Your search keyword '"Proton resonance frequency"' showing total 3 results

1. Proton resonance frequency shift-weighted imaging for monitoring MR-guided high-intensity focused ultrasound transmissions

Author

Wen-Shiang Chen, Teng-Yi Huang, Wen-Yih Isaac Tseng, Jyun-Wen Chen, and Hsu-Hsia Peng

Subjects

medicine.medical_specialty, Materials science, Time Factors, Swine, media_common.quotation_subject, medicine.medical_treatment, Phase (waves), Image processing, medicine, Image Processing, Computer-Assisted, Contrast (vision), Animals, Radiology, Nuclear Medicine and imaging, Medical physics, Ultrasonics, media_common, Ultrasonography, Proton resonance frequency, Models, Statistical, Muscles, Temperature, Equipment Design, Magnetic Resonance Imaging, High-intensity focused ultrasound, Magnitude (astronomy), Rabbits, Protons, Energy (signal processing), Temperature mapping, Algorithms, Biomedical engineering

Abstract

Purpose: To combine temperature-related information of phase images and magnitude images acquired from an MR spoiled gradient echo sequence using a postprocessing method referred to as PRF-shift-weighted imaging (PRFSWI). Materials and Methods: Phase images are capable of detecting shifts in proton resonance frequency (PRF) caused by local changes in temperature. Magnitude images provide anatomical information for treatment planning and positioning as well as temperature-related contrast. We used PRFSWI to produce a phase-mask and performed multiplication on the magnitude image to increase temperature-related contrast. Results: Through MRI-guided focused ultrasound (MRIgFUS) experiments (both ex vivo and in vivo), we determined that PRFSWI is capable of enhancing the contrast of a heated area even in the initial stages of transmitting high-intensity focused ultrasound energy. Conclusion: The PRFSWI images are sensitive to changes in temperature and display the heated spot directly in the magnitude images. Although the images do not provide quantitative data related to temperature, this method could be used as a complement to the phase temperature mapping method in the real-time monitoring of MRIgFUS experiments. J. Magn. Reson. Imaging 2011;33:1474–1481. © 2011 Wiley-Liss, Inc.

Published

2011

2. Correction of proton resonance frequency shift temperature maps for magnetic field disturbances using fat signal

Author

Chris J.G. Bakker, Andriy V. Shmatukha, and Paul R. Harvey

Subjects

Models, Anatomic, Swine, Signal, Sensitivity and Specificity, Imaging phantom, Compensation (engineering), Magnetics, Nuclear magnetic resonance, Electromagnetic Fields, Image Processing, Computer-Assisted, Animals, Radiology, Nuclear Medicine and imaging, Spin-½, Physics, Artifact (error), Proton resonance frequency, business.industry, Phantoms, Imaging, Lasers, Temperature, Water, Lipids, Magnetic Resonance Imaging, Margarine, Magnetic field, Liver, Temporal resolution, Calibration, Protons, Nuclear medicine, business, Artifacts

Abstract

Purpose To improve the immunity of the proton resonance frequency shift (PRFS) method of MRI temperature mapping against magnetic field disturbances. Since PRFS is a phase-sensitive method, it misinterprets magnetic field disturbances as artifact temperature changes. If not corrected, the resulting temperature artifacts can completely obscure the true temperature estimation, especially if the temperature elevations are small. Materials and Methods Since the fat protons experience the same magnetic field disturbances as the water protons, but no temperature-related frequency shift, the fat signal has been used for correcting PRFS temperature maps for the disturbances. A simple correction method is proposed that has either better compensation capability than the phase correction methods previously reported or higher spatial and temporal resolution than the spectroscopic correction methods previously reported. The evaluated method is based on the utilization of several gradient and spin echoes acquired within one repetition interval with water- and fat-selective scans. Results In a series of phantom experiments, the improved method is shown to enable the reconstruction of accurate temperature maps in spite of interscan motion, suboptimal fat–water separation, and a wide range of magnetic field disturbances. Conclusion Our approach can be used for the guidance of thermal therapies involving tissues containing fat or surrounded by fat. J. Magn. Reson. Imaging 2007. © 2007 Wiley-Liss, Inc.

Published

2007

3. Multiplanar MR temperature-sensitive imaging of cerebral thermal treatment using interstitial ultrasound applicators in a canine model

Author

Per Daniel Tyreus, Roger E. Price, Will Nau, R. Jason Stafford, Marko Kangasniemi, Donald F. Schomer, John D. Hazle, Lars E. Olsson, and Chris J. Diederich

Subjects

Male, medicine.medical_specialty, Gadolinium, Ultrasonic Therapy, chemistry.chemical_element, Contrast Media, Thermal treatment, Necrosis, Dogs, Imaging, Three-Dimensional, medicine, Animals, Radiology, Nuclear Medicine and imaging, Monitoring, Physiologic, Proton resonance frequency, medicine.diagnostic_test, business.industry, Brain Neoplasms, Echo-Planar Imaging, Ultrasound, Temperature, Brain, Magnetic resonance imaging, Magnetic Resonance Imaging, Coagulative necrosis, chemistry, Feasibility Studies, Temperature sensitive, Radiology, Nuclear medicine, business, Canine model, Neoplasm Transplantation

Abstract

PURPOSE: To study the feasibility of an interleaved gradient-echo, echo-planar imaging (iGE-EPI) sequence for multiplanar magnetic resonance temperature imaging (MRTI) to monitor intracerebral thermal treatment three-dimensionally using multielement ultrasound applicators.MATERIALS AND METHODS: Transmissible venereal tumor (TVT) fragments were injected into the right cerebral hemisphere of five dogs. Guided by MRI, an interstitial ultrasound applicator was inserted into the tumor or normal brain tissue. The iGE-EPI sequence was used to estimate temperature changes by computing the complex phase-difference induced by temperature-dependent shifts in the proton resonance frequency of water. The thermal dose maps were updated every 6-8 seconds for five to seven image planes during treatment. The results of MRTI were compared with those of post-treatment MRI and histologic analysis.RESULTS: The multiplanar MRTI monitored temperature and thermal dose distributions in tumor and normal brain tissue over the entire user-defined treatment volume. The ultrasound applicators produced contiguous areas of coagulative necrosis, resulting in 1.5-4.0 cm(3) volumes of tissue necrosis. MRTI-based assessments of thermal-dose distributions were consistent with the results of post-treatment MRI and histologic analysis.CONCLUSION: Multiplanar MRTI is feasible for measuring necrosing thermal doses during intracerebral thermal delivery by interstitial ultrasound applicators. (Less)

Published

2002