RU2153866C1 - Device for photothermocryotherapy and method for its use - Google Patents

Abstract

FIELD: medicine, in particular, devices and methods for photothermocryotherapy used at physiotherapeutic influence. SUBSTANCE: device has an actuator carrying a set of thermoelectric coolers and a set of radiators with a radiation wavelength within 0.5 to 1.6 μm and average radiation power within 0.00005 to 2 W. The device has also power supplies of the thermoelectric coolers and radiators, microcontroller connected to the control members and respective control inputs of the programmed commutators of the radiators, photosensors, temperature-sensitive elements and thermoelectric coolers. The method for use of the device provides for installation of the photothermocryotherapy actuator on the biotissue, and, depending on the purpose of therapy and the extension of the region of biotissue, photothermocryotherapy is accomplished at a fixed position of the actuator, and/or by slow rotary-translational motions of the actuator. Preliminarily set is the condition of synchronization of radiation of the radiators with thermo- and cryo-effects. The frequency of radiation pulses is selected within 0 to 10 kHz, the duration of thermo- and cryo-effect is set within 30 s to 30 min, the number of cycles being up to 100. Depending on the specific technique of influence, the temperature of the side of the thermoelectric cooler facing the biotissue is set within -20 to +70 C. EFFECT: enhanced efficiency of therapeutic action due to the increase of the expansion wall and narrowing of microvessels. 3 cl, 2 dwg, 3 ex

Description

 The invention relates to medicine, namely to devices and methods for photothermocryotherapy used in physiotherapy.

 A device is known for thermo- and cryotherapy at acupuncture points (SU 797686 A), in which a thermoelectric cooler is used as a source of thermo- and cryotherapy.

 Due to the design (the small area of the acting element intended for contact with the acupuncture point), the devices do not allow thermo- and cryotherapy of extended areas of biological tissues.

 A device is known, considered as a prototype, in the form of a fixing bandage; (SU 1674834 A1), in which a set of thermoelectric coolers connected via a switch to a power source, as well as a temperature sensor, is installed on the acting element.

 As a result of local thermal or cryogenic action on the biological tissue, the expansion or narrowing of the blood microvasculature in the affected area occurs, respectively. Alternating cyclical changes in the operating mode of the acting element from heating to cooling increases the efficiency of thermo- and cryotherapy and thermocryomassage. The thermoelectric dressing provides for work only in a fixed position, which does not allow thermocryomassage of extended areas of biological tissues.

 It should be noted that under the influence of low-intensity laser and incoherent radiation of LEDs within the spectral range of 0.5 ... 1.6 μm, the dilation of arterioles occurs, and the veins of the microvasculature are already at the 1st ... 10th minute, depending on the power of photo-exposure to biological tissue (Kozlov V.I., Builin V.A., et al. "Fundamentals of laser physical and reflexotherapy", Samara-Kiev, 1993, p. 60).

 The technical result of the invention is to increase the efficiency of therapeutic thermal and cryogenic effects on biological tissue by increasing the degree of expansion and contraction of microvessels, anti-pain, anti-inflammatory, immunostimulating and other biological effects, by combining exposure to biological tissue with elevated and lowered temperatures using a thermoelectric cooler and phototherapeutic radiation.

 The technical result is ensured by the fact that in the device for photothermocryotherapy containing an acting element on which a set of thermoelectric coolers is connected, connected through a switch to a power source of thermoelectric coolers, and temperature sensors, the switch of thermoelectric coolers is connected to a microcontroller, the output of which is connected to the control input of the power source thermoelectric coolers, additionally the microcontroller is connected to the controls and the corresponding the control inputs of the emitter power supply, a programmable emitter switch connected to a set of emitters, a programmable switch of photosensitive sensors connected to them, a programmable switch of temperature sensors connected to them, and to the indicator input, a set of emitters is mounted on a water element and is made with a radiation wavelength from 0.5 to 1.6 microns and an average radiation power in the range from 0.00005 to 2 watts.

In addition, thermoelectric coolers can be made with the possibility of installing on their surface the effects of temperatures in the range from -20 ^o C to +70 ^o C, the modulation frequency of the emitters can be from 0 to 10 kHz.

In the method of photothermocryotherapeutic exposure using the inventive device for photothermocryotherapy, which consists in placing an actiating element on a biotissue with a set of thermoelectric coolers and carrying out thermo- and cryotherapy, they additionally carry out photo-exposure with a set of emitters on the acting element, and the synchronization mode of radiation of emitters with thermo and cryotherapy, in which the average radiation power is from 0.00005 to 2 W with a length of emission wavelengths in the range from 0.5 to 1.6 μm, the frequency of radiation pulses is selected from 0 to 10 kHz, the duration of thermal and / or cryotherapy in one cycle is set in the range from 30 s to 30 min, with the number of cycles up to 100 and the temperature of the thermoelectric cooler from the side of the biological tissue is set from -20 ^o C to +70 ^o C, while the effect is carried out at a fixed position of the element by the position of the acting element and by its slow rotational-translational movements on the impact area.

 Thermoelectric coolers and emitters have an arbitrary shape and are located in the acting element relative to each other in the order determined by the therapeutic task.

 Thermoelectric coolers in the acting element are controlled by a microcontroller according to individual programs (the heating and cooling mode of each of the thermoelectric coolers based on the acting element is set individually for each thermo-cryocycle of the acting element).

 On the surface of the thermoelectric cooler facing the biological tissue, interchangeable nozzles made of a material with high thermal conductivity (copper, aluminum, etc.) can be installed, which allows them to be disinfected after removal from the device; and also temperature sensors (thermistors or other semiconductor devices) are installed.

 Temperature sensors are designed to monitor the temperature from the thermoelectric cooler facing the surface of the biological tissue (as well as the temperature of the replaceable nozzles) when choosing the temperature necessary for photothermocryotherapy.

 To effectively remove heat from the opposite tissue side of the thermoelectric cooler, an additional radiator and / or fan can be used. To obtain the lowest (high) temperature of the thermoelectric cooler side, a cascade connection of thermoelectric coolers is implemented.

 When using a thermoelectric cooler, structurally made with a hole in the middle, a radiator (s) and (or) an optical cable are installed inside this hole through which radiation is supplied to the biological tissue.

 The composition of the emitters includes a set of active elements (photo-emitting matrix of active elements), a set of photosensitive sensors (set of photodiodes). In order to maintain the constancy of the installed radiation power in the emitters during photothermocryotherapy, stabilization of the radiation power and stabilization of the temperature of the emitters were applied.

 When emitters and photosensitive sensors (photodiodes) are placed outside the acting element, the radiation is supplied to the biological tissue using optical fiber (optical fiber cable), the output end of which is fixed to the acting element. In this case, the radiation power of the emitter is controlled using an optical fiber, one end of which is fixed to the acting element, and the second is fed to a photosensitive sensor (photodiode). The radiation power reflected from the biological tissue enters the optical fiber and then enters the photosensitive area of the remote photosensor (photodiode).

 In FIG. 1 shows a structural electrical diagram of the proposed device.

 The composition of the acting element is shown in FIG. 2.

 The photothermocryotherapy device contains a power source 1 for powering a set of thermoelectric coolers 10, 11, 12 (Fig. 1), a power source 2 for powering a set of emitters 16, 17, 18, a microcontroller 3 for controlling the operation of the device, an indicator 4 for indicating established operating modes of thermoelectric coolers and radiators, controls 5 for setting the operating modes of thermoelectric coolers, thermosensitive elements 13, 14, 15, photosensitive sensors (photodiodes) 19, 20, 21, programmable thermoelement switch 6 comrade, a programmable switch emitters 8, a programmable switch temperature sensor 7, a programmable switch of photosensitive sensors (photodiode) 9.

 The power supply of thermoelectric coolers 1 is connected through a switch 6 programmable using a microcontroller 3 with a set of thermoelectric coolers 10, 11, 12, the control input of the power source is connected to a microcontroller 3. The radiator power supply 2 is connected through a switch 8 programmable using microcontroller 3 with a set of emitters 16 , 17, 18, the control input of the emitter power supply is connected to the microcontroller 3. Temperature sensors 13, 14, 15 through a switch programmable with the help of microcontroller 3 7, the control input of which is connected to the microcontroller 3, connected to the microcontroller 3. The photosensitive sensors 19, 20, 21 through the switch 9 programmable with the help of the microcontroller 3, the control input of which is connected to the microcontroller 3, are connected to the microcontroller 3. Indicator 4, on which are indicated established operating modes of thermoelectric coolers based on Peltier elements and emitters, made using an LCD and (or) digital LED indicators, connected to the microcontroller 3. Controls 5, intended for the mode of operation devices (buttons, endokodery and (or) other controls) are connected to the microcontroller 3.

When conducting photothermocryotherapy on the side of the thermoelectric cooler facing the biological tissue, depending on the specific exposure method, a temperature is set in the range from -20 ^o C to +70 ^o C. The duration of thermo- and (or) cryotherapy in one cycle of thermo-cryotherapy is set to 30 from up to 30 minutes The number of installed cycles is from 1 to 100. The average radiation power of the emitters is in the range of 0.00005 ... 2 W. It should be added that the average radiation power for a pulsed mode is defined as the radiation power in a pulse, related to duty cycle. The modulation frequency of the emitters is in the range from 0 to 10 kHz.

 To use the device during physiotherapeutic exposure, temperature values are selected for thermal and cryotherapy on biological tissue; duration of cooling and heating in one cycle; number of cycles; exposure time; radiation power of emitters; dose of photo exposure; modulation frequency of the emitter radiation; The mode of synchronization of radiation of emitters with thermal and cryotherapy.

 The synchronization modes of radiation of emitters with thermal and cryogenic influence allow you to choose the constant inclusion of emitters during the entire time of photothermocryotherapy, the inclusion of emitters only during thermal exposure, the inclusion of emitters only during cryotherapy, the shutdown of emitters during thermal and cryotherapy on biological tissue.

 After setting the required values of the parameters of photothermocryotherapy, the acting element 22 of the photothermocryotherapy device is placed on the biological tissue and, depending on the purpose of the therapy and the length of the area of the biological tissue, photothermocryotherapy is performed at a fixed position of the acting element 22 or by slow rotational-translational movements of the acting element 22. Depending on the indications of therapy, the procedure is carried out within 10 s to 30 min (if necessary, arrange breaks between thermal and cryogenic effects eat). To apply a set of different methods of photothermocryotherapy, the data for setting the parameters of photothermocryotherapy are sent to the microcontroller 3 from an external personal computer in accordance with the selected therapy methodology.

 The external computer displays the set temperature values of each of the thermoelectric coolers in the acting element, the radiation power, the dose of photo exposure, the modulation frequency of the emitters, the number of thermo-cryocycles, the set exposure time and their countdown during the procedure.

Examples:
1. Patient P., 47 years old. For 8 years, suffers from a chronic form of pneumonia, frequent exacerbations 2-3 times a year. The treatment was not effective. The patient was prescribed a cryotherapy course with an exposure temperature from minus 5 to minus 15 ^o C, at the beginning of the session 10 s, with a break for reflex addiction of the body up to 2 minutes.

 First step. Rotational smooth strokes clockwise in the region of the right hypochondrium with capture of the oblique muscle of the back, costal arch and lower VIII-XII ribs. The exposure time is up to 10 minutes, then a break of 2-3 minutes. Then the patient is turned on his back and the procedure is started on the left - the area of influence from the costal arch to the angle of the scapula, stroking movements, clockwise rotation up to 15-17 minutes, rest 2-3 minutes. At the same time, a course of laser therapy is carried out for 5 minutes using a radiation wavelength of 890 nm, a pulse repetition frequency of radiation of 80-1500 Hz, a radiation power of 5 W per pulse in the vertebral region. The course of treatment is up to 10 sessions. After the course of photocryotherapy, the patient noted improvement in well-being, the cough disappeared. There was no relapse of the disease within one year.

2. Patient I., 32 years old, has been suffering from peptic ulcer of the duodenum for 4 years. Marks exacerbations 2-3 times a year. Upon admission to treatment noted pain in the right hypochondrium, bitterness, belching. On FGS - a peptic ulcer on the back wall of 12 p. Intestines up to 1.5 cm. The patient was prescribed a course of photocryotherapy in the supine position with a roller placed under the knees. The exposure temperature is from minus 10 ^o C to minus 20 ^o C. In the first 5-10 s a cold test was carried out, then a break of 2-3 minutes. Then they began to act with rotational movements in the right hypochondrium in a clockwise direction for 7-10 minutes without pressing the abdominal wall. Then a break of 2-3 minutes, followed by repetition and deeper pressure on the abdominal wall. At the same time, the patient underwent a course of laser therapy for 5 minutes using a radiation wavelength of 890 nm, the radiation power per pulse was 10 W, and the pulse repetition rate was 80-1500 Hz. The course of treatment was 10 sessions. After the first session, the patient noted the complete disappearance of the pain syndrome. On the control FGS after 10 days, the ulcer epithelized.

3. Patient B., 63 years, for 3 years suffered from widespread osteochondrosis of the thoracic and lumbar spine. Was admitted to the clinic with severe pain, limited mobility in the thoracic and lumbar spine. The patient was prescribed a course of photocryotherapy with exposure temperature from minus 5 to minus 20 ^o C. Cold test for 3-5 minutes. Stroking circular movements clockwise for 5-10 minutes on both paravertebral areas of the spine with repeated manipulations up to 4 times. At the same time, a photo-exposure course was conducted using an incoherent light source (LEDs) with a radiation wavelength of 570 nm and a power of 150 mW for 4 min to the thoracic paravertebral region of the spine. A course of 15 sessions. After the first session, the patient noted a decrease in pain, for the first time she slept peacefully at night. After three sessions, the pain syndrome completely stopped, the patient within 16 months does not notice an exacerbation of the disease.

Claims (3)

 1. A device for thermocryotherapy containing an acting element on which a set of thermoelectric coolers is installed, connected through a switch to a power source of thermoelectric coolers, and temperature sensors, characterized in that the switch of thermoelectric coolers is connected to a microcontroller, the output of which is connected to the control input of the thermoelectric power source coolers, additionally the microcontroller is connected to the controls and the corresponding control inputs power supply of emitters, a programmable commutator of emitters connected to a set of emitters, a programmable commutator of photosensitive sensors connected to them, a programmable commutator of temperature sensors connected to them, and to the input of the indicator, a set of emitters is installed on the acting element and is made with a radiation wavelength in the range 0 , 5 - 1.6 microns and an average radiation power in the range of 0.00005 - 2 watts. 2. The device according to claim 1, characterized in that the thermoelectric coolers are made with the possibility of installing on their surface the influence of temperatures in the range - 20 ... +70 ^o C. 3. The method of thermocryotherapeutic exposure, which consists in placing an acting element on a biotissue with a set of thermoelectric coolers and conducting thermal and cryotherapy, characterized in that they additionally carry out photo exposure by a set of emitters on the acting element, and the synchronization mode of emitters with thermo and cryotherapy, in which the average radiation power is from 0.00005 to 2 W with a radiation wavelength in the range of 0.5 - 1.6 microns, the frequency of radiation pulse is selected from 0 to 10 Hz, the duration of heat and / or cryotherapy set in the range from 30 seconds to 30 minutes, when the number of cycles up to 100, and a thermoelectric cooler temperature from the biotissue adjusted from -20 to +70 ^o C, at this effect is carried out at a fixed position of the acting element or by its slow rotational-translational movements in the area of influence.

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