Atsushi M. Takahashi , Jitendra Sharma , David O. Guarin , Julie Miller , Hiroaki Wakimoto , Daniel P. Cahill , Yi-Fen Yen
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引用次数: 0
Abstract
We report several inductively coupled RF coil designs that are very easy to construct, produce high signal-to-noise ratio (SNR) and high spatial resolution while accommodating life support, anesthesia and monitoring in small animals. Inductively coupled surface coils were designed for hyperpolarized 13 C MR spectroscopic imaging (MRSI) of mouse brain, with emphases on the simplicity of the circuit design, ease of use, whole-brain coverage, and high SNR. The simplest form was a resonant loop designed to crown the mouse head for a snug fit to achieve full coverage of the brain with high sensitivity when inductively coupled to a broadband pick-up coil. Here, we demonstrated the coil's performance in hyperpolarized 13 C MRSI of a normal mouse and a glioblastoma mouse model at 4.7 T. High SNR exceeding 70:1 was obtained in the brain with good spatial resolution (1.53 mm x 1.53 mm). Similar inductively coupled loop for other X-nuclei can be made very easily in a few minutes and achieve high performance, as demonstrated in 31 P spectroscopy. Similar design concept was expanded to splitable, inductively coupled volume coils for high-resolution proton MRI of marmoset at 3T and 9.4T, to easily accommodate head restraint, vital-sign monitoring, and anesthesia delivery.
我们报告了几种电感耦合射频线圈设计,它们非常容易构建,产生高信噪比(SNR)和高空间分辨率,同时适用于小动物的生命支持,麻醉和监测。设计了用于小鼠脑超极化13c磁共振成像(MRSI)的电感耦合表面线圈,重点是电路设计简单、易于使用、全脑覆盖和高信噪比。最简单的形式是一个谐振回路,设计在鼠标头的顶部,当电感耦合到宽带拾取线圈时,以高灵敏度实现对大脑的全覆盖。在这里,我们展示了线圈在正常小鼠和胶质母细胞瘤小鼠模型4.7 t的超极化13c磁共振成像中的表现,在大脑中获得了超过70:1的高信噪比,具有良好的空间分辨率(1.53 mm x 1.53 mm)。类似的电感耦合环可以很容易地在几分钟内制成其他x核,并达到高性能,如31 P光谱所示。类似的设计概念被扩展到可分裂的电感耦合容积线圈,用于3T和9.4T的狨猴高分辨率质子MRI,以方便地适应头部约束、生命体征监测和麻醉输送。