Study of energy transfer processes between rare earth ions and photosensitizer molecules for photodynamic therapy with IR-excitation

Q3 Medicine
D. Pominova, A. S. Bogatova, V. Proydakova, I. Romanishkin, E. Akhlyustina, S. Kuznetsov, T. A. Saveleva, E. Lukyanets, V. Loschenov
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引用次数: 0

Abstract

Today, photodynamic therapy is one of the most promising minimally invasive methods of treatment of various diseases, including cancer. The main limitation of this method is the insufficient penetration into the tissue of laser radiation used to activate photosensitizer molecules, which makes it difficult to carry out therapy in the treatment of large or deep-seated tumors. In this regard, there is a great interest in the development of new strategies for photodynamic therapy using infrared radiation for excitation, the wavelengths of which fall into the “transparency window” of biological tissues. In this work, it was proposed to use upconversion NaGdF4 :Yb:Er nanoparticles (UCNP), which absorb infrared excitation and serve as a donor that transfers energy to the photosensitizer. Photosens and phthalosens were chosen as the most promising photosensitizers for the study. The aim of this work was to study the energy transfer processes between upconversion nanoparticles doped with rare-earth ions and photosensitizer molecules. in order to excite photosensitizers with IR radiation and carry out photodynamic therapy of deep-seated neoplasms. Using spectroscopic and time-resolved methods, it has been demonstrated that there is an efficient energy transfer between upconversion particles and photosensitizers phthalosens and photosens. The calculated efficiency of energy transfer by the Foerster mechanism was 41% for the UCNP + photosens system and 69% for the UCNP + phthalosens system. It has been experimentally and theoretically proved that there is a binding of photosensitizer molecules with UCNP by means of surfactants, leading to a reduction in the distance between them, due to which effective nonradiative energy transfer is realized. The generation of singlet oxygen by the phthalosens photosensitizer upon excitation by means of energy transfer from UCNP, excited at 980 nm wavelength of, has been demonstrated.
稀土离子与光敏剂分子之间的能量转移过程研究
今天,光动力疗法是治疗包括癌症在内的各种疾病的最有前途的微创方法之一。该方法的主要局限性是用于激活光敏剂分子的激光辐射不能充分渗透到组织中,这使得在治疗大型或深部肿瘤时难以进行治疗。在这方面,人们对开发利用红外辐射进行激发的光动力治疗新策略非常感兴趣,红外辐射的波长落入生物组织的“透明窗口”。在这项工作中,提出了使用上转换的NaGdF4:Yb:Er纳米颗粒(UCNP),它吸收红外激发并作为将能量传递给光敏剂的供体。选择光敏剂和光二苯二酚作为最有前途的光敏剂进行研究。本研究的目的是研究稀土离子掺杂的上转换纳米粒子与光敏剂分子之间的能量传递过程。利用红外辐射激发光敏剂,对深部肿瘤进行光动力治疗。利用光谱和时间分辨方法,已经证明了在上转换粒子和光敏剂酞苯二酚和光敏剂之间存在有效的能量传递。UCNP +光敏系统的福斯特机制计算的能量传递效率为41%,UCNP +苯二酚系统的计算效率为69%。通过实验和理论证明,光敏剂分子通过表面活性剂与UCNP结合,使两者之间的距离减小,从而实现了有效的非辐射能量传递。在980 nm波长激发下,利用UCNP的能量转移,苯二酚光敏剂产生单线态氧。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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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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