K. Kuroda, Shuhei Morita, M. K. Lam, M. Obara, P. Baron, W. Bartels, Masatoshi Honda, T. Horie, Y. Imai
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A phantom with two mayonnaise tubes,one heated by microwave while the other kept at room temperature was imaged at 3 Tesla during the cooling process by a spoiled gradient recalled acquisition in steady state (SPGR)of the following conditions;field of view,32 × 32 cm (cid:50892) ;matrix,64 × 64;parallel imaging factor, 2;repetition time,36 ms;echo time spacing,1.15 ms;and flip angles,20,50 and 70 degrees. Signals obtained with each flip angle were processed by IDEAL(Iterative Decomposition of water and fat with Echo Asymmetry and Least squares estimation)algorithm to obtain H (cid:50877) O,CH (cid:50877) and CH (cid:50878) images. The smaller components of fat were ignored for simplicity. Temperature distribution of fat in the phantom was imaged by T (cid:50876) of CH (cid:50877) obtained from the three CH (cid:50877) images with different flip angles,while that of water with the change in the phase difference between H (cid:50877) O and CH (cid:50877) or the relative phase change in H (cid:50877) O. Those temperature images were then fused as a weighted sum of H (cid:50877) O and CH (cid:50877) fractions in each voxel. The resultant images highly correlated with the probe-measured temperature elevation demonstrating that simultaneous fat-water temperature imaging is feasible and is expected to be sufficient for clinical practice. . The other study evaluated the stability of the water-fat chemical shifts using line scan echo planar spectroscopic imaging(LSEPSI) (cid:50896)(cid:50903) . The deviation of the results demonstrated that the water-fat PRF difference is not a useful indicator for breast temperature. Moreover,both water and fat contents have to be high enough in this type of spectroscopic technique. These studies were conducted at relatively low magnetic field(0.5-1.5T)aiming at observation of total fat signal without separating the fatty acid components.","PeriodicalId":23299,"journal":{"name":"Thermal Medicine","volume":null,"pages":null},"PeriodicalIF":0.0000,"publicationDate":"2012-12-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"3","resultStr":"{\"title\":\"Feasibility of Noninvasive Magnetic Resonance Temperature Imaging of Fat and Water Based on Methylene Proton Spin-lattice Relaxation Time and Water Proton Resonance Frequency\",\"authors\":\"K. Kuroda, Shuhei Morita, M. K. Lam, M. Obara, P. Baron, W. Bartels, Masatoshi Honda, T. Horie, Y. 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引用次数: 3
摘要
提出了一种用于脂肪-水混合组织的无创磁共振温度成像技术。该技术利用脂肪亚甲基链(CH (cid:50877))质子的自旋-晶格弛驰时间(T (cid:50876))和水质子(H (cid:50877) O)的共振频移对温度的依赖关系,采用多点Dixon法结合多翻转角法,可以同时计算CH (cid:50877)的T (cid:50876)和H (cid:50877) O的共振频移另一组在室温下保存,在3特斯拉的冷却过程中通过破坏梯度回忆采集(SPGR)在以下条件下成像:视场为32 × 32 cm (cid:50892),矩阵为64 × 64,平行成像因子为2,重复时间为36 ms,回波时间间隔为1.15 ms,翻转角度为20、50和70度。利用IDEAL(Iterative Decomposition of water and fat with Echo asymmetric and Least squares estimation)算法对各翻转角度得到的信号进行处理,得到H (cid:50877) O、CH (cid:50877)和CH (cid:50878)图像。为了简单起见,忽略了脂肪的较小成分。通过三张不同翻转角度的CH (cid:50877)图像得到的CH (cid:50876)的T (cid:50876)来成像幻体中脂肪的温度分布,通过H (cid:50877) O和CH (cid:50877)的相位差变化或H (cid:50877) O的相对相位变化来成像水的温度分布。然后将这些温度图像融合为每个体素中H (cid:50877) O和CH (cid:50877)分量的加权和。所得图像与探针测量的温度高度相关,表明同时进行脂肪-水温成像是可行的,并有望用于临床实践。另一项研究利用线扫描回波平面光谱成像(LSEPSI) (cid:50896)(cid:50903)评估了水-脂肪化学位移的稳定性。结果的偏差表明,水-脂肪PRF差不是乳房温度的有用指标。此外,在这种光谱技术中,水和脂肪的含量都必须足够高。这些研究是在相对较低的磁场(0.5-1.5T)下进行的,目的是在不分离脂肪酸组分的情况下观察总脂肪信号。
Feasibility of Noninvasive Magnetic Resonance Temperature Imaging of Fat and Water Based on Methylene Proton Spin-lattice Relaxation Time and Water Proton Resonance Frequency
:A noninvasive magnetic resonance temperature imaging technique for fat-water mixed tissues was proposed. This technique uses the temperature dependence of the spin-lattice relaxation time( T (cid:50876) ) of protons originated from methylene chain(CH (cid:50877) )of fat as well as the resonance frequency shift of water proton(H (cid:50877) O). A multiple point Dixon method in conjunction with a multiple flip angle method enables simultaneous calculation of T (cid:50876) of CH (cid:50877) and the resonance frequency change of H (cid:50877) O. A phantom with two mayonnaise tubes,one heated by microwave while the other kept at room temperature was imaged at 3 Tesla during the cooling process by a spoiled gradient recalled acquisition in steady state (SPGR)of the following conditions;field of view,32 × 32 cm (cid:50892) ;matrix,64 × 64;parallel imaging factor, 2;repetition time,36 ms;echo time spacing,1.15 ms;and flip angles,20,50 and 70 degrees. Signals obtained with each flip angle were processed by IDEAL(Iterative Decomposition of water and fat with Echo Asymmetry and Least squares estimation)algorithm to obtain H (cid:50877) O,CH (cid:50877) and CH (cid:50878) images. The smaller components of fat were ignored for simplicity. Temperature distribution of fat in the phantom was imaged by T (cid:50876) of CH (cid:50877) obtained from the three CH (cid:50877) images with different flip angles,while that of water with the change in the phase difference between H (cid:50877) O and CH (cid:50877) or the relative phase change in H (cid:50877) O. Those temperature images were then fused as a weighted sum of H (cid:50877) O and CH (cid:50877) fractions in each voxel. The resultant images highly correlated with the probe-measured temperature elevation demonstrating that simultaneous fat-water temperature imaging is feasible and is expected to be sufficient for clinical practice. . The other study evaluated the stability of the water-fat chemical shifts using line scan echo planar spectroscopic imaging(LSEPSI) (cid:50896)(cid:50903) . The deviation of the results demonstrated that the water-fat PRF difference is not a useful indicator for breast temperature. Moreover,both water and fat contents have to be high enough in this type of spectroscopic technique. These studies were conducted at relatively low magnetic field(0.5-1.5T)aiming at observation of total fat signal without separating the fatty acid components.