The Whitaker Biomedical Engineering Institute at Johns Hopkins University School of Medicine, Baltimore 21205, Maryland, USA.
J Cereb Blood Flow Metab. 2011 Jul;31(7):1623-36. doi: 10.1038/jcbfm.2011.17. Epub 2011 Mar 9.
Abnormal vascular phenotypes have been implicated in neuropathologies ranging from Alzheimer's disease to brain tumors. The development of transgenic mouse models of such diseases has created a crucial need for characterizing the murine neurovasculature. Although histologic techniques are excellent for imaging the microvasculature at submicron resolutions, they offer only limited coverage. It is also challenging to reconstruct the three-dimensional (3D) vasculature and other structures, such as white matter tracts, after tissue sectioning. Here, we describe a novel method for 3D whole-brain mapping of the murine vasculature using magnetic resonance microscopy (μMRI), and its application to a preclinical brain tumor model. The 3D vascular architecture was characterized by six morphologic parameters: vessel length, vessel radius, microvessel density, length per unit volume, fractional blood volume, and tortuosity. Region-of-interest analysis showed significant differences in the vascular phenotype between the tumor and the contralateral brain, as well as between postinoculation day 12 and day 17 tumors. These results unequivocally show the feasibility of using μMRI to characterize the vascular phenotype of brain tumors. Finally, we show that combining these vascular data with coregistered images acquired with diffusion-weighted MRI provides a new tool for investigating the relationship between angiogenesis and concomitant changes in the brain tumor microenvironment.
异常的血管表型与从阿尔茨海默病到脑肿瘤等多种神经病理学有关。此类疾病的转基因小鼠模型的发展,对描述鼠类神经脉管系统提出了迫切需求。虽然组织学技术非常适合以亚微米分辨率对微血管成像,但它们的覆盖范围有限。在组织切片后,重建三维(3D)脉管系统和其他结构,如白质束,也极具挑战性。在这里,我们描述了一种使用磁共振显微镜(μMRI)对鼠类整个大脑脉管系统进行 3D 映射的新方法,以及它在一种临床前脑肿瘤模型中的应用。通过六个形态学参数来描述 3D 血管结构:血管长度、血管半径、微血管密度、单位体积长度、血容量分数和迂曲度。感兴趣区域分析表明,肿瘤与对侧大脑之间以及接种后第 12 天和第 17 天肿瘤之间的血管表型存在显著差异。这些结果明确表明,使用 μMRI 来描述脑肿瘤的血管表型是可行的。最后,我们表明,将这些血管数据与与扩散加权 MRI 获得的配准图像相结合,为研究血管生成与脑肿瘤微环境同时发生的变化之间的关系提供了一种新工具。