RU182170U1 - DEVICE FOR EVALUATING THE STATE OF BIOLOGICAL TISSUE IN A SURFACE LAYER - Google Patents

Abstract

The invention relates to the field of laser medicine, namely, devices for assessing the state of biological tissue on the surface or at the depth of the skin or soft tissues. A device for assessing the state of biological tissue in the surface layer contains: a laser radiation source with a wavelength of 700-1000 nm, connected with it an optical fiber for delivering laser radiation, a spectrometer with a fiber optic input of radiation containing a filter, while the spectrometer includes a polychromator, a photodiode array, a recording unit and made with the possibility of connecting to a computer with software, characterized in that it additionally uses a pulsed laser source with a wavelength of 700-1000 nm, an optical fiber connected to it and a probe for delivering laser radiation and receiving a luminescent signal, allowing you to vary the angles and distances between by inputting laser radiation and receiving a luminescent signal, the probe via optical fibers connected to a spectrometer, a laser source with a wavelength of 700-1000 nm and additional Yelnia pulsed laser source with a wavelength of 700-1000 nm.Takim manner an apparatus which allows to assess the biological tissue with different depths, thereby improving diagnostic accuracy and completeness of the diagnostic procedure.

Description

The utility model relates to the field of laser medicine, namely to devices for assessing the state of biological tissue on the surface or at the depth of the skin or soft tissues.

In modern clinical practice, new diagnostic devices are actively used and constantly introduced, using laser radiation to activate photoactive substances and recording luminescent radiation from them.

С, Zyuzin MV, Parak WJ. Luminescent Rare-earth-based Nanoparticles: A Summarized Overview of their Synthesis, Functionalization, and Applications. // Top Curr Chem (Cham). 2016 374(4):48. doi:10.1007/s41061-016-0049-8]. Кристаллы, допированные ионами Nd³⁺ (термо-агенты), имеют спектры люминесценции и поглощения, попадающие как в первое 800-900 нм, так и во второе окно биологической прозрачности 1200-1300 нм [X. Li, R. Wang, F. Zhang, L. Zhou, D. Shen, C. Yao& D. Zhao. Nd³⁺ Sensitized up/down converting dual-mode nanomaterials for efficient in-vitro and in-vivo bioimaging excited at 800 nm, Sci. Rep.3 (2013) 3536. doi:10.1038/srep03536; Z. Wang, P. Zhang, Q. Yuan, X. Xu, P. Lei, X. Liu, Y. Su, L. Dong, J. Feng, and H. Zhang. Nd³⁺-sensitized NaLuF₄ luminescent nanoparticles for multimodal imaging and temperature sensing under 808 nm excitation, Nanoscale. 7-42 (2015) 17861-17870. doi:10.1039/C5NR04889C]. Поэтому диагностические устройства, использующие такие термо-агенты, позволяют производить лазерное возбуждение и регистрацию люминесценции в разных спектральных диапазонах, а также оценивать температуру частиц по интенсивности люминесценции в соответствии с больцмановской заселенностью энергетических уровней.In the last decade, much attention has been paid to inorganic nanoparticles containing rare earth ions, as a promising class of nanomaterials for biophotonics. The advantages of rare-earth ions as luminescent labels consist in narrow-band radiation, a large spectral distance between the wavelengths of excitation and emission, which is characteristic of up-and-down conversion, long luminescence emission time, high photostability of materials and low toxicity, minimal autofluorescence of biotissue the greatest sounding depth upon excitation of nanoparticles in the near infrared region [Escudero A,

C, Zyuzin MV, Parak WJ. Luminescent Rare-earth-based Nanoparticles: A Summarized Overview of their Synthesis, Functionalization, and Applications. // Top Curr Chem (Cham). 2016 374 (4): 48. doi: 10.1007 / s41061-016-0049-8]. The crystals doped with Nd ³⁺ ions (thermo-agents) have luminescence and absorption spectra that fall both in the first 800–900 nm and in the second biological transparency window of 1200–1300 nm [X. Li, R. Wang, F. Zhang, L. Zhou, D. Shen, C. Yao & D. Zhao. Nd ³⁺ Sensitized up / down converting dual-mode nanomaterials for efficient in-vitro and in-vivo bioimaging excited at 800 nm, Sci. Rep. 3 (2013) 3536. doi: 10.1038 / srep03536; Z. Wang, P. Zhang, Q. Yuan, X. Xu, P. Lei, X. Liu, Y. Su, L. Dong, J. Feng, and H. Zhang. Nd ³⁺ -sensitized NaLuF ₄ luminescent nanoparticles for multimodal imaging and temperature sensing under 808 nm excitation, Nanoscale. 7-42 (2015) 17861-17870. doi: 10.1039 / C5NR04889C]. Therefore, diagnostic devices using such thermo-agents allow laser excitation and registration of luminescence in different spectral ranges, as well as estimation of particle temperature by luminescence intensity in accordance with the Boltzmann population of energy levels.

Known devices using high-intensity laser pulses, contributing to a deeper penetration of laser radiation. Spectral changes caused by the laser can be characterized by transient changes in the propagation of light; through tissue, provided that the excited states of these molecules change the absorption spectra. Then, the characteristic of these transitional changes can be used for new mechanisms of photosensitization and / or optimization of photobiological effects. Pogue et al. Measured transmittance and reflection coefficient as a function of laser pulse energy from tissue imitating tissue, as well as in sections of rat muscles and liver, both with and without photosensitizer. A temporary decrease in the absorption of the photosensitizer was observed at peak pulse illumination in the range of 100-1000 W / cm ² .

[Pogue BW, Momma T, Wu HC, Hasan T. Transient absorption changes in vivo during photodynamic therapy with pulsed-laser light. // Br J Cancer. 1999 May; 80 (3-4): 344-51.]

Known devices that allow you to measure the luminescence spectra at a distance from the place of excitation. The depth with which the measurement takes place can vary from 0.5 mm to 2 mm depending on the distance between the irradiation site and the measurement site [Kholodtsova M.N., Grachev P.V., Savelieva T.A., Kalyagina N.A., Blondel W., Loschenov V..B. Scattered and fluorescent photon track reconstruction in a biological tissue. // International Journal of Photoenergy. (2014) doi: 10.1155 / 2014/517510]. The disadvantage of this device is that it uses a wavelength of laser radiation, which is not able to activate thermal agents, and there is no possibility to change the angle between the input of laser radiation and the reception of a luminescent signal.

A device is known that provides a quantitative measurement of the concentration of tumor markers at a point [RF Patent for the invention 2169590 A61N 5/06 2001 - prototype]. This device includes a polychromator in a spectrometer with fiber-optic radiation input, in which a special narrow-band filter, a recording unit, a computer, a laser with a wavelength exceeding 600 nm with a device for inputting laser radiation into a fiber containing a filter are installed. In addition, a continuous spectrum light source containing a transmission filter. A fiber optic catheter including a laser delivery fiber, a continuous spectrum light source, and receiving optical fibers.

The known device allows you to accurately measure the concentration of the tumor marker protoporphyrin IX by bringing the fiber to the zone of interest. The optical fiber is subject to repeated sterilization by standard methods and is used during surgical interventions.

The main disadvantage of the known device is that the depth with which the spectroscopic information is collected is fixed and depends only on the type of biological tissue in which the measurement takes place. And in clinical practice, it is often required to measure both superficial and deeper layers of biological tissue.

The objective of this utility model is to create a device that allows spectroscopic measurements from various depths of biological tissue.

The problem is solved in that a device for assessing the state of biological tissue in the surface layer, including a laser source with a wavelength of 700-1000 nm, an optical fiber for delivering laser radiation connected to it, a spectrometer with a fiber-optic input of radiation containing a filter, this spectrometer includes a polychromator, a photodiode array, a recording unit, and is configured to connect to a computer with software, characterized in that it additionally uses pulsed a laser radiation detector with a wavelength of 700-1000 nm, an optical fiber connected to it, and a probe for delivering laser radiation and receiving a luminescent signal, which allows you to vary the angles and distances between the input of laser radiation and the reception of the luminescent signal, while the probe is connected via optical fibers to spectrometer, a laser source with a wavelength of 700-1000 nm and an additional pulsed laser source with a wavelength of 700-1000 nm.

A device for assessing the state of biological tissue in the surface layer, including a laser radiation source (1) with a wavelength of 700-1000 nm, an optical fiber (2) connected to it for delivering laser radiation, a spectrometer (3) with a fiber-optic input of radiation containing filter (4), while the spectrometer (3) includes a polychromator (5), a photodiode array (6), a recording unit (7), and is configured to connect to a computer (8) with software, characterized in that the pulse is additionally used laser source (9) radiation with a wavelength of 700-1000 nm, an optical fiber connected to it (10), and a probe (11) for delivering laser radiation and receiving a luminescent signal, allowing you to vary the angles and distances between the input of laser radiation and the reception of the luminescent signal, while the probe through optical fibers (12, 2, 10) is connected to a spectrometer (3), a laser radiation source (1) with a wavelength of 700-1000 nm and an additional pulsed laser source (9) with a wavelength of 700-1000 nm.

A device for assessing the state of biological tissue in the surface layer works as follows.

The patient is preliminarily systemically administered a preparation consisting of multifunctional thermo-agents that selectively accumulate in cancer cells. The radiation from the laser source 1 is introduced into the probe for delivering laser radiation and receiving luminescence 11 using an optical fiber 2. A probe for delivering laser radiation and receiving a luminescent signal 11 is mounted above the studied region so that it is in the middle between the point of radiation input and the luminescent signal reception . Check the integrity of the optical fiber for receiving a luminescent signal 12, connected to a probe for delivering laser radiation and receiving a luminescent signal 11 on the one hand, and with a spectrometer 3 with fiber-optic input of radiation on the other hand. Turn on the laser source 1. Make sure that the spectrometer receives a luminescent signal from thermo-agents. If it is necessary to diagnose deeper layers of biological tissue, either increase the distance between the input of laser radiation and the reception of the luminescent signal, or reduce the angle between them. With a significant drop in the luminescent signal, due to the too large distance between the input of the laser radiation and the reception of the luminescent signal, an additional pulsed source of the laser signal 9 is connected using an optical fiber 10 with a probe for delivering laser radiation and receiving the luminescent signal 11. Due to intense short pulses thermal agents located closer to the surface are saturated and cease to absorb radiation from the laser source 1, resulting in radiation e from it excites thermo-agents located more deeply.

Thus, a device is proposed that allows the evaluation of biological tissue from various depths, thereby increasing the diagnostic accuracy and completeness of the diagnostic procedure.

Claims (1)

A device for assessing the state of biological tissue in the surface layer, including a laser source with a wavelength of 700-1000 nm, an optical fiber for delivering laser radiation connected to it, a spectrometer with a fiber optic input of radiation containing a filter, the spectrometer including a polychromator, a photodiode a ruler, a recording unit, and is configured to connect to a computer with software, characterized in that it additionally uses a pulsed laser source with a length of 700-1000 nm, an optical fiber and a probe for delivering laser radiation and receiving a luminescent signal connected to it, allowing you to vary the angles and distances between the input of laser radiation and receiving the luminescent signal, while the probe is connected via optical fibers to a spectrometer, a laser source with wavelength of 700-1000 nm and an additional pulsed source of laser radiation with a wavelength of 700-1000 nm.

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