通过动物和人体的水和脂肪抑制质子投影 MRI(WASPI)对骨基质进行体内成像。
Bone matrix imaged in vivo by water- and fat-suppressed proton projection MRI (WASPI) of animal and human subjects.
机构信息
Department of Orthopaedic Surgery, Children's Hospital, Boston, Massachusetts 02115, USA.
出版信息
J Magn Reson Imaging. 2010 Apr;31(4):954-63. doi: 10.1002/jmri.22130.
Abstract
PURPOSE
To demonstrate water- and fat-suppressed proton projection MRI (WASPI) in a clinical scanner to visualize the solid bone matrix in animal and human subjects.
MATERIALS AND METHODS
Pig bone specimens and polymer pellets were used to optimize the WASPI method in terms of soft-tissue suppression, image resolution, signal-to-noise ratio, and scan time on a 3T MRI scanner. The ankles of healthy 2-3-month-old live Yorkshire pigs were scanned with the optimized method. The method was also applied to the wrists of six healthy adult human volunteers to demonstrate the feasibility of the WASPI method in human subjects. A transmit/receive coil built with proton-free materials was utilized to produce a strong B(1) field. A fast transmit/receive switch was developed to reduce the long receiver dead time that would otherwise obscure the signals.
RESULTS
Clear 3D WASPI images of pig ankles and human wrists, showing only the solid bone matrix and other tissues with high solid content (eg, tendons), with a spatial resolution of 2.0 mm in all three dimensions were obtained in as briefly as 12 minutes.
CONCLUSION
WASPI of the solid matrix of bone in humans and animals in vivo is feasible.
摘要
目的
在临床扫描仪上展示水脂抑制质子投影 MRI(WASPI),以可视化动物和人体研究对象的固体骨基质。
材料和方法
使用猪骨标本和聚合物颗粒,在 3T MRI 扫描仪上针对软组织抑制、图像分辨率、信噪比和扫描时间优化 WASPI 方法。对健康的 2-3 月龄活体约克夏猪的踝关节进行了优化方法的扫描。该方法还应用于六名健康成年人类志愿者的手腕,以证明 WASPI 方法在人体研究对象中的可行性。利用无质子材料制成的发射/接收线圈产生强 B(1)场。开发了快速发射/接收开关,以减少否则会使信号模糊的长接收器死时间。
结果
在 12 分钟内即可获得猪踝关节和人手腕的清晰 3D WASPI 图像,仅显示固体骨基质和其他固体含量高的组织(例如肌腱),所有三个维度的空间分辨率均为 2.0 毫米。
结论
在体内对人和动物的骨固体基质进行 WASPI 是可行的。
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