利用Nd3+离子的发光光谱无创估计激光照射下生物组织加热的局部温度

Q3 Medicine
I. Romanishkin, D. Pominova, P. Grachev, V. Makarov, A. Vanetsev, E. Orlovskaya, A. Baranchikov, I. Sildos, V. Loschenov, Y. Orlovskii, A. Ryabova
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引用次数: 3

摘要

激光热疗是治疗肿瘤疾病的一种很有前途的方法。临床常规应用热疗时,需要控制肿瘤内热的均匀性和局部化。局部加热可以通过使用特殊的热剂来实现,比如掺杂稀土离子的纳米颗粒。热剂温度的测量将允许及时调节所应用的激光辐射激发功率和优化热疗过程。本文介绍了在30 ~ 60°С温度范围内,以0.2%°С-1的灵敏度对掺杂Nd3+的YPO4纳米粒子进行无创伤测定的研究结果。利用805 nm激光激发至4F5/2能态时800 ~ 1000 nm范围内Nd3+的发光光谱计算纳米颗粒的温度。给出了根据玻尔兹曼分布重新计算4F3/2 Nd3+态Stark亚能级发光强度与实际NP温度比值的校准程序。提出了一种计算单个Stark组件发光强度的算法。计算每个单独Stark分量对应的强度后,将4F3/2状态上下两个Stark亚能级转换相关的所有强度相加,然后计算它们的比值。将得到的比率归一化为室温下的比率值,并根据校准相关性重新计算到NP加热温度中。研究表明,所研究的1%Nd3+:YPO4纳米颗粒可以用作“初级”温度计,不需要额外的重新校准来评估用于热疗的温度范围。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
NONINVASIVE ESTIMATION OF THE LOCAL TEMPERATURE OF BIOTISSUES HEATING UNDER THE ACTION OF LASER IRRADIATION FROM THE LUMINESCENCE SPECTRA OF Nd3+ IONS
Laser hyperthermia is one of the promising methods for treatment of oncological diseases. For routine clinical use of hyperthermia, it is necessary to control the uniformity and localization of heat within the tumor. Local heating can be achieved by using special thermal agents, such as nanoparticles doped with rare-earth ions. Measurement of the temperature of the thermal agents will allow timely regulation of the applied laser radiation excitation power and optimization of the hyperthermia process.The paper presents the results of a study on the non-invasive determination of the YPO4 nanoparticles doped with Nd3+ temperature with sensitivity of 0.2% °С-1 in 30-60°С temperature range. The temperature of the nanoparticles was calculated from the Nd3+ luminescence spectra in the 800-1000 nm range under excitation into 4F5/2 energy state by 805 nm laser. A calibration procedure for recalculating the ratio of the luminescence intensities from the Stark sublevels of the 4F3/2 Nd3+ state into the values of the real NP temperature in accordance with the Boltzmann distribution is given. An algorithm for calculating luminescence intensities for individual Stark components is proposed. After calculating the intensities corresponding to each individual Stark component, all the intensities related to the transition from the upper and lower Stark sublevels of the 4F3/2 state are summed, and then their ratio is calculated. The resulting ratio is normalized to the value of the ratio at room temperature and, in accordance with the calibration dependence, is recalculated into the NP heating temperature. It was demonstrated that the investigated 1%Nd3+:YPO4 nanoparticles can be used as "primary” thermometers that do not require additional recalibration to evaluate the temperature in the range used for hyperthermia.
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来源期刊
Biomedical Photonics
Biomedical Photonics Medicine-Surgery
CiteScore
1.80
自引率
0.00%
发文量
19
审稿时长
8 weeks
期刊介绍: The main goal of the journal – to promote the development of Russian biomedical photonics and implementation of its advances into medical practice. The primary objectives: - Presentation of up-to-date results of scientific and in research and scientific and practical (clinical and experimental) activity in the field of biomedical photonics. - Development of united Russian media for integration of knowledge and experience of scientists and practitioners in this field. - Distribution of best practices in laser medicine to regions. - Keeping the clinicians informed about new methods and devices for laser medicine - Approval of investigations of Ph.D candidates and applicants.
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