He Kaiyan, Wan Shuangai, Sheng Jingwei, Liu Dongsu, Wang Chune, Li Dongxu, Qin Lang, Luo Shen, Qin Jie, Gao Jia-Hong
Beijing City Key Lab for Medical Physics and Engineering, Institution of Heavy Ion Physics, School of Physics, Peking University, Beijing 100871, China.
Beijing Automation Control Equipment Institute, Beijing 100074, China.
Rev Sci Instrum. 2019 Jun;90(6):064102. doi: 10.1063/1.5066250.
The rapid development of the optically pumped magnetometer (OPM) has offered a much more flexible method for magnetoencephalography (MEG). Without using liquid helium and its associated dewar device in the OPM detectors, the large and expensive magnetically shielded room (MSR) for traditional MEG systems could be replaced by a compact shield. In the present work, an economic and compact cylindrical shield was designed and built to meet the low-field working requirement of the OPM in detecting human brain neuronal activities. The performance of the compact shield was evaluated and further compared with that of a commercial MSR. Our results showed that the residual magnetic fields and background noise of the compact shield were lower than or comparable to those of the MSR. The remnant field in the shield is found to be 4.2 nT, a factor of 13 000 smaller than the geomagnetic field which is applied to the transverse direction of the shield, and the longitudinal shielding factors measured using a known alternating-current magnetic field are approximately 191, 205, and 3130 at 0.1 Hz, 1 Hz, and 10 Hz, respectively; in addition, the evoked dynamic waveforms in the human auditory cortex that were recorded separately in these two shields demonstrated consistency. Our findings suggested that a compact shield is feasible for OPM-based MEG applications with high performance and low cost.
光泵磁力仪(OPM)的快速发展为脑磁图(MEG)提供了一种更加灵活的方法。由于OPM探测器中不使用液氦及其相关的杜瓦瓶装置,传统MEG系统中庞大且昂贵的磁屏蔽室(MSR)可以被一个紧凑的屏蔽装置所取代。在本研究中,设计并建造了一个经济紧凑的圆柱形屏蔽装置,以满足OPM检测人类大脑神经元活动时的低场工作要求。对该紧凑屏蔽装置的性能进行了评估,并与商用MSR的性能进行了进一步比较。我们的结果表明,紧凑屏蔽装置的剩余磁场和背景噪声低于或与MSR相当。发现屏蔽装置中的剩余磁场为4.2 nT,比施加在屏蔽装置横向的地磁场小13000倍,并且使用已知交变磁场测量的纵向屏蔽因子在0.1 Hz、1 Hz和10 Hz时分别约为191、205和3130;此外,在这两个屏蔽装置中分别记录的人类听觉皮层诱发动态波形显示出一致性。我们的研究结果表明,紧凑屏蔽装置对于基于OPM的高性能、低成本MEG应用是可行的。