PURPOSE: A segmented inversion-recovery module combined with the 2D ultrashort echo time radial technique is proposed that allows accurate pixel level T(1) mapping of mouse lung in vivo. METHODS: Numerical simulations were performed to estimate T(1) measurement accuracy and precision versus flip angle and signal-to-noise ratio. Phantom measurements were used for protocol validation, where the segmented inversion-recovery ultrashort echo-time sequence was compared with the reference technique (inversion-recovery rapid acquisition with refocused echoes). The in vivo experiments were carried out on free-breathing C57 mice (n = 10), breathing first air and then oxygen. RESULTS: The simulations demonstrated the high potential of the technique for accurate and precise T(1) assessment. Phantom experiments showed good agreement for T(1) values measured with segmented inversion-recovery ultrashort echo-time and the reference technique. The in vivo experiment demonstrated the utility of the technique in oxygen-enhanced assessment, where small T(1) changes were detected with high precision. CONCLUSION: Segmented inversion-recovery ultrashort echo-time provides accurate, high resolution T(1) mapping of the lung parenchyma.
PURPOSE: A segmented inversion-recovery module combined with the 2D ultrashort echo time radial technique is proposed that allows accurate pixel level T(1) mapping of mouse lung in vivo. METHODS: Numerical simulations were performed to estimate T(1) measurement accuracy and precision versus flip angle and signal-to-noise ratio. Phantom measurements were used for protocol validation, where the segmented inversion-recovery ultrashort echo-time sequence was compared with the reference technique (inversion-recovery rapid acquisition with refocused echoes). The in vivo experiments were carried out on free-breathing C57 mice (n = 10), breathing first air and then oxygen. RESULTS: The simulations demonstrated the high potential of the technique for accurate and precise T(1) assessment. Phantom experiments showed good agreement for T(1) values measured with segmented inversion-recovery ultrashort echo-time and the reference technique. The in vivo experiment demonstrated the utility of the technique in oxygen-enhanced assessment, where small T(1) changes were detected with high precision. CONCLUSION: Segmented inversion-recovery ultrashort echo-time provides accurate, high resolution T(1) mapping of the lung parenchyma.
Authors: Christian E Anderson; Charlie Y Wang; Yuning Gu; Rebecca Darrah; Mark A Griswold; Xin Yu; Chris A Flask Journal: Magn Reson Med Date: 2017-08-10 Impact factor: 4.668
Authors: Ana L Gomes; Paul Kinchesh; Stuart Gilchrist; Philip D Allen; Luiza Madia Lourenço; Anderson J Ryan; Sean C Smart Journal: PLoS One Date: 2019-02-12 Impact factor: 3.240
Authors: Andreas Boss; Laura Heeb; Divya Vats; Fabian H L Starsich; Alice Balfourier; Inge K Herrmann; Anurag Gupta Journal: NMR Biomed Date: 2022-02-01 Impact factor: 4.478