RU2072880C1 - Apparatus for intracavitary laser therapy - Google Patents

Abstract

FIELD: gynecologic and proctological practice under clinical and ambulatory conditions. SUBSTANCE: apparatus comprises optical radiation scorcher made in form of laser and/or array of light-emitting diodes accommodated in hollow tubular casing made at least partially, at optical radiation exit end, of optically transparent material. Additionally, hollow casing may carry permanent magnet and/or heating element. Optical radiation source, permanent magnet and additional heating element may be provided, respectively, with optical diaphragm and magnetic reflecting screens. Outer surface of casing carries circular collar with locking member. Casing itself and collar have, respectively, linear and angular scales. Electric circuitry of apparatus comprises control unit for controlling operation of both laser and each individual light-emitting diode. Apparatus comprises mechanism for angular turning of optical radiator around longitudinal axis of casing which may be made replaceable or in form of expendable head piece. EFFECT: effective laser treatment of inflammation foci in internal organs. 9 cl, 8 dwg

Description

 The invention relates to medical systems, mainly to devices for cavity laser therapy of inflammatory foci of internal organs and can be used in clinical and outpatient gynecological and proctological practice.

Cavity electric heaters of the type PEN-01 are known for the treatment of non-specific chronic inflammatory processes of the uterus and appendages, as well as adhesions and cicatricial changes in the area of parametria and magotase with dosed heat exposure in the disease focus using a special electric heater located inside the hollow tubular casing of the casing and providing the temperature of the heat exposure 37-42 ^o C for 5-100 minutes This device serves for local hyperthermia and provides a physiological effect in chronic non-specific inflammations of the uterus and appendages, relieves pain, restores the ovulation cycle, menstrual and secretory functions, reduces the need for additional drug treatment, etc. (I).

The main disadvantages of this type of device are:
insufficiently high efficiency of the therapeutic effect of electrohyperthermia in gynecological proctological practice;
insufficient degree of localization in the treatment of hyperthermia using this type of device.

 Currently, in various fields of medicine, low-intensity infrared (laser) radiation is used to one degree or another, the therapeutic effect of which is quite effective in the treatment of inflammatory foci of internal organs in gynecology and proctology, gastroenterology, etc.

 Laser therapy of long-term non-healing stomach and duodenal ulcers is carried out using devices containing a laser source, which can be used lasers LG-38, LG-75, wavelengths of 0.63 microns with a power of 50 and 25 mW, and a fiber endoscope, in the instrumental the channel of which is placed a light guide having a light distribution indicatrix at the distal end corresponding to the geometry of the irradiation zone (2).

The main disadvantages of this class of devices for laser therapy of internal organs are:
insufficiently high efficiency of the therapeutic effect of laser radiation due to its losses in the fiber itself, depending both on the geometry of the fiber and its physical characteristics, and at the junction of the optical elements;
lack of opportunities to equip such devices with additional physical effects (magnetic field, thermal radiation), providing direct local therapeutic effect.

 Also known in gynecological and proctological practice are devices for cavity laser therapy containing an optical radiation source and a hollow tubular-shaped casing, made at least at the exit point of the optical radiation from an optically transparent material in the operating range of the optical emitter. A fiber is placed inside the casing, and the optical radiation source is outside the hollow casing and is in optical communication with the fiber and through the fiber with a light-tight nozzle installed at the exit point of the optical radiation from the hollow casing (3). The device is additionally equipped with an annular piezoelectric emitter and focon.

The main disadvantages of this device are:
low efficiency of the therapeutic effect of laser radiation due to the loss of optical radiation in the path: the source of optical radiation is a fiber exit window of the casing;
the impossibility of using such a device for magneto-laser therapy and thermal massage;
the impossibility of varying the degree of localization of the therapeutic effect.

 The present invention aims to achieve the following technical result.

 The result is an increase in the efficiency of the process of intracavitary laser therapy by reducing the loss of optical radiation and shortening the treatment time, as well as expanding the functionality of the device by combining the effects of optical radiation with a magnetic field and additional thermotherapy.

 An additional result of the invention is to increase the efficiency of the process of intracavitary therapy due to the localization of the magnetic field and additional thermotherapy, as well as the localization of the zone of exposure to optical radiation.

 An additional result of the invention is also to increase the usability of the device, its accuracy of exposure and the improvement of sanitary and hygienic properties.

 An additional result is achieved by the fact that in the known device for cavity laser therapy, containing a source of optical radiation and a hollow tubular-shaped casing, made at least at the place of exit of optical radiation from an optically transparent material in the operating range of the optical emitter, the optical radiation source is made in the form of a laser and / or a set of LEDs that are installed in the hollow casing in the immediate vicinity of the exit from the casing of optical radiation.

 In addition, the technical result is achieved by the fact that at least one permanent magnet is additionally placed inside the hollow casing near the place of exit from the optical radiation casing, the hollow casing, at least in the area of the permanent magnet, is made of a material with a small value of the magnetic permeability coefficient, and the magnet itself is installed so that its north pole coincides in the direction with the direction of the maximum of the optical indicatrix of optical radiation.

 In addition, the technical result is achieved by the fact that the device is equipped with an additional heating element, also installed inside the hollow casing, and interchangeable magnetic screens installed in the hollow casing, as well as reflective screens.

 The technical result is also achieved by supplying the device with an optical diaphragm.

 In addition, the goal is achieved by the fact that on the outer surface of the hollow casing is installed with the possibility of installation movement along its longitudinal axis of the ring-cuff with a latch, which has the possibility of angular rotation relative to the casing around its longitudinal axis, and on the casing along its longitudinal axis and on the ring -cuffs around the circumference are respectively linear and angular scales.

 In addition, the technical result is achieved by the fact that the hollow casing is made replaceable or in the form of a disposable nozzle.

 In addition, the technical result is achieved in that the device is equipped with a mechanism for angular rotation of the optical emitter around the longitudinal axis of the casing.

 In addition, the technical result is achieved in that it is equipped with a control unit for the operation of both the laser and each LED individually.

 A comparative analysis of the claimed device for cavity therapy with the prototype (3) shows that the proposed device differs in the implementation of the optical radiation source in the form of a laser and / or a set of LEDs and their placement in the immediate vicinity of the exit from the casing of optical radiation, which improves the efficiency of the intracavitary process therapy by reducing the loss of laser radiation and reduce treatment time.

 In addition, the proposed device is characterized by the placement inside the hollow casing of at least one permanent magnet and an additional heating element, which allows you to significantly expand the functionality of the device for cavity laser therapy by combining exposure to the patient with laser radiation with exposure to the magnetic field and additional thermotherapy such as thermal massage.

 In addition, the proposed device is characterized by equipping it with removable magnetic and reflective screens and a replaceable diaphragm, providing the necessary localization of all physical influences (optical radiation, magnetic field and thermal radiation from an additional heater).

 In addition, the proposed device is characterized by the implementation of a hollow casing of the device removable or in the form of a disposable nozzle, which increases the convenience of its operation and ensures compliance with sanitary requirements for this class of devices.

 In addition, the proposed device is characterized by supplying it with a cuff ring, which can be installed on the casing at different distances from the optical emitter (or magnet) and, playing the role of a limiter for the depth of insertion of the device into the cavity subjected to treatment of the patient’s internal organ, ensures the locality and accuracy of the therapeutic exposure to it (for this the device is equipped with a linear and angular scales that determine the linear and angular position, in particular, for example, of an optical emitter relative to the radiation volume of the patient.

 In addition, the proposed device is characterized by the supply of an optical emitter, a mechanism for its angular rotation relative to the longitudinal axis of the casing and a control unit for the operation of both the laser and each individual LED, which can significantly expand its functionality and improve serviceability.

 Thus, the claimed design of the device cavity laser therapy meets the criterion of "NEW".

 Comparison of the claimed solution, not only with the prototype, but also with other technical solutions in this field of medicine, did not allow them to identify signs that distinguish the claimed solution from the prototype, which gives the right to conclude that it meets the criterion of "INVENTIVE LEVEL".

 In FIG. 1 shows a General view of the device in section with two options for the placement of optical emitters; in FIG. 2 in section two options for the placement of optical emitters in combination with permanent magnets; in FIG. 3 - placement of an additional heating element in combination with optical emitters; in FIG. 4 is an embodiment of an additional heating element in the form of an optically transparent partition of a track window deposited on a surface; in FIG. 5-shift optical aperture 1 6; in FIG. 6 is an external view of the device with a cuff ring installed on the casing (views are shown in AA and BB of the device); in FIG. 7 is an embodiment of a device with a mechanism for angular rotation of an optical emitter; in FIG. 8 is an electrical diagram of the device.

 The device for cavity laser therapy contains a hollow tube-shaped casing, inside which there is an optical radiation source 2, made in the form of a laser 3 and / or a set of LEDs 4, and mounted on a board 5 in the housing 6, which is mounted on a hollow shaft 7, inside which are placed wires supplying electric current from the power source 8. The hollow rod has a locking mechanism for the casing 1, containing spacer rings 9 made, for example, of elastic material (rubber), and spacer sleeves 10, 11, 12 with conical chamfers, which sleeve 10 is fixed on side 7, and the sleeve 10 and 12 are mounted on the shaft 7 with the possibility of movement along its longitudinal axis, and the sleeve 12 transmits the tightening force to the locking mechanism from the handle 13 mounted freely on the free end of the hollow shaft 7 with rotation around the longitudinal axis of the rod 7 and movement along its axis by means of a helical gear 14. The hollow casing 1 at least at the point of exit from the optical radiation (laser and / or LEDs) is made of a material that is optically transparent in the range this operation of an optical emitter, for example, in the form of a glass optically transparent test tube or an optically transparent plastic tube with a transparent window 15 at the end or in another place where the optical radiation exits the casing 1, including when the casing 1 is made of an optically opaque material, for example plastic , with the installation of transparent partitions at the places of optical radiation exit 15. For localization of the zone of action of optical radiation at the places of its exit (windows 15 are located in places), a hollow casing 1 can be installed interchangeable optical diaphragm 16. Outside on the hollow casing 1 is installed with the possibility of installation movement along the longitudinal axis of the casing 1 and with the possibility of rotation relative to its longitudinal axis of the ring-cuff 17, equipped with a latch 18, made, for example, in the form of a rubber ring, and on the side surface the casing 1 and the latch 18 are applied, respectively, linear 19 and angular 20 of the scale. In addition to the optical emitter, permanent magnets 21 can be placed inside the hollow casing, which are installed near the exit point from the optical casing 1 (around the radiation sources or in the center) so that the north pole of the magnet coincides with the direction of the maximum of the optical indicatrix of radiation (parallel to the perpendicular to the window surface 15 in the casing 1, restored in the center of the window). By selecting the material of the permanent magnet 21, it is possible to create a magnetic field in the zone of influence of the required magnitude (30-50 mT), for example, the addition of cobalt up to 15% can increase the residual induction on the surface of the magnet by 3 times (from 40 to 120 mT), and the addition of samarium with 100 times cobalt (from 40 mT to 4 T). In addition, heating elements 22 can also be installed inside the casing 1, made, for example, in the form of an electric spiral (made of nichrome) or in the form of 15 tracks of nichrome, tin dioxide, indium oxide, and the like placed on the transparent transparent partitions of the windows . connected like a spiral to a power source 8. If the permanent magnets 21 are located inside the casing 1, the casing itself, at least in the area of the permanent magnet, must be made of materials with a small magnetic permeability coefficient.

 To localize the action of the magnetic and thermal fields on the patient, magnetic 23 removable and reflective replaceable 24 screens, for example, made of transformer steel, can be additionally installed in the casing. The hollow casing 1 itself can be made removable or in the form of a disposable nozzle and provided with an external antiseptic coating, for example, of antibacterial drugs. Optical emitter 2, which can be used as a laser of the ILPN 203 A brand with a radiation power of 2-2.5 mW and a radiation wavelength of 0.88 ± 0.001 μm and AL 118 A LEDs with a radiation power of 2-2.5 mW and the radiation wavelength at the maximum of the spectral characteristic - 0.88 ± 0.001 μm, can be installed in the hollow casing with the possibility of installation movement along the longitudinal axis of the casing 1, and installation angular rotation around this axis, for example, in the case of a spline connection of the housing 6 with the end of the hollow rod 7, as well as with the working angular rotation around the longitudinal axis of the casing 1 together with the hollow shaft 7 relative to the casing 1 in the case of a device with an angular rotation mechanism of the optical emitter (as shown in Fig. 7), which includes a sleeve 25, replacing the sleeve 10 and freely mounted on rod 26, replacing the hollow rod 7 and bearing on its free end (from the side of the handle 13) instead of the nut 27 of the screw transmission 14, the handwheel 28, mounted on it. In this case, the role of the screw transmission 14 is played by a nut 29 fixed in the handle 13, which interacts not with a screw thread at the free end of the shaft 7, but with a screw thread at the free end of the sleeve 25.

 The electrical circuit of the device includes, in addition to the power source 8, a laser control unit 31 for connecting a laser diode 3, a control unit for light emitting diodes (multi-channel) 32 for powering emitting diodes (LEDs) 4 and a temperature stabilizer 33 for powering a thermal heating device, which are also connected to it through switches 30 temperature feedback element 22. Optical emitters 3, 4 can be connected to the power system through tuning variable resistors 34, 35, respectively, for smooth adjustment of their radiation power. The electrical circuit of the device may also include an indication unit 37 connected through a switch 36 to a power source 8 with a radiation receiver 38 and an indicator 39. An FD-265 brand photodiode can be used as an optical radiation receiver, and an AL brand LED as an element of light indication -307. The temperature stabilizer 33 with the element 40 in the feedback circuit by the temperature sensor and the heating element 22 itself can be performed similarly (according to the principle of operation) to the cavity electric heater PEN-01 with structural changes necessary to integrate it into the proposed device.

 The device is also equipped with a limiter 41 and a sealing gasket 42 installed between the open end of the hollow casing 1 and the handle 13.

The operation of the device for cavity laser therapy is as follows:
Having determined the localization of the lesion, for example, the rectum, the device is prepared for operation. For this, the type of optical emitter 2 that is included with the device, for example, with an end or side location in the housing 6, is selected, respectively, if it is necessary according to the treatment conditions, the type of constant a magnet, for example, also end-mounted or side-mounted in the housing 6, and a heating element 22. A selected set, consisting, for example, of an optical emitter 2, a permanent magnet 21 and additional th heating element 22, and mounted, for example in a common housing 6 is mounted on the end of the hollow shaft 7 and is fixed on the thread or using a fixing screw (not shown). After installing the housing 6 on the hollow rod, with a set of working tools (emitter, magnet, etc.) and connecting the power wires located in the inner cavity of the rod, or simply selecting the rod 7 with the housing 6 already installed on it containing the necessary set tools and included in the set of nozzles to the device (if you do not assign this preparation of the device to the attending physician), put on the hollow shaft 7 a hollow casing by introducing into its internal cavity with the required angular orientation relative to the casing 1 tbsp rod 7 with a set fixed on it (optical emitter 2, permanent magnet 21 and heating element 22). The casing 1 is mounted on the rod 7, tightening the ring 9 when turning the nut 27 of the screw gear 14, transmitting the tightening force through the threaded end of the rod 7 to the sleeve 10, then the spacer rings, the sleeve 11, the spacer ring 9, the sleeve 12, the handle 13 with a stop 41 and by the gasket 42 and again by the nut 27. The axial displacement of the shaft 7 relative to the casing 1 held in the hand during assembly is eliminated by the presence of friction between the inner surface of the casing 1 and the outer surface of the spacer rings inserted into it with an interference fit 9. To localize the action of optical radiation , magnetic field and thermal radiation from the heating element 22, it is necessary to install the corresponding optical diaphragm 16, a magnetic screen 23 and a thermal reflective screen 24, which, if all the tools are in the case 6, are also mounted on this case, and can also be installed directly in the inner cavity of the casing 1 before assembly. To install the optical emitter 2, the permanent magnet 21 and the heating element 22 to a certain depth, that is, to adjust the depth of insertion of the casing 1 of the device into the cavity, for example the rectum, a cuff ring 17 is installed on the outer surface before treatment using linear and angular scales (19 and 20) precisely determining the position of the emitter, magnet and heating element relative to the cuff ring 17 and thereby enabling the physician to monitor their position relative to the irradiated damage during treatment ennogo portion of the internal organ.

 Depending on the diagnosis, the number of necessary sessions and the doses corresponding to each session are determined, the patient is prepared for the prescribed course of treatment. After an enema, for example, in the treatment of a lesion of the rectum, the device is switched on to the network by setting the operating modes of the heating element 22, laser 3 and LEDs 4, respectively, by setting blocks 33, 31, 32. The outer surface of the casing 1 is lubricated with Vaseline or glycerin and introduced into the cavity of the rectum of the patient to the required depth, determining the depth of introduction of the emitters and their angular location relative to the body by the position of the ring cuff 14 (using linear 19 and angular 20 scales). Using the switch 30, the laser 3 and / or the LEDs 4 and / or the heating element 22 are turned on, each with its own exposure, and using the display unit 37, a visual indication is carried out using the display element 38 of the emitter radiation (laser or LEDs) when the optical feedback is closed through the radiation receiver 39. Variable resistors 34 and 35 provide smooth adjustment of the radiation power of the laser 3 and each LED 4.

 If it is necessary to irradiate two or more sections inside the cavity located at the same depth, it is possible, without changing the position of the apparatus, turning only the casing 6 with the optical emitters mounted on it around the optical axis of the casing using the handwheel 28, to move the irradiation zone to the desired section.

 At the end of the session, turn off the power of the optical emitters, the heating element, and then remove the device from the cavity. The removed device is treated with disinfectant solutions, and the hollow casing is sterilized (if it does not fulfill the role of a disposable nozzle).

 The power source 8 is built according to well-known schemes consisting of a transformer, a rectifier, a filter.

 The control units of the laser 31 and LEDs 32 are performed in a continuous mode of radiation in the form of an adjustable current source and in the form of a multi-channel adjustable voltage source, respectively. In the case of the implementation of the pulsed radiation mode, the control units contain generators in each channel with adjustable duration, frequency and amplitude of the pulses.

 To modulate the output radiation by external signals in the control units of the laser and LEDs, the corresponding inputs are provided associated with the control circuits through matching elements. Control units can be made on microcircuits, transistors, switches, providing reliability, small dimensions and weight.

The temperature stabilizer 33 is designed to power the heating element 22 while maintaining a constant temperature at a predetermined (depending on the setting of the feedback system with the sensor 40) level, for example, both above 36.6 ^o C and lower, especially when installing into the element 22 of the micro-refrigerator . As a temperature sensor 40 in the feedback circuit, a thermistor can be used.

 To ensure the stability of the radiation power of the laser emitter 3, feedback on the optical channel (not shown) can be integrated into the circuit of the laser control unit 31, for example, as is the case in ILPN 203, where a photodetector is built into the laser emitter housing. The stabilization of the current supply of the laser emitter (not shown) can also be introduced into the laser control unit. Accordingly, to ensure the stability of the power of the LEDs 4, stabilization of the supply current of each LED 4 (not shown) can also be introduced into the control unit of the LEDs 32.

 The supply of the device with a heating element 22, placed in the zone of location of the optical emitters 2, due to the presence in its power circuit of a temperature stabilizer 3 3 allows to stabilize the temperature of the environment surrounding the optical emitters 2 and thereby significantly increase the stability of their radiation power.

 The proposed device for cavity laser therapy works like a device according to the Academy of Sciences of the USSR 1298987 (prototype) and, while retaining its advantages in terms of ease of use, also increases the efficiency of the treatment process by reducing the loss of optical radiation in the light-transmitting channel and reducing treatment time , and also allows you to more effectively use the power of optical radiation and control the degree of illumination by the area of the lesion, by chromaticity and by radiation frequency.

 In addition, the proposed device expands the possibilities of laser cavity therapy, combining as necessary (linking the direction of the magnetic lines of force of a constant magnetic field and the direction of the maximum of the optical indicatrix of radiation) in the space under the influence of optical radiation and magnetic field, as well as in time.

 In addition, the proposed device expands the possibilities of cavity therapy, combining in space and time the effects on the lesion site of optical radiation, a magnetic field and a thermal field with the required degree of localization by fitting an optical diaphragm, a protective magnetic screen and a reflective heat screen.

 Using a modern component base allows you to make this device compact and easy to use. Yr

Claims (10)

 1. A device for cavity laser therapy containing an optical radiation source and a hollow casing with a restrictive cuff, made at least in places where the optical radiation exits from a material that is optically transparent in the range of the optical emitter, characterized in that the optical radiation source is installed inside the hollow casing in the place where optical radiation exits from it and is made in the form of a laser and / or a set of LEDs.  2. The device according to claim 1, characterized in that at least one permanent magnet is additionally placed inside the hollow casing so that the direction of the magnetic field coincides with the direction of the maximum of the optical indicatrix of radiation, the hollow casing at least in the magnetic field made of material with a small value of the coefficient of magnetic permeability.  3. The device according to p. 1, characterized in that it is equipped with a heating element with a temperature stabilization unit, and the heating element is installed inside the hollow casing in the area of the optical emitters.  4. The device according to p. 2, characterized in that it is equipped with removable magnetic screens mounted inside the hollow casing at the location of the permanent magnet.  5. The device according to p. 3, characterized in that it is equipped with reflective screens installed in the hollow casing at the location of the heating element.  6. The device according to paragraphs. 1-3, characterized in that it is equipped with a replaceable optical diaphragm installed at the exit from the hollow casing of the optical radiation.  7. The device according to paragraphs. 1-6, characterized in that the cuff ring is mounted with a latch with the ability to move along the longitudinal axis of the hollow casing and angular rotation around its longitudinal axis, moreover, on the casing along its longitudinal axis and on the cuff ring circumferentially applied linear and angular scales .  8. The device according to paragraphs. 1-7, characterized in that the hollow casing is removable.  9. The device according to p. 1, characterized in that it is equipped with a mechanism for angular rotation of the optical emitters around the longitudinal axis of the casing.  10. The device according to paragraphs. 1 and 9, characterized in that it is equipped with a laser operation control unit, and each LED individually.

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