MRI evidence of endolymphatic impermeability to the gadolinium molecule in the in vivo mouse inner ear at 9.4 tesla.

Q4 Medicine
Open Neuroimaging Journal Pub Date : 2013-06-28 Print Date: 2013-01-01 DOI:10.2174/1874440001307010027
S Allen Counter, Sahar Nikkhou, Stefan Brené, Peter Damberg, Adam Sierakowiak, Tomas Klason, Cecilia Engmér Berglin, Göran Laurell
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引用次数: 9

Abstract

Objective: Previous in vivo experimental magnetic resonance imaging (MRI) investigations of the mammalian inner ear at 4.7 Tesla have indicated that intravenously injected gadolinium (Gd) penetrates the perilymphatic labyrinth, but not the endolymphatic membranous labyrinth. In the present study, high field MRI at 9.4T was used to visualize the in vivo mouse vestibulo-cochlea system, and to determine whether the endolymphatic system is permeable to a Gd complex.

Methods: A 9.4 T Varian magnet equipped with a 12 cm inner diameter gradient system with maximum gradient strength of 600 mT/m, a millipede coil (Varian design) and a Gd contrast agent were used for image acquisition in the normal C57 BL-6 mouse.

Results: High-resolution 2D and 3D images of the mouse cochlea were acquired within 80 minutes following intravenous injection of Gd. Gd initially permeated the perilymphatic scala tympani and scala vestibuli, and permitted visualization of both cochlear turns from base to apex. The superior, inferior and lateral semicircular canals were subsequently visualized in 3 planes. The membranous endolymphatic labyrinth was impermeable to intravenously injected Gd, and thus showed no apparent uptake of Gd at 9.4T.

Conclusion: The 9.4T field strength MRI permitted acquisition of high resolution images of anatomical and physiological features of the normal, wild type mouse perilymphatic inner ear in vivo, and provided further evidence that the endolymphatic system is impermeable to intravenously injected Gd.

Abstract Image

Abstract Image

Abstract Image

9.4特斯拉时小鼠内耳内淋巴对钆分子不渗透性的MRI证据。
目的:先前对哺乳动物内耳4.7特斯拉的体内实验磁共振成像(MRI)研究表明,静脉注射钆(Gd)可以穿透淋巴周围迷路,但不能穿透淋巴内膜迷路。在本研究中,使用9.4T高场MRI可视化小鼠体内前庭-耳蜗系统,并确定内淋巴系统是否可渗透Gd复合物。方法:采用9.4 T瓦里安磁体,内径12 cm梯度系统,最大梯度强度600 mT/m,千足虫线圈(瓦里安设计)和Gd造影剂对正常C57 BL-6小鼠进行图像采集。结果:静脉注射Gd后80分钟内获得小鼠耳蜗高分辨率二维和三维图像。Gd最初渗透到淋巴周围的中耳膜和前庭鳞片,并允许从基部到尖端的两个耳蜗旋转的可视化。上半规管、下半规管和外侧半规管在3个平面上可见。膜性淋巴内迷路对静脉注射的Gd是不渗透的,因此在9.4T时没有明显的Gd摄取。结论:9.4T场强MRI可获得正常野生型小鼠淋巴周围内耳体内解剖和生理特征的高分辨率图像,并进一步证明淋巴内系统对静脉注射Gd是不渗透的。
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来源期刊
Open Neuroimaging Journal
Open Neuroimaging Journal Medicine-Radiology, Nuclear Medicine and Imaging
CiteScore
0.70
自引率
0.00%
发文量
3
期刊介绍: The Open Neuroimaging Journal is an Open Access online journal, which publishes research articles, reviews/mini-reviews, and letters in all important areas of brain function, structure and organization including neuroimaging, neuroradiology, analysis methods, functional MRI acquisition and physics, brain mapping, macroscopic level of brain organization, computational modeling and analysis, structure-function and brain-behavior relationships, anatomy and physiology, psychiatric diseases and disorders of the nervous system, use of imaging to the understanding of brain pathology and brain abnormalities, cognition and aging, social neuroscience, sensorimotor processing, communication and learning.
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