PURPOSE: To present a three-dimensional (3D) segmented echoplanar imaging (EPI) pulse sequence implementation that provides simultaneously the proton resonance frequency shift temperature of aqueous tissue and the longitudinal relaxation time (T1 ) of fat during thermal ablation. METHODS: The hybrid sequence was implemented by combining a 3D segmented flyback EPI sequence, the extended two-point Dixon fat and water separation, and the double flip angle T1 mapping techniques. High-intensity focused ultrasound (HIFU) heating experiments were performed at three different acoustic powers on excised human breast fat embedded in ex vivo porcine muscle. Furthermore, T1 calibrations with temperature in four different excised breast fat samples were performed, yielding an estimate of the average and variation of dT1 /dT across subjects. RESULTS: The water only images were used to mask the complex original data before computing the proton resonance frequency shift. T1 values were calculated from the fat-only images. The relative temperature coefficients were found in five fat tissue samples from different patients and ranged from 1.2% to 2.6%/°C. CONCLUSION: The results demonstrate the capability of real-time simultaneous temperature mapping in aqueous tissue and T1 mapping in fat during HIFU ablation, providing a potential tool for treatment monitoring in organs with large fat content, such as the breast.
PURPOSE: To present a three-dimensional (3D) segmented echoplanar imaging (EPI) pulse sequence implementation that provides simultaneously the proton resonance frequency shift temperature of aqueous tissue and the longitudinal relaxation time (T1 ) of fat during thermal ablation. METHODS: The hybrid sequence was implemented by combining a 3D segmented flyback EPI sequence, the extended two-point Dixon fat and water separation, and the double flip angle T1 mapping techniques. High-intensity focused ultrasound (HIFU) heating experiments were performed at three different acoustic powers on excised human breast fat embedded in ex vivo porcine muscle. Furthermore, T1 calibrations with temperature in four different excised breast fat samples were performed, yielding an estimate of the average and variation of dT1 /dT across subjects. RESULTS: The water only images were used to mask the complex original data before computing the proton resonance frequency shift. T1 values were calculated from the fat-only images. The relative temperature coefficients were found in five fat tissue samples from different patients and ranged from 1.2% to 2.6%/°C. CONCLUSION: The results demonstrate the capability of real-time simultaneous temperature mapping in aqueous tissue and T1 mapping in fat during HIFU ablation, providing a potential tool for treatment monitoring in organs with large fat content, such as the breast.
Authors: Martin Blaimer; Felix A Breuer; Nicole Seiberlich; Matthias F Mueller; Robin M Heidemann; Vladimir Jellus; Graham Wiggins; Lawrence L Wald; Mark A Griswold; Peter M Jakob Journal: J Magn Reson Imaging Date: 2006-08 Impact factor: 4.813
Authors: R Jason Stafford; Roger E Price; Chris J Diederich; Marko Kangasniemi; Lars E Olsson; John D Hazle Journal: J Magn Reson Imaging Date: 2004-10 Impact factor: 4.813
Authors: Sara M Sprinkhuizen; Chris J G Bakker; Johannes H Ippel; Rolf Boelens; Max A Viergever; Lambertus W Bartels Journal: MAGMA Date: 2011-04-12 Impact factor: 2.310
Authors: Floortje M Knuttel; Sèvrin E M Huijsse; Talitha L Feenstra; Chrit T W Moonen; Maurice A A J van den Bosch; Erik Buskens; Marcel J W Greuter; Geertruida H de Bock Journal: J Ther Ultrasound Date: 2017-08-01