Abstract
In this article, local hyperthermia using core-shell magnetic nanoparticles based on soft and hard magnetic ferrite phases, comprising Zn (0.4)Co (0.6)Fe (2)O (4) @Zn (0.4) Mn (0.6) Fe (2)O (4), under the influence of an AC magnetic field, has been numerically investigated to simulate heat distribution and tumor destruction in liver tissue. It is observed that the dual-phase-lag (DPL) model predicts the maximum temperature lower than both the Pennes bioheat and the single-phase-lag (SPL) model. In addition simulation of temperature distribution over time considering different core-shell nanoparticles in AC magnetic field, has been performed using DPL model. The highest temperature is related to Zn (0.4) Co (0.6) Fe (2)O(4) @Zn (0.4) Mn (0.6) Fe (2)O(4) and the lowest temperature is related to MnFe(2)O(4).We have concluded that these combinations maximize the properties of magnetic nanoparticles and have higher SLP values and more power dissipation of magnetic nanoparticles compared to magnetic nanoparticles of MnFe(2)O (4), MnFe(2)O(4) @ CoFe(2)O(4) and CoFe(2)O(4) @MnFe(2)O4. Two-dimensional temperature distribution simulation over time in liver tissue has been performed using DPL model to quantitatively investigate the tumor temperature in different locations. The results show that temperature curves is a Gaussian-like distribution. The temperature curve is symmetric around the y axis. Temperature is maximum at the center of the tumor and decreases radially outward.