Abstract

Using an open magnet system, we are developing methods for guiding interventional magnetic resonance imaging (IMRI) procedures including thermal ablation. Thermal ablation is minimally invasive and cost effective. Interventional MRI is different from diagnostic MRI, and in our paradigm, minimally invasive treatment of cancer tumors is performed entirely in the MR imager. MRI provides both guidance of the interventional device to the cancer tumor and monitoring the thermal treatment. This is a achieved by exploiting MRI's ability to: 1) generate contrast between tumors, normal tissues, interventional tools and thermal lesions and 2) obtain images at any angle (and dynamically adjusted, like ultrasound, via a localization device). Nonetheless, limitations exist in the current MRI techniques used for guidance, localization and treatment monitoring; unless overcome IMRI will not achieve it's vast potential in minimally invasive diagnostic and cancer treatment procedures. These limitations create a unique opportunity to develop and optimize advanced magnetic imaging pulse sequence techniques which will ultimately improve patient care through more effective IMRI capabilities. The research pursued in this project will create new imaging methods meeting the constraints of the IMRI environment by addressing four primary issues in which IMRI differs from diagnostic MRI (and these must be attained simultaneously): contrast: speed, motion insensitivity and therapy monitoring. In IMRI patient risk is related to time, and so we will create new rapid steady state free precession imaging methods with specific application for IMRI guidance. They will achieve better contrast between tissues and interventional devices than methods presently available for low field dynamic interventional applications. New radial K-space sampling methods which utilize information on the orientation of the interventional device will be designed and evaluated to improve the device tip accuracy and reduce sensitivity to motion artifacts better than 2DFT methods used commonly in IMRI. The most important anatomic locations for local control of primary and metastatic cancer are the liver, brain, kidney, pancreas, head/neck and musculoskeletal system. The research in this application will create customized IMRI methods for these anatomic locations and test them on rabbits (implanted with VX2 in the abdominal organs) and pigs. This project will provide the first systematic study in which low field IMRI techniques are designed by combining the advantages of both the MRI contrast mechanism and K-space sampling scheme together to achieve optimized IMRI methods for each anatomic location; they will offer greater performance than current 2DFT strategies used in virtually all IMRI guided procedures. Further, this project will improve emerging quantitative MR thermal mapping methods and allow attainment of accurate thermal monitoring of IMRI guided thermal cancer therapy. Based on our success to date, the second generation of IMRI guidance strategies will be created.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Cancer Institute (NCI)
Type
Research Project (R01)
Project #
5R01CA081431-03
Application #
6513560
Study Section
Special Emphasis Panel (ZRG1-DMG (04))
Program Officer
Farahani, Keyvan
Project Start
2000-06-01
Project End
2004-05-31
Budget Start
2002-06-01
Budget End
2003-05-31
Support Year
3
Fiscal Year
2002
Total Cost
$294,947
Indirect Cost

  Institution

Name
Case Western Reserve University
Department
Radiation-Diagnostic/Oncology
Type
Schools of Medicine
DUNS #
077758407
City
Cleveland
State
OH
Country
United States
Zip Code
44106

  Publications

Frericks, B B; Elgort, D R; Hillenbrand, C et al. (2009) Magnetic resonance imaging-guided renal artery stent placement in a Swine model: comparison of two tracking techniques. Acta Radiol 50:21-7
Wacker, Frank K; Vogt, Sebastian; Khamene, Ali et al. (2006) An augmented reality system for MR image-guided needle biopsy: initial results in a swine model. Radiology 238:497-504
Moriguchi, Hisamoto; Duerk, Jeffrey L (2006) Bunched phase encoding (BPE): a new fast data acquisition method in MRI. Magn Reson Med 55:633-48
Wacker, Frank K; Hillenbrand, Claudia; Elgort, Daniel R et al. (2005) MR imaging-guided percutaneous angioplasty and stent placement in a swine model comparison of open- and closed-bore scanners. Acad Radiol 12:1085-8
Maes, Robbert M; Lewin, Jonathan S; Duerk, Jeffrey L et al. (2005) Combined use of the intravascular blood-pool agent, gadomer, and carbon dioxide: a novel type of double-contrast magnetic resonance angiography (MRA). J Magn Reson Imaging 21:645-9
Breen, Michael S; Lazebnik, Roee S; Nour, Sherif G et al. (2004) Three-dimensional comparison of interventional MR radiofrequency ablation images with tissue response. Comput Aided Surg 9:185-91
Breen, Michael S; Lazebnik, Roee S; Fitzmaurice, Maryann et al. (2004) Radiofrequency thermal ablation: correlation of hyperacute MR lesion images with tissue response. J Magn Reson Imaging 20:475-86
Nour, Sherif Gamal; Lewin, Jonathan S; Gutman, Michael et al. (2004) Percutaneous MR imaging-guided radiofrequency interstitial thermal ablation of tongue base in porcine models: implications for obstructive sleep apnea syndrome. Radiology 230:359-68
Hwang, Ken-Pin; Flask, Chris; Lewin, Jonathan S et al. (2004) Selective missing pulse steady state free precession (MP-SSFP): inner volume and chemical shift selective imaging in a steady state sequence. J Magn Reson Imaging 19:124-32
Wacker, Frank K; Nour, Sherif G; Eisenberg, Rosana et al. (2004) MRI-guided radiofrequency thermal ablation of normal lung tissue: in vivo study in a rabbit model. AJR Am J Roentgenol 183:599-603

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