磁铁矿纳米颗粒在交流磁场下的大小依赖性产热肿瘤治疗。

Jun Motoyama, Toshiyuki Hakata, Ryuji Kato, Noriyuki Yamashita, Tomio Morino, Takeshi Kobayashi, Hiroyuki Honda
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引用次数: 53

摘要

背景:我们已经开发了磁性阳离子脂质体(mcl),其中含有磁性纳米颗粒作为加热介质,用于局部热疗。磁性纳米颗粒的加入对微晶复合材料的加热性能有显著影响。我们通过测量其对交变磁场(AMF)辐射的比吸收率(SAR)来估计磁铁矿纳米颗粒的加热能力。方法:将具有不同比表面积(SSA)的磁铁矿纳米颗粒分散在样品管中,进行不同比表面积(AMF)作用,并对其进行sar研究。结果:通过SSA总结了不同AMF条件下磁铁矿颗粒的产热情况。在各频率范围内,局部SAR值在12 ~ 190 m2/g之间均有两个最大值,且随功率的增大而增大。其中一个最大值是在大约90 m2/g的SSA颗粒处观察到的,另一个是在大约120 m2/g的SSA颗粒处观察到的。在110 m2/g的SSA颗粒附近观察到生成热量的SAR的边界值,并且AMF功率对两者的影响是不同的。较小的SSA颗粒的SAR值与AMF功率强度的相关性较强,而较大的SSA颗粒的相关性较弱。结论:两个最大SAR值代表了磁铁矿纳米颗粒的加热机制,即磁滞损失和弛豫损失。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Size dependent heat generation of magnetite nanoparticles under AC magnetic field for cancer therapy.

Size dependent heat generation of magnetite nanoparticles under AC magnetic field for cancer therapy.

Size dependent heat generation of magnetite nanoparticles under AC magnetic field for cancer therapy.

Size dependent heat generation of magnetite nanoparticles under AC magnetic field for cancer therapy.

Background: We have developed magnetic cationic liposomes (MCLs) that contained magnetic nanoparticles as heating mediator for applying them to local hyperthermia. The heating performance of the MCLs is significantly affected by the property of the incorporated magnetite nanoparticles. We estimated heating capacity of magnetite nanoparticles by measuring its specific absorption rate (SAR) against irradiation of the alternating magnetic field (AMF).

Method: Magnetite nanoparticles which have various specific-surface-area (SSA) are dispersed in the sample tubes, subjected to various AMF and studied SAR.

Result: Heat generation of magnetite particles under variable AMF conditions was summarized by the SSA. There were two maximum SAR values locally between 12 m2/g to 190 m2/g of the SSA in all ranges of applied AMF frequency and those values increased followed by the intensity of AMF power. One of the maximum values was observed at approximately 90 m2/g of the SSA particles and the other was observed at approximately 120 m2/g of the SSA particles. A boundary value of the SAR for heat generation was observed around 110 m2/g of SSA particles and the effects of the AMF power were different on both hand. Smaller SSA particles showed strong correlation of the SAR value to the intensity of the AMF power though larger SSA particles showed weaker correlation.

Conclusion: Those results suggest that two maximum SAR value stand for the heating mechanism of magnetite nanoparticles represented by hysteresis loss and relaxation loss.

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