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时间分割多重复合用于在超高场与有限的射频频道的并行传输.

Felix Glang1,2, Georgiy A Solomakha1, Dario Bosch1,3,4

  • 1Magnetic Resonance Center, Max Planck Institute for Biological Cybernetics, Tübingen, Germany.

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概括
此摘要是机器生成的。

时间分割复杂化使8个射频频道能够在超高场MRI中实现16个频道的并行传输性能. 这种方法提高了全脑激发的均性,使先进的线圈阵列可以使用更少的通道.

关键词:
一个RF开关,一个RF开关.这就是为什么SAR SAR SAR.翻转角度的一致性 翻转角度的一致性高场核磁共振 (MRI) 是一种高场核磁共振.多重复杂的多重复杂.

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科学领域:

  • 磁共振成像是一种磁共振成像技术.
  • 射频线圈技术 射频线圈技术
  • 生物医学工程 生物医学工程

背景情况:

  • 超高波段 (UHF) MRI 系统需要先进的并行传输 (pTx) 技术来实现均的射频激发.
  • 在MRI系统中,有限的射频通道限制了多元件发射线圈阵列的性能.
  • 优化射频激发对于高场MRI的诊断准确性和安全性至关重要.

研究的目的:

  • 在超高频MRI中研究pTx的时间分割复杂化 (TDM).
  • 通过使用有限数量的射频通道来实现均的全脑刺激.
  • 将TDM性能与RF线圈阵列的同时传输进行比较.

主要方法:

  • 开发了一种快速的射频开关,以路线8传输通道到9.4T的16元线圈阵列.
  • 实现了TDM,用于使用kT点脉冲进行并行传输.
  • 研究了SAR监测和SAR意识脉冲设计方法.
  • 对TDM与同时传播的激发均性和局部SAR进行比较.

主要成果:

  • 通过使用只有8个通道,TDM实现了与16个传输通道相比的激发保真度.
  • 多重复合将翻转角度不均性降低了高达2.22倍.
  • TDM需要更长的脉冲持续时间或更高的幅度,可能会增加局部SAR.
  • 具有SAR意识的脉冲设计有效控制了多重化诱导的SAR增加.

结论:

  • 时间分割复杂化通过使更多的传输元件能够使用更少的射频通道来提高并行传输性能.
  • 在有限的RF通道可用性的情况下,TDM为MRI系统中使用先进的多行传输线圈阵列提供了可行的解决方案.
  • 这种技术在资源有限的环境中扩大了高性能MRI的可能性.