Department of Electrical and Electronics Engineering, Bilkent University, Ankara, Turkey.
National Magnetic Resonance Research Center (UMRAM), Bilkent University, Ankara, Turkey.
Med Phys. 2022 Apr;49(4):2590-2601. doi: 10.1002/mp.15509. Epub 2022 Feb 18.
Magnetic particle imaging (MPI) is emerging as a highly promising imaging modality. Magnetic nanoparticles (MNPs) are used as imaging tracers in MPI, and their relaxation behavior provides the foundation for its functional imaging capability. Since MNPs are also utilized in magnetic fluid hyperthermia (MFH) and MPI enables localized MFH, temperature mapping arises as an important application area of MPI. To achieve accurate temperature estimations, however, one must also take into account the confounding effects of viscosity on the MPI signal. In this work, we analyze the effects of temperature and viscosity on MNP relaxation and determine temperature and viscosity sensitivities of relaxation time constant estimations via TAURUS (TAU estimation via Recovery of Underlying mirror Symmetry) at a wide range of operating points to empower simultaneous mapping of these two parameters.
A total of 15 samples were prepared to reach four target viscosity levels (0.9-3.6 mPa s) at five different temperatures (25-45 C). Experiments were performed on a magnetic particle spectrometer (MPS) setup at 60 different operating points at drive field amplitudes ranging between 5 and 25 mT and frequencies ranging between 1 and 7 kHz. To enable these extensive experiments, an in-house arbitrary-waveform MPS setup with temperature-controlled heating capability was developed. The operating points were divided into four groups with comparable signal levels to maximize signal gain during rapid signal acquisition. The relaxation time constants were estimated via TAURUS, by restoring the underlying mirror symmetry property of the positive and negative half cycles of the time-domain MNP response. The relative time constants with respect to the drive field period, , were computed to enable quantitative comparison across different operating points. At each operating point, a linear fit was performed to as a function of each functional parameter (i.e., temperature or viscosity). The slopes of these linear fits were utilized to compute the temperature and viscosity sensitivities of TAURUS.
Except for outlier behaviors at 1 kHz, the following global trends were observed: decreases with drive field amplitude, increases with drive field frequency, decreases with temperature, and increases with viscosity. The temperature sensitivity varies slowly across the operating points and reaches a maximum value of 1.18%/ C. In contrast, viscosity sensitivity is high at low frequencies around 1 kHz with a maximum value of 13.4%/(mPa s) but rapidly falls after 3 kHz. These results suggest that the simultaneous estimation of temperature and viscosity can be achieved by performing measurements at two different drive field settings that provide complementary temperature/viscosity sensitivities. Alternatively, temperature estimation alone can be achieved with a single measurement at drive field frequencies above 3 kHz, where viscosity sensitivity is minimized.
This work demonstrates highly promising temperature and viscosity sensitivities for TAURUS, highlighting its potential for simultaneous estimation of these two environmental parameters via MNP relaxation. The findings of this work reveal the potential of a hybrid MPI-MFH system for real-time monitored and localized thermal ablation treatment of cancer.
磁性粒子成像(MPI)作为一种极具前景的成像方式正在兴起。磁性纳米粒子(MNPs)被用作 MPI 中的成像示踪剂,其弛豫行为为其功能成像能力提供了基础。由于 MNPs 也用于磁流体热疗(MFH),并且 MPI 能够实现局部 MFH,因此温度测绘成为 MPI 的一个重要应用领域。然而,为了实现准确的温度估计,还必须考虑粘度对 MPI 信号的干扰影响。在这项工作中,我们分析了温度和粘度对 MNP 弛豫的影响,并通过 TAURUS(通过恢复底层镜像对称性来估计 TAU)在广泛的工作点范围内确定了弛豫时间常数估计的温度和粘度灵敏度,从而实现这两个参数的同时测绘。
共制备了 15 个样本,以在五个不同温度(25-45°C)下达到四个目标粘度水平(0.9-3.6 mPa s)。在磁场强度幅度为 5-25 mT、频率为 1-7 kHz 的 60 个不同工作点上,在磁粒子光谱仪(MPS)设置上进行了实验。为了实现这些广泛的实验,开发了具有温度控制加热功能的内部任意波形 MPS 设置。将工作点分为四组,每组具有可比的信号水平,以在快速信号采集期间最大限度地提高信号增益。通过 TAURUS 估计弛豫时间常数,通过恢复时域 MNP 响应的正负半周期的底层镜像对称性来恢复。为了能够在不同的工作点之间进行定量比较,计算了相对于驱动场周期的相对时间常数 。在每个工作点上,对作为每个功能参数(即温度或粘度)函数的 进行线性拟合。这些线性拟合的斜率用于计算 TAURUS 的温度和粘度灵敏度。
除了在 1 kHz 处的异常行为外,观察到以下全局趋势: 随驱动场幅度减小,随驱动场频率增大,随温度降低,随粘度增大。温度灵敏度在工作点之间缓慢变化,最大值为 1.18%/°C。相比之下,粘度灵敏度在 1 kHz 左右的低频时较高,最大值为 13.4/(mPa s),但在 3 kHz 后迅速下降。这些结果表明,可以通过在提供互补温度/粘度灵敏度的两个不同驱动场设置下进行测量来实现温度和粘度的同时估计。或者,可以通过在驱动场频率高于 3 kHz 的单个测量来实现单独的温度估计,其中粘度灵敏度最小化。
这项工作展示了 TAURUS 非常有前景的温度和粘度灵敏度,突出了其通过 MNP 弛豫对这两个环境参数进行同时估计的潜力。这项工作的结果揭示了混合 MPI-MFH 系统在癌症实时监测和局部热消融治疗中的潜力。
