2010, 55(16): 4861-4869.
3.	Keyvanloo A, Burke B, Warkentin B, et al. Skin dose in longitudinal and transverse linac-MRIs using Monte Carlo and realistic 3D MRI field models. Med Phys, 2012, 39(10): 6509-6521.
4.	Lagendijk J J, Raaymakers B W, Raaijmakers A J, et al. MRI/linac integration. Radiother Oncol, 2008, 86(1): 25-29.
5.	Raaymakers B W, Lagendijk J J, Overweg J, et al. Integrating a 1.5 T MRI scanner with a 6 MV accelerator: proof of concept. Phys Med Biol, 2009, 54(12): N229-N237.
6.	St Aubin J, Steciw S, Fallone B G. Magnetic decoupling of the linac in a low field biplanar linac-MR system. Med Phys, 2010, 37(9): 4755-4761.
7.	Lamey M, Burke B, Blosser E, et al. Radio frequency shielding for a linac-MRI system. Phys Med Biol, 2010, 55(4): 995-1006.
8.	Sumner T J, Pendlebury J M, Smith K F. Convectional magnetic shielding. J Phys D Appl Phys, 1987, 20(1987): 1095-1101.
9.	Mager A J. Magnetic shields. IEEE Trans Magn, 1970, 6(1): 67-75.
10.	Overweg J, Raaymakers B W, Lagendijk J W, et al. System for MRI guided radiotherapy. Proc Int Soc Mag Reson Med, 2009, 17(2009): 594.
11.	Santos D M, St Aubin J, Fallone B G, et al. Magnetic shielding investigation for a 6 MV in-line linac within the parallel configuration of a linac-MR system. Med Phys, 2012, 39(2): 788-797.
12.	曾庆庾, 徐国华, 宋国乡. 电磁场有限单元法. 北京: 科学出版社, 1982.
13.	刘涛, 杨凤鹏. 精通 ANSYS. 北京: 清华大学出版社, 2002.
14.	夏志伟, 李伟, 卢杰, 等. ITER 气体加料阀门箱磁屏蔽效能的有限元分析. 核聚变与等离子体物理, 2009, 29(4): 353-356.
15.	周辉. 磁屏蔽技术的仿真研究. 长沙: 湖南大学, 2014.
16.	杨士元. 电磁屏蔽理论与实践. 北京: 国防工业出版社, 2006.
17.	St Aubin J, Santos D M, Steciw S, et al. Effect of longitudinal magnetic fields on a simulated in-line 6 MV linac. Med Phys, 2010, 37(9): 4916-4923.
18.	Constantin D E, Fahrig R, Keall P J. A study of the effect of in-line and perpendicular magnetic fields on beam characteristics of electron guns in medical linear accelerators. Med Phys, 2011, 38(7): 4174-4185.
19.	St Aubin J, Steciw S, Fallone B G. The design of a simulated in-line side-coupled 6 MV linear accelerator waveguide. Med Phys, 2010, 37(2): 466-476.

1. Lagendijk J J, Raaymakers B W, Van den Berg C A, et al. MR guidance in radiotherapy. Phys Med Biol, 2014, 59(21): R349-R369.
2. St Aubin J, Steciw S, Fallone B G. Effect of transverse magnetic fields on a simulated in-line 6 MV linac. Phys Med Biol, 2010, 55(16): 4861-4869.
3. Keyvanloo A, Burke B, Warkentin B, et al. Skin dose in longitudinal and transverse linac-MRIs using Monte Carlo and realistic 3D MRI field models. Med Phys, 2012, 39(10): 6509-6521.
4. Lagendijk J J, Raaymakers B W, Raaijmakers A J, et al. MRI/linac integration. Radiother Oncol, 2008, 86(1): 25-29.
5. Raaymakers B W, Lagendijk J J, Overweg J, et al. Integrating a 1.5 T MRI scanner with a 6 MV accelerator: proof of concept. Phys Med Biol, 2009, 54(12): N229-N237.
6. St Aubin J, Steciw S, Fallone B G. Magnetic decoupling of the linac in a low field biplanar linac-MR system. Med Phys, 2010, 37(9): 4755-4761.
7. Lamey M, Burke B, Blosser E, et al. Radio frequency shielding for a linac-MRI system. Phys Med Biol, 2010, 55(4): 995-1006.
8. Sumner T J, Pendlebury J M, Smith K F. Convectional magnetic shielding. J Phys D Appl Phys, 1987, 20(1987): 1095-1101.
9. Mager A J. Magnetic shields. IEEE Trans Magn, 1970, 6(1): 67-75.
10. Overweg J, Raaymakers B W, Lagendijk J W, et al. System for MRI guided radiotherapy. Proc Int Soc Mag Reson Med, 2009, 17(2009): 594.
11. Santos D M, St Aubin J, Fallone B G, et al. Magnetic shielding investigation for a 6 MV in-line linac within the parallel configuration of a linac-MR system. Med Phys, 2012, 39(2): 788-797.
12. 曾庆庾, 徐国华, 宋国乡. 电磁场有限单元法. 北京: 科学出版社, 1982.
13. 刘涛, 杨凤鹏. 精通 ANSYS. 北京: 清华大学出版社, 2002.
14. 夏志伟, 李伟, 卢杰, 等. ITER 气体加料阀门箱磁屏蔽效能的有限元分析. 核聚变与等离子体物理, 2009, 29(4): 353-356.
15. 周辉. 磁屏蔽技术的仿真研究. 长沙: 湖南大学, 2014.
16. 杨士元. 电磁屏蔽理论与实践. 北京: 国防工业出版社, 2006.
17. St Aubin J, Santos D M, Steciw S, et al. Effect of longitudinal magnetic fields on a simulated in-line 6 MV linac. Med Phys, 2010, 37(9): 4916-4923.
18. Constantin D E, Fahrig R, Keall P J. A study of the effect of in-line and perpendicular magnetic fields on beam characteristics of electron guns in medical linear accelerators. Med Phys, 2011, 38(7): 4174-4185.
19. St Aubin J, Steciw S, Fallone B G. The design of a simulated in-line side-coupled 6 MV linear accelerator waveguide. Med Phys, 2010, 37(2): 466-476.

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