Wilson Neil E, Elliott Mark A, Nanga Ravi Prakash Reddy, Swago Sophia, Witschey Walter R, Reddy Ravinder
Center for Advanced Metabolic Imaging in Precision Medicine, Department of Radiology, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA, USA.
Department of Bioengineering, School of Engineering and Applied Sciences, University of Pennsylvania, Philadelphia, PA, USA.
medRxiv. 2024 Apr 12:2024.04.09.24305552. doi: 10.1101/2024.04.09.24305552.
This goal of this study was to optimize spectrally selective H MRS methods for large volume acquisition of low concentration metabolites with downfield resonances at 7T and 3T, with particular attention paid to detection of nicotinamide adenine dinucleotide (NAD) and tryptophan.
Spectrally selective excitation was used to avoid magnetization transfer effects with water, and various sinc pulses were compared to a pure-phase E-BURP pulse. Localization using a single slice selective pulse was compared to voxel-based localization that used three orthogonal refocusing pulses, and low bandwidth refocusing pulses were used to take advantage of the chemical shift displacement of water. A technique for water sideband removal was added, and a method of coil channel combination for large volumes was introduced.
Proposed methods were compared qualitatively to previously-reported techniques at 7T. Sinc pulses resulted in reduced water signal excitation and improved spectral quality, with a symmetric, low bandwidth-time product pulse performing best. Single slice localization allowed shorter TEs with large volumes, enhancing signal, while low bandwidth slice selective localization greatly reduced the observed water signal. Gradient cycling helped remove water sidebands, and frequency aligning and pruning individual channels narrowed spectral linewidths. High quality brain spectra of NAD and tryptophan are shown in four subjects at 3T.
Improved spectral quality with higher downfield signal, shorter TE, lower nuisance signal, reduced artifacts, and narrower peaks was realized at 7T. These methodological improvements allowed for previously unachievable detection of NAD and tryptophan in human brain at 3T in under five minutes.
本研究的目的是优化光谱选择性氢磁共振波谱(H MRS)方法,用于在7T和3T磁场下对具有低场共振的低浓度代谢物进行大体积采集,特别关注烟酰胺腺嘌呤二核苷酸(NAD)和色氨酸的检测。
采用光谱选择性激发来避免与水的磁化传递效应,并将各种 sinc 脉冲与纯相位 E - BURP 脉冲进行比较。将使用单个切片选择脉冲的定位与使用三个正交重聚焦脉冲的基于体素的定位进行比较,并使用低带宽重聚焦脉冲来利用水的化学位移。添加了一种去除水边带的技术,并引入了一种用于大体积的线圈通道组合方法。
在7T磁场下,将所提出的方法与先前报道的技术进行了定性比较。sinc 脉冲导致水信号激发减少,光谱质量提高,其中对称的、低带宽 - 时间乘积脉冲表现最佳。单切片定位允许在大体积时使用更短的回波时间(TE),增强了信号,而低带宽切片选择定位大大降低了观察到的水信号。梯度循环有助于去除水边带,频率对齐和修剪单个通道可缩小光谱线宽。展示了3T磁场下四名受试者高质量的NAD和色氨酸脑谱。
在7T磁场下实现了更高的低场信号、更短的TE、更低的干扰信号、更少的伪影和更窄的峰,从而提高了光谱质量。这些方法学上的改进使得在3T磁场下能够在不到五分钟的时间内对人脑中的NAD和色氨酸进行以前无法实现的检测。