Dazai Jun, Spring Shoshana, Cahill Lindsay S, Henkelman R Mark
Mouse Imaging Centre, Hospital for Sick Children.
J Vis Exp. 2011 Feb 27(48):2497. doi: 10.3791/2497.
The field of mouse phenotyping with magnetic resonance imaging (MRI) is rapidly growing, motivated by the need for improved tools for characterizing and evaluating mouse models of human disease. MRI is an excellent modality for investigating genetically altered animals. It is capable of whole brain coverage, can be used in vivo, and provides multiple contrast mechanisms for investigating different aspects of neuranatomy and physiology. The advent of high-field scanners along with the ability to scan multiple mice simultaneously allows for rapid phenotyping of novel mutations. Effective mouse MRI studies require attention to many aspects of experiment design. In this article, we will describe general methods to acquire quality images for mouse phenotyping using a system that images mice concurrently in shielded transmit/receive radio frequency (RF) coils in a common magnet (Bock et al., 2003). We focus particularly on anatomical phenotyping, an important and accessible application that has shown a high potential for impact in many mouse models at our imaging centre. Before we can provide the detailed steps to acquire such images, there are important practical considerations for both in vivo brain imaging (Dazai et al., 2004) and ex vivo brain imaging (Spring et al., 2007) that should be noted. These are discussed below.
受改进人类疾病小鼠模型表征和评估工具需求的推动,利用磁共振成像(MRI)进行小鼠表型分析的领域正在迅速发展。MRI是研究基因改变动物的一种出色方式。它能够覆盖整个大脑,可用于活体成像,并提供多种对比机制以研究神经解剖学和生理学的不同方面。高场扫描仪的出现以及同时扫描多只小鼠的能力使得新型突变的快速表型分析成为可能。有效的小鼠MRI研究需要关注实验设计的许多方面。在本文中,我们将描述使用一种在普通磁体中通过屏蔽发射/接收射频(RF)线圈同时对小鼠成像的系统,获取用于小鼠表型分析的高质量图像的一般方法(博克等人,2003年)。我们特别关注解剖学表型分析,这是一个重要且易于实现的应用,在我们的成像中心,它已在许多小鼠模型中显示出产生重大影响的巨大潜力。在我们能够提供获取此类图像的详细步骤之前,对于活体脑成像(大宰等人,2004年)和离体脑成像(斯普林等人,2007年)都有一些重要的实际考虑因素需要注意。以下将对此进行讨论。
