测量小鼠胚胎的血流量

O. Aristizábal, D. A. Christopher, F. Foster, D. H. Turnball
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引用次数: 2

摘要

广泛的遗传信息和最近引入的转基因基因操作技术使小鼠成为正常心脏发育和先天性心脏病的公认模型。这一领域进展的一个障碍是缺乏评估胚胎心血管结构和功能的非侵入性技术。作者开发了一种高频(40-50 MHz)超声成像和多普勒系统,可以在体内分析小鼠早期胚胎心血管发育。可以无创地同时获得实时图像和多普勒数据,从而首次测量小鼠胚胎心脏的流入和流出特征以及脐带循环中的血流。高分辨率(测量的横向分辨率=60-100 /spl mu/m)图像用于定位多普勒换能器的样本量。40 MHz连续多普勒系统使用一对安装在SMB连接器上的气背LiNbO/sub 3/传感器,并使用10至300 mm/s的弦模进行校准,速度与胚胎心血管血液波形相关。在正常10天的小鼠胚胎(大约相当于4周的人)中测量双相流入波形,峰值血流速度接近200 mm/s。同一胚胎的流出速度接近70 mm/s,而脐动脉流速约为20 mm/s。未来的研究将比较正常速度数据与心脏和胎盘有特定缺陷的突变小鼠的测量结果。
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Measuring blood flow in the mouse embryo
Extensive genetic information and the recent introduction of transgenic techniques for genetic manipulation have made the mouse the accepted model for normal cardiac development and congenital heart disease. An impediment to progress in this area has been the lack of noninvasive technologies to assess embryonic cardiovascular structure and function. The authors have developed a high frequency (40-50 MHz) ultrasound imaging and Doppler system enabling in vivo analysis of early embryonic cardiovascular development in the mouse. Simultaneous real-time image and Doppler data can be obtained noninvasively allowing, for the first time, measurements to be made of inflow and outflow characteristics of the mouse embryo heart and blood flow in the umbilical circulation. High resolution (measured lateral resolution=60-100 /spl mu/m) images are used to position the sample volume of the Doppler transducers. The 40 MHz CW Doppler system utilizes a pair of air backed LiNbO/sub 3/ transducers mounted on SMB connectors, and has been calibrated with a string phantom from 10 to 300 mm/s, velocities relevant to embryonic cardiovascular blood waveforms. Biphasic inflow waveforms were measured in normal 10 day mouse embryos (approximately equivalent to 4 weeks human) with peak blood velocities close to 200 mm/s. Outflow velocities in the same embryos were close to 70 mm/s while umbilical artery velocities were approximately 20 mm/s. Future studies will compare normal velocity data to measurements of mutant mice with specific defects in heart and placenta.
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