Braun Jürgen, Guo Jing, Lützkendorf Ralf, Stadler Jörg, Papazoglou Sebastian, Hirsch Sebastian, Sack Ingolf, Bernarding Johannes
Institute of Medical Informatics, Charité-Universitätsmedizin Berlin, Berlin, Germany.
Department of Radiology, Charité-Universitätsmedizin Berlin, Berlin, Germany.
Neuroimage. 2014 Apr 15;90:308-14. doi: 10.1016/j.neuroimage.2013.12.032. Epub 2013 Dec 22.
Magnetic resonance elastography (MRE) is capable of measuring the viscoelastic properties of brain tissue in vivo. However, MRE is still limited in providing high-resolution maps of mechanical constants. We therefore introduce 3D multifrequency MRE (3DMMRE) at 7T magnetic field strength combined with enhanced multifrequency dual elasto-visco (MDEV) inversion in order to achieve high-resolution elastographic maps of in vivo brain tissue with 1mm(3) resolution. As demonstrated by phantom data, the new MDEV-inversion method provides two high resolution parameter maps of the magnitude (|G*|) and the phase angle (ϕ) of the complex shear modulus. MDEV inversion applied to cerebral 7T-3DMMRE data of five healthy volunteers revealed structures of brain tissue in greater anatomical details than previous work. The viscoelastic properties of cortical gray matter (GM) and white matter (WM) could be differentiated by significantly lower values of |G*| and ϕ in GM (21% [P<0.01]; 8%, [P<0.01], respectively) suggesting that GM is significantly softer and less viscous than WM. In conclusion, 3DMMRE at ultrahigh magnetic fields and MDEV inversion open a new window into characterizing the mechanical structure of in vivo brain tissue and may aid the detection of various neurological disorders based on their effects to mechanical tissue properties.
磁共振弹性成像(MRE)能够在体内测量脑组织的粘弹性特性。然而,MRE在提供高分辨率的力学常数图谱方面仍存在局限性。因此,我们引入了7T磁场强度下的三维多频MRE(3DMMRE),并结合增强型多频双弹性 - 粘弹性(MDEV)反演,以实现分辨率为1mm³的体内脑组织高分辨率弹性成像图谱。如体模数据所示,新的MDEV反演方法提供了复剪切模量的大小(|G*|)和相角(ϕ)的两个高分辨率参数图谱。将MDEV反演应用于五名健康志愿者的脑部7T - 3DMMRE数据,揭示了比以往研究更详细的脑组织解剖结构。通过GM中|G*|和ϕ值显著更低(分别为21% [P<0.01];8%,[P<0.01]),可以区分皮质灰质(GM)和白质(WM)的粘弹性特性,这表明GM比WM明显更软且粘性更小。总之,超高磁场下的3DMMRE和MDEV反演为表征体内脑组织的机械结构打开了一扇新窗口,并可能有助于基于各种神经系统疾病对组织力学特性的影响来检测这些疾病。
