RU2786481C1 - Method for manufacturing a laser fiber scalpel with a temperature-stabilized thermo-optical tip - Google Patents

Abstract

FIELD: medical technology.

SUBSTANCE: invention relates to medical technology, in particular to methods for manufacturing laser devices, and can be used for the production of laser scalpels used in surgery or therapy, the principle of operation of which is based on thermal exposure. The claimed method for manufacturing a laser fiber scalpel with a temperature stabilized thermo-optical tip includes applying an optically absorbing material to the distal end of the fiber light guide, annealing the tip by briefly heating it to a temperature below the ablation temperature of the absorbing material, maintaining a predetermined temperature level of the tip during operation of the laser fiber scalpel. Moreover, after annealing, the tip is heated to the ablation temperature of the material, stabilization of heat release on the layer of absorbing material is achieved by maintaining the process of ablation of this material, thereby maintaining the specified temperature level of the tip at the level of the ablation temperature during operation of the laser fiber scalpel.

EFFECT: development of a method for manufacturing a laser fiber scalpel that provides a stable temperature of the thermo-optical tip during operation without the use of additional temperature control and regulation systems.

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Description

The invention relates to medical technology, in particular to methods for manufacturing laser devices, and can be used for the production of laser scalpels used in surgery or therapy, the principle of operation of which is based on thermal exposure.

An important aspect of the effectiveness of oncosurgery is the choice of an adequate instrument for resection and the method of its use. On the one hand, the selected instrument must comply with the principles of ablastics, and on the other hand, it must allow the operation to be performed quickly enough and not impair the possibility of subsequent diagnostics of the surgical field. The thermally damaged layer resulting from the laser scalpel is important for creating a bloodless incision. Its large size leads to inflammation and poor healing, so it must be optimal. The size of the incision depends on the laser resection technique, on the radiation parameters, on the angle of the scalpel to the surface, etc. Minimization of surgical trauma determines the degree of preservation of the function of the organ and, thus, the level of quality of life of the patient, and the degree of radical removal of the tumor determines the possibility of continued growth and/or recurrence of the process.

At the moment, it is believed that laser surgery has survived the stage of research into exposure modes and has become a medical technology. To create an even bloodless seam, the same size of the coagulation zone is needed, which depends on the stable temperature value of the cutting part of the quartz fiber. Temperature measurement under cutting conditions is hampered by locality (fiber diameter 400-550 µm), scattering of biotissue and carbonization of biotissue during the cutting process. Attempts to organize feedback on the radiation power, and thus stabilize the temperature, did not lead to clinical application. Recently, new theoretical models of laser resection of tumors have begun to appear, with the help of which it has become possible to understand the physical principles of the process and determine the optimal radiation parameters.

According to patent RU 2586847 "Laser fiber scalpel with a thermo-optical tip and method for its manufacture" (published on June 10, 2016, IPC A61V 18/22), a method for manufacturing a laser fiber scalpel is known, including blackening the output end of the fiber light guide by applying the prepared colloidal powder solution graphite in organosilicon varnish on the end face and on the adjacent cylindrical part (~0.5 mm) of the optical fiber, which makes it possible to maintain a high temperature on it for a long time due to the absorption of optical laser radiation by it. The method also includes drying and checking the quality of the applied coating. This patent describes a method for manufacturing a fiber scalpel with a thermo-optical tip without the possibility of maintaining a certain temperature level of this tip during operation.

According to US patent 6015404 "Laser dermatology with feedback control") (publ. 01/18/2000, IPC A61B 18/20, A61B 18/00) a method and device for laser dermatology is known. In the proposed method, the temperature level of the epidermis, which is affected by a laser pulse, is controlled, preventing the threshold level from being exceeded due to feedback and control of the power and duration of the pulse. However, this method is applicable only to the repetitively pulsed mode, while most laser surgical devices also have a continuous mode of radiation.

As a prototype, a method for manufacturing a laser surgical scalpel described in US patent 8956343 "Dental surgical laser with feedback mechanisms" (published on February 17, 2015, IPC A61B 18/20) was chosen. A known method for manufacturing a thermo-optical tip includes obtaining an optical tip from an optically transparent material, applying an optically absorbing material to the distal end of a fiber light guide, and annealing the tip by applying laser power to the tip. Maintaining a predetermined temperature level of the tip during operation of the scalpel is carried out by automatically adjusting the laser power.

The disadvantage of this method is the need for constant monitoring and regulation of the tip temperature during operation, which is carried out using a feedback system. This solution complicates the design and increases its cost. Also, the disadvantage of the proposed method is the complex calibration of the feedback system, depending on the degree of modification of the biological tissue, which undergoes several phase transitions under the influence of temperature, the backscattering spectrum changes.

The problem to be solved by the proposed invention is the development of a method for manufacturing a laser fiber scalpel that provides a stable temperature of the thermo-optical tip during operation without the use of additional temperature control and regulation systems.

The technical result in the proposed method for manufacturing a laser fiber scalpel with a stabilized temperature of the thermo-optical tip is achieved due to the fact that it, like the prototype method, includes applying an optically absorbing material to the distal end of the optical fiber, annealing the tip by briefly heating it to a temperature below the ablation temperature absorbing material, maintaining a predetermined temperature level of the tip during operation of the laser fiber scalpel. What is new in the proposed method is that after annealing the tip is heated to the ablation temperature of the material, stabilization of heat release on the layer of absorbing material is achieved by maintaining the ablation process of this material, thereby maintaining the specified temperature level of the tip at the level of the ablation temperature during operation of the laser fiber scalpel.

The invention is illustrated in the following figures.

In FIG. 1 schematically shows a fiber light guide with a layer of optically absorbing material deposited on its end face.

In FIG. Figure 2 shows the time dependences of the temperature of the thermooptical tip, measured experimentally (dots) and calculated using the model (lines) for various laser radiation powers: a) for a power of 3 W and 4 W, b) for a power of 5 W and 6 W.

In FIG. Figure 3 shows the dependences of the optical density of the tip material on time, calculated using the model for various laser radiation powers: a) for powers of 3 W and 4 W, b) for powers of 5 W and 6 W.

In FIG. Figure 4 shows the dependences of the temperature of the optically absorbing material on time, calculated using the model, in the following approximations: points - taking into account all types of losses, thin solid lines - taking into account only ablation, thick solid line - taking into account only losses due to radiation and heat exchange with the environment a) for power 3 W and 4 W, b) for power 5 W and 6 W.

The method is carried out as follows.

According to the developed method, a layer of optically absorbing material is applied to the distal end of the optical fiber by immersing the stripped end of the optical fiber in a small amount of this material. The fiber is then briefly heated to a temperature below the ablation temperature of the absorbing material, which makes it possible to fix this material on the fiber and obtain a thermo-optical tip.

In a particular case, a mixture of microparticles of pyrotechnic coal and organosilicon varnish was used as an absorbing material. The absorption coefficient of the coating was measured and amounted to 1200 cm ^-1 .

After annealing, the tip is heated to the ablation temperature of the material, stabilization of heat release on the layer of absorbing material is achieved by maintaining the ablation process of this material, thereby maintaining the specified temperature level of the tip at the level of the ablation temperature during operation of the laser fiber scalpel.

A theoretical model describing the process of tip temperature stabilization as a result of absorbing material ablation is described in the article ((Investigation of the Effect of Temperature Stabilization in Radiation-Heat Converters Based on a Strong Absorbing Coating” (authors Natalia Sapogova, Vladimir Bredikhin, Andrey Afanasiev, Vladislav Kamensky and Nikita Bityurin, published October 2, 2021), where the problem of heat propagation in an optical fiber with a layer of optically absorbing material deposited on the end is considered. Laser radiation passing through the absorbing layer heats it. The model takes into account that with sufficient heating the material of the strongly absorbing layer will evaporate.Reducing the thickness of the absorbing layer leads to a decrease in the heating that occurs due to the absorption of radiation.Calculations show how the temperature in the system will change as a result of these processes for various radiation powers.

поглощающего слоя бесконечно малой величиной. Будем считать, что вещество поглощающего слоя однородно и толщина

слоя сохраняется одинаковой на всей площади торца волокна.The following model was used to solve the problem: in a cylindrical coordinate system (z, r, ϕ), a semi-infinite cylindrical fiber of radius R is considered, located along the positive direction of the z axis (see Fig. 1). The point r=0 coincides with the center of the fiber. The end of the fiber is at the point z=0. The material of the light guide is considered homogeneous. It is believed that the problem is homogeneous in the azimuthal angle cp. At the end of the optical fiber at the point z=0 there is a strongly absorbing layer; when solving the problem, we will consider the thickness

absorbing layer is infinitely small. We will assume that the substance of the absorbing layer is homogeneous and the thickness

layer remains the same over the entire area of the end face of the fiber.

The absorption coefficient deposited on the end of the fiber strongly absorbing layer at a wavelength of laser diode radiation λ=965 nm was measured, and amounted to α _sAc =1200 cm ^-1 . The absorption coefficient of the fiber material is approximately 10 ^-2 cm ^-1 , which is significantly less than the absorption of the layer material, so the absorption of laser radiation directly in the fiber is neglected, considering it optically transparent.

на коэффициент поглощения α_sAC, также меняется от эксперимента к эксперименту. Для каждого отдельного эксперимента величина оптической плотности в начальный момент времени задавалась в соответствии с наблюдающимися в эксперименте данными. Коэффициент поглощения α_sac в ходе испарения слоя предполагается неизменным. Изменение оптической плотности сильно поглощающего слоя представлено на фиг. 3а, б. Для мощностей 4 Вт и 5 Вт также приведены по две кривые. Как видно из данных графиков, независимо от оптической толщины поглощающего слоя в начальный момент времени при нагреве в ходе абляции вещества оптическая плотность уменьшается и достигает некоторого уровня, который слабо зависит от мощности лазерного излучения. Например, на фиг. 3б представлены две зависимости оптической плотности от времени для мощности 5 Вт: несмотря на различную оптическую плотность в начале эксперимента, со временем в обоих случаях оптическая плотность начинает совпадать. Поскольку оптическая плотность пропорциональна толщине поглощающего слоя, то очевидно, что начальная толщина слоя не влияет на итоговую толщину, которая устанавливается в ходе нагрева поглощающего слоя в течение ~ 5 сек.Within the framework of this model, the dependences of the temperature of a strongly absorbing layer on the irradiation time were plotted for different laser radiation powers. For powers of 4 W and 5 W, the experiment was carried out twice, so the graphs show two sets of data for these powers. The obtained curves were compared with the available experimental data (see Fig. 2a, b). When comparing, it was taken into account that in the course of the experiment, a strongly absorbing layer was applied anew each time, and the initial thickness of the layer could vary from experiment to experiment. Accordingly, at the initial moment of time, the optical density of the absorbing layer D, which is equal to the product of the layer thickness

on the absorption coefficient α _sAC also varies from experiment to experiment. For each individual experiment, the value of the optical density at the initial moment of time was set in accordance with the data observed in the experiment. The absorption coefficient α _sac is assumed to be unchanged during the evaporation of the layer. The change in optical density of the highly absorbing layer is shown in Fig. 3a, b. For powers of 4 W and 5 W, two curves are also shown. As can be seen from these graphs, regardless of the optical thickness of the absorbing layer at the initial moment of time, upon heating during ablation of the substance, the optical density decreases and reaches a certain level, which weakly depends on the laser radiation power. For example, in FIG. Figure 3b shows two dependences of the optical density on time for a power of 5 W: despite the different optical density at the beginning of the experiment, over time, in both cases, the optical density begins to coincide. Since the optical density is proportional to the thickness of the absorbing layer, it is obvious that the initial thickness of the layer does not affect the final thickness, which is established during the heating of the absorbing layer for ~ 5 sec.

As can be seen from the data of Fig. 2a, b and fig. 3a and 3b, the radiation power used to heat the end of the fiber with the optically absorbing material deposited on it, as well as the initial thickness of the layer of this material, have little effect on the set temperature of the end of the fiber. With an increase in the heating of the strongly absorbing layer due to an increase in the power of the absorbed radiation or an increase in the thickness of the layer, the material of the layer begins to evaporate faster. Reducing the thickness of the absorbing layer, in turn, reduces further heating efficiency and leads to a decrease in the temperature of the absorbing layer. As a result of this self-regulation process, the temperature of the fiber tip reaches a value of the order of 2000 K a few seconds (~5 sec) after the laser is turned on, regardless of the laser radiation power or the initial thickness of the absorbing layer.

The article also considers how significant the role of the process of ablation of a strongly absorbing layer in the process of temperature stabilization is. To do this, the change in the temperature of the absorbing layer and its optical density is calculated in cases where: the system does not take into account losses for radiation and heat exchange with the environment, losses for ablation are taken into account; and the system takes into account only losses due to radiation and heat exchange with air, the layer does not evaporate. The calculation results are shown in Fig. 4. It can be seen from these data that the evaporation of the substance of the absorbing layer plays a fundamental role in the process of temperature stabilization. Radiation and heat transfer do not significantly affect the change in the temperature of the absorbing layer, while in the absence of ablation, the temperature curves have a fundamentally different character.

The time dependence of the temperature of the end of an optical fiber with a strongly absorbing layer deposited on it during irradiation of the fiber with a cw laser is experimentally studied. It is found that, in a certain range of laser power, the temperature dynamics weakly depends on the value of this power. In this case, the temperature reaches an almost stationary plateau.

Thus, the claimed method of manufacturing a laser fiber scalpel makes it possible to ensure a stable temperature of the thermo-optical tip of the scalpel during operation without the use of additional temperature control and adjustment systems.

Claims (1)

A method for manufacturing a laser fiber scalpel with a stabilized temperature of a thermo-optical tip, which includes applying an optically absorbing material to the distal end of the fiber light guide, annealing the tip by briefly heating it to a temperature below the ablation temperature of the absorbing material, maintaining a predetermined temperature level of the tip during operation of the laser fiber scalpel, characterized in that that after annealing the tip is heated to the ablation temperature of the material, stabilization of heat release on the layer of absorbing material is achieved by maintaining the process of ablation of this material, thereby maintaining the specified temperature level of the tip at the level of the ablation temperature during operation of the laser fiber scalpel.

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