Threshold heating temperature for magnetic hyperthermia: Controlling the heat exchange with the blocking temperature of magnetic nanoparticles

Pimentel B.; Caraballo-Vivas R. J.; Checca N. R.; Zverev V. I.; Salakhova R. T.; Makarova L. A.; Pyatakov A. P.; Perov N. S.; Tishin A. M.; Shtil A. A.; Rossi A. L.; Reiss M. S.

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Threshold heating temperature for magnetic hyperthermia: Controlling the heat exchange with the blocking temperature of magnetic nanoparticles

机译：磁体热疗的阈值加热温度：控制磁性纳米粒子的阻塞温度的热交换

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La0.75Sr0.25MnO3 nanoparticles with average diameter close to 20.9 nm were synthesized using a sol-gel method. Measurements showed that the heating process stops at the blocking temperaturesignificantly below the Curie temperature. Measurements of Specific Absorption Rate (SAR) as a function of AC magnetic field revealed a superquadratic power law, indicating that, in addition to usual Neel and Brown relaxation, the hysteresis also plays an important role in the mechanism of heating. The ability to control the threshold heating temperature, a low remanent magnetization and a low field needed to achieve the magnetic saturation are the advantages of this material for therapeutic magnetic hyperthermia.

机译：使用溶胶 - 凝胶法合成La0.75Sr0.25mNO3平均直径接近20.9nm的纳米颗粒。测量结果表明，加热过程在低于居里温度的温度下堵塞。作为AC磁场的函数的特定吸收率（SAR）的测量揭示了一种超级化的电力法，表明除了通常的NEEL和棕色松弛之外，滞后还在加热机制中起着重要作用。控制阈值加热温度的能力，低再伸缩磁化和实现磁饱和度所需的低场是该材料用于治疗磁体热疗的优点。

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来源
《Journal of Solid State Chemistry 》 |2018年第2018期| 共5页
作者
Pimentel B.; Caraballo-Vivas R. J.; Checca N. R.; Zverev V. I.; Salakhova R. T.; Makarova L. A.; Pyatakov A. P.; Perov N. S.; Tishin A. M.; Shtil A. A.; Rossi A. L.; Reiss M. S.;
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Fluminense Fed Univ Phys Inst Av Gal Milton Tavares Souza S-N BR-24210346 Niteroi RJ Brazil;

Fluminense Fed Univ Phys Inst Av Gal Milton Tavares Souza S-N BR-24210346 Niteroi RJ Brazil;

Fluminense Fed Univ Phys Inst Av Gal Milton Tavares Souza S-N BR-24210346 Niteroi RJ Brazil;

Moscow MV Lomonosov State Univ Fac Phys Moscow 119991 Russia;

Moscow MV Lomonosov State Univ Fac Phys Moscow 119991 Russia;

Moscow MV Lomonosov State Univ Fac Phys Moscow 119991 Russia;

Moscow MV Lomonosov State Univ Fac Phys Moscow 119991 Russia;

Moscow MV Lomonosov State Univ Fac Phys Moscow 119991 Russia;

Moscow MV Lomonosov State Univ Fac Phys Moscow 119991 Russia;

Moscow MV Lomonosov State Univ Blokhin Natl Med Ctr Oncol Moscow 119991 Russia;

Brazilian Ctr Res Phys Rua Dr Xavier Sigaud 150 BR-22290180 Rio De Janeiro RJ Brazil;

Fluminense Fed Univ Phys Inst Av Gal Milton Tavares Souza S-N BR-24210346 Niteroi RJ Brazil;

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正文语种 eng
中图分类物理化学（理论化学）、化学物理学 ;
关键词
Magnetic nanoparticles; Hyperthermia; Self-controlled inductive heating; Self-regulating magnetic hyperthermia;

机译：磁性纳米粒子;热疗;自控感应加热;自我调节磁体热疗;

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专利

1. Threshold heating temperature for magnetic hyperthermia: Controlling the heat exchange with the blocking temperature of magnetic nanoparticles [J] . Pimentel B., Caraballo-Vivas R. J., Checca N. R., Journal of Solid State Chemistry . 2018 ,第期

机译：磁体热疗的阈值加热温度：控制磁性纳米粒子的阻塞温度的热交换
2. Preparation of La_(2/3)Sr_(1/3)Mn_(1-x)Cu_xO_(3)Perovskite Ceramics forTemperature-self-controlled Magnetic Hyperthermia Mediators andEstimates of their Heating Ability under Alternating Magnetic Fields [J] . Mayumi Horiki, Takashi Nakagawa, Tomohiro Yoshioka, Journal of the Magnetics Society of Japan . 2011 ,第1期

机译：La_（2/3）Sr_（1/3）Mn_（1-x）Cu_xO_（3）钙钛矿陶瓷的制备用于温度自控磁热疗器和交变磁场下的加热能力估算
3. Preparation of La_(2/3)Sr_(1/3)Mn_(1-x)Cu_xO_(3)Perovskite Ceramics forTemperature-self-controlled Magnetic Hyperthermia Mediators andEstimates of their Heating Ability under Alternating Magnetic Fields [J] . Mayumi Horiki, Takashi Nakagawa, Tomohiro Yoshioka, Journal of the Magnetics Society of Japan . 2011 ,第1期

机译：La_（2/3）Sr_（1/3）Mn_（1-x）Cu_xO_（3）钙钛矿陶瓷的钙钛矿陶瓷在交替磁场下的加热能力及其加热能力恒温
4. Multifunctional upconversion nanoparticles based on NaYGdF4 for laser induced heating, non-contact temperature sensing and controlled hyperthermia with use of pulsed periodic laser excitation [C] . Daria V. Pominova, Anastasia V. Ryabova, Igor D. Romanishkin, SPIE Conference on Optical Technologies in Biophysics and Medicine . 2018

机译：基于NAYGDF4的多功能上转换纳米粒子用于激光诱导加热，非接触温度传感和控制热疗，采用脉冲周期激光激发
5. Adaptive real-time closed-loop temperature control for ultrasound hyperthermia using magnetic resonance thermometry [D] . Sun, Lei 2004

机译：利用磁共振测温法对超声热疗进行自适应实时闭环温度控制
6. Magnetic Heating of Nanoparticles: The Importance of Particle Clustering to Achieve Therapeutic Temperatures [O] . John Pearce, Andrew Giustini, Robert Stigliano, -1

机译：纳米粒子的电磁加热：达到治疗温度的粒子团簇的重要性
7. Estimation of Specific Power Loss of Heating Mediator (La-Sr-Mn-Cu perovskite) for Magnetic Hyperthermia under 1 MHz Magnetic Field at Different Temperatures [O] . H. Kado, T. Nakagawa, S. Seino, 2015

机译：不同温度下1 MHz磁场下磁体热疗的热介质（La-SR-Mn-Cu钙钛矿）特定功率丧失的估计

Threshold heating temperature for magnetic hyperthermia: Controlling the heat exchange with the blocking temperature of magnetic nanoparticles

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