Abstract:The magneto acoustic concentration tomography of magnetic nanoparticles (MNPs) with magnetic induction (MACT-MI) represents a novel approach to MNP concentration tomography. However, prior research revealed a limitation: the current MACT-MI yields a weak magneto acoustic signal due to the small magnetic force on MNPs, hindering experimental progress. Our study focuses on gradient magnetic field uniformity to enhance signal-to-noise ratio and imaging quality by designing a high-quality gradient magnetic field coil to amplify the magnetic force of MNPs. An improved gradient coil for MACT-MI is proposed. An intelligent optimization algorithm is incorporated to rectify the correlation error from representing continuous current density through the contour lines of the discrete flow function during the conventional target field method (TFM) coil design. This algorithm defines the fitness function for minimizing relative magnetic field error by optimizing current density coefficients. A gradient coil is produced for various coil spacing requirements in imaging. The proposed TFM coil shows a larger uniform space within the imaging area than the traditional gradient coil. Compared with the matrix coil, the TFM coil reduces the coil count by approximately 30% under equivalent conditions, decreases coil turns by about 65%, minimizes coil size by 84%, and lowers the maximum current by approximately 22%. Additionally, to investigate the influence of gradient magnetic field spatial distribution on MACT-MI, diverse distribution models for magnetic nano particles (MNPs) are constructed. With the multi physics simulation software COMSOL, the physical processes of MACT-MI are numerically solved. Variations in magnetic force and sound pressure acting on MNPs can be analyzed in both uniform and non-uniform magnetic fields. The magnetic force on MNPs exhibits enhanced smoothness and stability in a uniform magnetic field. Conversely, in a non-uniform field, as the gradient magnetic field's uniform space diminishes, the stability range of the magnetic force contracts significantly. Similarly, the sound pressure waveform is broad in a uniform field, accompanied by a wide effective range of sound pressure fluctuations. In contrast, sound pressure curve peaks gradually attenuate as the distance from the center increases in a non-uniform field. The results indicate a proportional relationship between the effective fluctuation range of magnetic force, sound pressure, and the uniform spatial extent of the gradient magnetic field. Moreover, as the uniform space decreases, the peak values of both magnetic force and sound pressure diminish. This phenomenon attests to the impact of the gradient magnetic field's spatial distribution characteristics on the magnitude of magnetic force and sound pressure amplitudes, which also contributes to the relatively weak magnetic-acoustic signals in MACT-MI. Enhancing the uniformity of the magnetic field emerges as apractical approach to bolstering the signal-to-noise ratio of the magnetic-acoustic signals.
闫孝姮, 淡新贤, 陈伟华, 刘方田. 基于改进目标场法梯度线圈的感应式磁声磁粒子浓度成像研究[J]. 电工技术学报, 2024, 39(14): 4305-4316.
Yan Xiaoheng, Dan Xinxian, Chen Weihua, Liu Fangtian. Magneto-Acoustic Magnetic Particle Concentration Imaging Based on Improved Target Field Method Gradient Coil. Transactions of China Electrotechnical Society, 2024, 39(14): 4305-4316.
[1] Shi Xiaoyu, Liu Guoqiang, Yan Xiaoheng, et al.Simulation research on magneto-acoustic concentration tomography of magnetic nanoparticles with magnetic induction[J]. Computers in Biology and Medicine, 2020, 119: 103653. [2] Yan Xiaoheng, Sun Di, Li Zhengxing, et al.Simulation research on the forward problem of magneto-acoustic concentration tomography of magnetic nanoparticles with magnetic induction based on the relaxation time of magnetic nanoparticles[J]. IEEE Access, 2022, 10: 56057-56066. [3] 陈顺中, 王秋良, 孙万硕, 等. 3T动物磁共振成像传导冷却超导磁体研究[J]. 电工技术学报, 2023, 38(4): 879-888. Chen Shunzhong, Wang Qiuliang, Sun Wanshuo, et al.The study of a 3 T conduction-cooled superconducting magnet for animal magnetic resonance imaging[J]. Transactions of China Electrotechnical Society, 2023, 38(4): 879-888. [4] 曲洪一, 刘鑫, 王晖, 等. 磁共振成像磁体无源匀场改进策略及实验研究[J]. 电工技术学报, 2022, 37(24): 6284-6293. Qu Hongyi, Liu Xin, Wang Hui, et al.Improved strategy and experimental research on passive shimming in magnetic resonance imaging magnet[J]. Transactions of China Electrotechnical Society, 2022, 37(24): 6284-6293. [5] 闫孝姮, 李政兴, 潘也, 等. 相同极性永磁体对感应式磁声磁粒子浓度成像过程影响的仿真[J]. 电工技术学报, 2022, 37(8): 1926-1937. Yan Xiaoheng, Li Zhengxing, Pan Ye, et al.Simulation of the influence of permanent magnets of the same polarity on the magneto-acoustic concentration tomography of magnetic nanoparticles with magnetic induction process[J]. Transactions of China Electro-technical Society, 2022, 37(8): 1926-1937. [6] 汤云东, 丁宇彬, 金涛. 基于亥姆霍兹线圈装置的磁热疗优化方法[J]. 电工技术学报, 2023, 38(5): 1248-1260. Tang Yundong, Ding Yubin, Jin Tao.Research on optimization method of magnetic hyperthermia based on Helmholtz coil device[J]. Transactions of China Electrotechnical Society, 2023, 38(5): 1248-1260. [7] 贺红艳, 魏树峰, 王慧贤, 等. 矩阵梯度线圈研究现状与发展趋势[J]. 波谱学杂志, 2021, 38(1): 140-153. He Hongyan, Wei Shufeng, Wang Huixian, et al.Matrix gradient coil: current research status and perspectives[J]. Chinese Journal of Magnetic Resonance, 2021, 38(1): 140-153. [8] 闫孝姮, 李政兴, 孙迪, 等. 基于矩阵式线圈的感应式磁声磁粒子浓度成像研究 (英文)[J]. 电工技术学报, 2022, 37(17): 4269-4283. Yan Xiaoheng, Li Zhengxing, Sun Di, et al.Magneto acoustic concentration tomography of magnetic nanoparticles with magnetic induction based on matrix coil[J]. Transactions of China Electrotechnical Society, 2022, 37(17): 4269-4283. [9] Turner R.A target field approach to optimal coil design[J]. Journal of Physics D: Applied Physics, 1986, 19(8): L147-L151. [10] Liu H, Truwit C L.True energy-minimal and finite-size biplanar gradient coil design for MRI[J]. IEEE Transactions on Medical Imaging, 1998, 17(5): 826-830. [11] Forbes L K, Crozier S.Novel target-field method for designing shielded biplanar shim and gradient coils[J]. IEEE Transactions on Magnetics, 2004, 40(4): 1929-1938. [12] Chen Shanshan, Xia Tian, Miao Zhiying, et al.Active shimming method for a 21.3 MHz small-animal MRI magnet[J]. Measurement Science and Technology, 2017, 28(5): 055902. [13] Wang Jing, Song Xinda, Zhou Weiyong, et al.Hybrid optimal design of biplanar coils with uniform magnetic field or field gradient[J]. IEEE Transactions on Industrial Electronics, 2021, 68(11): 11544-11553. [14] Zhao Fengwen, Wang Jing, Lu Fei, et al.Design of highly linear gradient field coils based on an improved target-field method[J]. IEEE Sensors Journal, 2021, 21(14): 16256-16263. [15] Ding Zhongya, Huang Ziyuan, Pang Maotong, et al.Iterative optimization algorithm to design biplanar coils for dynamic magnetoencephalography[J]. IEEE Transactions on Industrial Electronics, 2023, 70(2): 2085-2094. [16] Tomasi D.Stream function optimization for gradient coil design[J]. Magnetic Resonance in Medicine, 2001, 45(3): 505-512. [17] Peeren G N.Stream function approach for determining optimal surface currents[J]. Journal of Computational Physics, 2003, 191(1): 305-321. [18] Brideson M A, Forbes L K, Crozier S.Determining complicated winding patterns for shim coils using stream functions and the target-field method[J]. Concepts in Magnetic Resonance: an Educational Journal, 2002, 14(1): 9-18. [19] Liu Wentao, Zu Donglin, Tang Xin, et al.Target-field method for MRI biplanar gradient coil design[J]. Journal of Physics D: Applied Physics, 2007, 40(15): 4418-4424. [20] Mirjalili S, Lewis A.The whale optimization algo-rithm[J]. Advances in Engineering Software, 2016, 95(C): 51-67. [21] Hu Gang, He Bin.Magnetoacoustic imaging of magnetic iron oxide nanoparticles embedded in biological tissues with microsecond magnetic stimu-lation[J]. Applied Physics Letters, 2012, 100(1): 13704-137043.
2024, Vol. 39 
