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    • 3. 发明申请
    • FAST SPIN ECHO MRI METHOD COMPATIBLE WITH CPMG VIOLATION
    • 快速旋转ECHO MRI方法兼容CPMG暴露
    • US20080009701A1
    • 2008-01-10
    • US11420224
    • 2006-05-25
    • Hector E. AvramJames D. HaleIlya SimovskyDavid M. Kramer
    • Hector E. AvramJames D. HaleIlya SimovskyDavid M. Kramer
    • A61B5/05
    • G01R33/56341G01R33/5608G01R33/5615G01R33/5617G01R33/565G01R33/56509
    • In preferred embodiments, a fast spin echo imaging technique is provided that is insensitive to violations of the Carr Purcell Meiboom Gill (CPMG) condition. Diffusion gradients disrupt the CPMG condition, and, hence, the present fast spin echo method is compatible with diffusion measurements and diffusion weighted imaging. The preferred embodiments of the present technique involve splitting of spin echoes into echo pairs. Spin echoes are split by adjustment (in magnitude or duration) of an initial readout gradient pulse. A train of echo pairs is captured. A first image is constructed using the first echoes of each pair. Also, a second image is constructed using the second echoes of each pair. Hybrid radial Cartesian methods are used for constructing the first and second images. The first and second images are constructed independently of one another. Independent image construction renders the method insensitive to violation of the CPMG condition. Finally, the two images are combined to form a final image.
    • 在优选实施例中,提供了对违反Carr Purcell Meiboom Gill(CPMG)条件不敏感的快速自旋回波成像技术。 扩散梯度破坏CPMG条件,因此,本发明的快速自旋回波方法与扩散测量和扩散加权成像兼容。 本技术的优选实施例涉及将自旋回波分解为回波对。 旋转回波通过初始读数梯度脉冲的调整(幅度或持续时间)分割。 一串回波对被捕获。 使用每对的第一个回波构建第一个图像。 此外,使用每对的第二回波来构建第二图像。 混合径向笛卡尔方法用于构建第一和第二图像。 第一和第二图像彼此独立构建。 独立的图像构造使得方法对违反CPMG条件不敏感。 最后,将两张图像合并形成最终图像。
    • 4. 发明授权
    • Fast spin echo MRI method compatible with CPMG violation
    • 快速自旋回波MRI方法兼容CPMG违规
    • US07538548B2
    • 2009-05-26
    • US11420224
    • 2006-05-25
    • Hector E. AvramJames D. HaleIlya SimovskyDavid M. Kramer
    • Hector E. AvramJames D. HaleIlya SimovskyDavid M. Kramer
    • G01V3/00
    • G01R33/56341G01R33/5608G01R33/5615G01R33/5617G01R33/565G01R33/56509
    • In preferred embodiments, a fast spin echo imaging technique is provided that is insensitive to violations of the Carr Purcell Meiboom Gill (CPMG) condition. Diffusion gradients disrupt the CPMG condition, and, hence, the present fast spin echo method is compatible with diffusion measurements and diffusion weighted imaging. The preferred embodiments of the present technique involve splitting of spin echoes into echo pairs. Spin echoes are split by adjustment (in magnitude or duration) of an initial readout gradient pulse. A train of echo pairs is captured. A first image is constructed using the first echoes of each pair. Also, a second image is constructed using the second echoes of each pair. Hybrid radial Cartesian methods are used for constructing the first and second images. The first and second images are constructed independently of one another. Independent image construction renders the method insensitive to violation of the CPMG condition. Finally, the two images are combined to form a final image.
    • 在优选实施例中,提供了对违反Carr Purcell Meiboom Gill(CPMG)条件不敏感的快速自旋回波成像技术。 扩散梯度破坏CPMG条件,因此,本发明的快速自旋回波方法与扩散测量和扩散加权成像兼容。 本技术的优选实施例涉及将自旋回波分解为回波对。 旋转回波通过初始读数梯度脉冲的调整(幅度或持续时间)分割。 一串回波对被捕获。 使用每对的第一个回波构建第一个图像。 此外,使用每对的第二回波来构建第二图像。 混合径向笛卡尔方法用于构建第一和第二图像。 第一和第二图像彼此独立构建。 独立的图像构造使得方法对违反CPMG条件不敏感。 最后,将两张图像合并形成最终图像。