Continuous Focus Field Variation for Extending the Imaging Range in 3D MPI

被引:0
|
作者
Rahmer, J. [1 ]
Gleich, B. [1 ]
Schmidt, J. [1 ]
Bontus, C. [1 ]
Schmale, I. [1 ]
Kanzenbach, J. [1 ]
Borgert, J. [1 ]
Woywode, O. [2 ]
Halkola, A. [3 ]
Weizenecker, J. [4 ]
机构
[1] Philips Technol GmbH Innovat Technol, Res Labs, Rontgenstr 24-26, D-22335 Hamburg, Germany
[2] Philips Med Syst DMC GmbH, D-22335 Hamburg, Germany
[3] Univ Lubeck, Inst Med Engn, D-23562 Lubeck, Germany
[4] Univ Appl Sci, D-76133 Karlsruhe, Germany
来源
MAGNETIC PARTICLE IMAGING: A NOVEL SPIO NANOPARTICLE IMAGING TECHNIQUE, 1ST EDITION | 2012年 / 140卷
关键词
PARTICLES;
D O I
暂无
中图分类号
R318 [生物医学工程];
学科分类号
0831 ;
摘要
The imaging volume that is rapidly encoded by drive fields in 3D magnetic particle imaging is limited by power dissipation and nerve stimulation thresholds. Additional coils have been implemented to generate so-called focus fields that operate at lower frequencies and extend the accessible imaging range. This contribution presents the possibility of sweeping the rapidly encoded imaging volume along an arbitrary 3D path using continuous focus field variations. This technique can be useful for following a tracer bolus, for tracking devices, or for dynamically moving the image focus to different regions of interest.
引用
收藏
页码:255 / 259
页数:5
相关论文
共 50 条
  • [1] Modeling and Simulation of Wide Range Homogeneous Selection Field for 3D MPI Scanner
    Irfan, M.
    Dogan, O. Mercan
    Dogan, N.
    Bingolbali, A.
    MEDICAL PHYSICS, 2019, 46 (06) : E141 - E142
  • [2] 3D x-ray imaging of continuous objects beyond the depth of focus limit
    Gilles, M. A.
    Nashed, Y. S. G.
    Du, M.
    Jacobsen, C.
    Wild, S. M.
    OPTICA, 2018, 5 (09): : 1078 - 1086
  • [3] 3D Imaging without Range Information
    Rogers, J. D.
    Myatt, D. R.
    AIRBORNE INTELLIGENCE, SURVEILLANCE, RECONNAISSANCE (ISR) SYSTEMS AND APPLICATIONS VII, 2010, 7668
  • [4] Extending the OGC OpenLS Route Service to 3D for an interoperable realisation of 3D focus maps with landmarks
    Neis, Pascal
    Zipf, Alexander
    JOURNAL OF LOCATION BASED SERVICES, 2008, 2 (02) : 153 - 174
  • [5] Achieving 3D Imaging through Focus Stacking
    Wlodek, J.
    Gofron, K. J.
    Cai, Y. Q.
    13TH INTERNATIONAL CONFERENCE ON SYNCHROTRON RADIATION INSTRUMENTATION (SRI2018), 2019, 2054
  • [6] 3D reconstruction from focus for lensless imaging
    Li, Ying
    Li, Zhengdai
    Chen, Kaiyu
    Guo, Youming
    Rao, Changhui
    APPLIED OPTICS, 2024, 63 (31) : 8212 - 8220
  • [7] 3D imaging of the fetal face - Recommendations from the International 3D Focus Group
    Merz, E.
    Abramovicz, J.
    Baba, K.
    Blaas, H. -G. K.
    Deng, J.
    Gindes, L.
    Lee, W.
    Platt, L.
    Pretorius, D.
    Schild, R.
    Sladkevicius, P.
    Timor-Tritsch, I.
    ULTRASCHALL IN DER MEDIZIN, 2012, 33 (02): : 175 - 182
  • [8] Continuous Dual-Isocenter Imaging: Simultaneously Extending the Longitudinal and Lateral Intraoperative 3D CBCT Field-Of-View for Assessing Musculoskeletal Trauma
    Reynolds, T.
    Hatamikia, S.
    Dillon, O.
    Ma, Y.
    Kanawati, A.
    Stayman, J.
    O'Brien, R.
    MEDICAL PHYSICS, 2022, 49 (06) : E601 - E602
  • [9] ANIMATION FOCUS - TO 3D OR NOT TO 3D
    HARBISON, D
    COMPUTER GRAPHICS WORLD, 1987, 10 (07) : 55 - 56
  • [10] Range Reconstruction Model for 3D Gated Imaging
    Tan, ChinSeong
    Chai, TongYuen
    Chua, SingYee
    Wang, Xin
    Goi, BokMin
    Seet, Gerald
    NOVEL OPTICAL SYSTEMS DESIGN AND OPTIMIZATION XVI, 2013, 8842
12345