RU73788U1 - PHYSIOTHERAPEUTIC DEVICE - Google Patents

Abstract

The utility model relates to medicine, in particular to physiotherapy, and relates to physiotherapeutic devices intended for irradiation of acupuncture points, reflexogenic zones, for percutaneous irradiation and photomodification of blood. The technical result of the claimed utility model is to expand the functionality of the device by applying complex light-vacuum-magnetic therapy, monitoring the patient's condition during the irradiation process, automatically setting individual parameters of the treatment regimen, and also simplifying the therapeutic head. The physiotherapeutic device comprises a housing (1), on the control panel of which there are independent channels (2) for connecting therapeutic heads (3). The therapeutic head contains a vacuum applicator (4), a light emitter (5). New is that the therapeutic head is equipped with an electromagnetic emitter (6), a light emitter temperature sensor (7) and a reflected light flux intensity sensor (8), and the control unit consists of a central processor made in the form of a single-board computer (12) connected to controller (13) and controller (14). The controller (13) is connected to an electromagnetic pulse generator (15) and a light pulse generator (16). The controller (14) is connected to a vacuum pulse generator (17). The device is equipped with sensors for body temperature (18) and heart rate (19), and also contains an external electromagnetic emitter (20). The body of the device is made in the form of a case and is equipped with a closing compartment (21) for removable vacuum applicators (4) and therapeutic heads (3). In the cover of the housing (1) is a monitor (22) in the form of a TFT panel. 1 n.p.ph., 4 s.p.ph., 3 ill.

Description

The utility model relates to medicine, in particular to physiotherapy, and relates to physiotherapeutic devices intended for irradiation of acupuncture points, reflexogenic zones, for percutaneous irradiation and photomodification of blood.

The SOMAMED physiotherapeutic device is known, including power supplies and control light emission and vacuum, separately laser and vacuum collectors for three channels, connected by vacuum wires and laser communications with three working nozzles in the form of suction cups with the possibility of creating a constant discharge of air, and in the center of the nozzle the end face of the laser fiber with a wavelength of 0.63 μm is placed, on the side of the nozzle there is an opening for supplying a vacuum pipe (see V. Illarionov, Fundamentals of Laser Therapy, M.: 1992, p. 73-75).

The known device is almost impossible to irradiate parts of the body with complex contours. The disadvantage is also the low efficiency and duration of percutaneous irradiation of blood due to stagnation of blood in the area of constant suction, the inconvenience and laboriousness of using several banks at the same time, since when opening or rearranging one bank, the others automatically fall off, which requires considerable skill for their simultaneous installation on different parts of the body.

The closest in design and methodology of irradiation is a physiotherapeutic device containing a housing and a control unit located in it with light and vacuum pulse generators, an emitter (therapeutic head) connected to the control unit and located inside the frame (vacuum applicator), a vacuum wire , the frame has a side hole in which a tube is installed closed at one end with an electrical outlet and a valve, the lever of which protrudes when the valve is closed and open frame plane, wherein the emitter is connected to the socket, and electrovacuum-wire inserted into the tube (see. №2045972 RF patent, A61N5 / 06, A61N39 / 00 "Physiotherapy apparatus", publication date 20.10.1995 g).

A disadvantage of the known device is that it does not allow for complex light-vacuum-magnetic therapy, as well as to use the possibilities of exogenous bioresonance therapy, which reduces its functionality.

A disadvantage of the known device is also the contact of valve parts and the electrical connection of the emitter with the environment of the patient’s skin secretions, the concentration of which increases under the influence of vacuum, which causes pollution

valve and corrosion of electrical contacts and leads to their failure, reducing the reliability of the device as a whole.

The known device does not provide for monitoring the patient’s condition, namely, monitoring the intensity and frequency of the pulse, the rhythm of blood flow in the vessels and capillaries, depending on the effect of vacuum and light pulses, the intensity of the reflected light flux and the patient’s body temperature, which does not allow to adjust the parameters of the treatment regimen.

In addition, the design of the known device, namely, the location of the vacuum and electrical wires in the side opening of the housing, does not allow the complete removal of the therapeutic head to remove and put on the frame. If you need to change the irradiation area and the intensity of the vacuum exposure, you need to install a new therapeutic head, which increases the number of interchangeable heads, and, therefore, the cost of the device.

The control unit of the known device does not allow automatic installation of individual treatment parameters, their change and control, which reduces the functionality of the device, does not exclude the occurrence of errors and increases the setup time.

The technical result of the claimed utility model is to expand the functionality of the device by applying complex light-vacuum-magnetic therapy, monitoring the patient's condition during the irradiation process, automatically setting individual parameters of the treatment regimen, and also simplifying the therapeutic head.

The specified technical result is achieved by the fact that the physiotherapeutic device comprising a housing and a control unit located therein with light and vacuum pulse generators, therapeutic heads containing a vacuum applicator and a light emitter connected to the control unit by means of electric vacuum wires, according to a utility model, further comprises a generator electromagnetic pulses, body temperature and heart rate sensors connected to the control unit, as well as external an electromagnetic emitter connected to an electromagnetic pulse generator, the therapeutic head is equipped with an electromagnetic emitter, a temperature sensor of the light emitter and a sensor of the intensity of the reflected light flux, while the control unit is made in the form of a processor and controllers connected to the generators of light, electromagnetic and vacuum pulses, the vacuum applicator is made removable, the case is made in the form of a case, on the cover of which is located a type monitor

TFT, an external magnetic emitter is made in the form of a belt or a loop, the case is equipped with a closure compartment for replaceable therapeutic heads and vacuum applicators, the electrovacuum wire, light and electromagnetic emitters are sealed with a dielectric compound, the vacuum wire is equipped with a filter.

The presence of an additionally installed generator of electromagnetic pulses, connected to the electromagnetic emitter of the therapeutic head, allows, in conjunction with vacuum and pulsed radiation, to carry out complex light-vacuum-magnetic therapy, which increases the efficiency of irradiation by increasing blood flow and the volume of irradiated blood, which expands the functionality of the device.

The presence of body temperature and heart rate sensors connected to the control unit allows the patient to be monitored during the irradiation process and, depending on the intensity and time of irradiation, automatically change the treatment regimen, which ensures effective and safe therapy. The pulse sensor allows you to adjust the frequency of vacuum pulses to the rhythm of blood flow in the vessels and capillaries.

The location of the temperature sensor of the light emitter and the intensity sensor of the reflected light flux in the therapeutic head allows you to have a clear picture of the amount of light energy received by the patient during the irradiation process, and connecting them to the control unit allows depending on the patient’s condition, pulse rate and parameters of the cardiovascular system automatically change the intensity and time of radiation, which provides an effective and safe therapy in accordance with the physiological parameters patient's.

The execution of the control unit in the form of a processor and controllers connected to it associated with generators of light, electromagnetic, and vacuum pulses makes it possible to automate the introduction of treatment parameters and their control, as well as create a distribution control system in which the central computer is connected to the controllers, which allows increasing the number of modules, and minimize the number of connections.

The implementation of the removable vacuum applicator greatly expands the capabilities of the therapeutic head. Namely, when a vacuum applicator is put on, complex light-vacuum-magnetic therapy is carried out, and when the vacuum applicator is removed and the vacuum is turned off, it is possible to carry out magnetic-light irradiation, or only light, or only magnetic in accordance with the doctor's prescription, which significantly reduces the number of therapeutic heads.

In addition, the presence of a removable vacuum applicator allows the use of different applicators in terms of contact area, depending on the area of influence and the number of simultaneously placed therapeutic heads.

The presence of an additionally installed external electromagnetic emitter, made in the form of a belt or loop and connected to an electromagnetic pulse generator, allows bioresonance therapy, which also extends the functionality of the device.

The implementation of the device’s case in the form of a case equipped with a TFT-type monitor located on the case cover and a compartment for removable vacuum applicators and therapeutic heads allows you to create a compact multi-functional device, convenient for use and transportation.

The dielectric sealing of the electrovacuum wires, light and magnetic emitters located in the casing of the therapeutic head, increases the reliability of their fastening and the safety of the physiotherapeutic device.

The presence in the vacuum wire of the filter increases the purity of the air entering the vacuum applicator in contact with the skin of the patient, which ensures a clean vacuum environment.

No technical solutions matching the totality of essential features of the utility model have been identified, which allows us to conclude that the utility model meets the patentability condition of “novelty”.

The patentability condition "industrial applicability" is confirmed by the example of a specific implementation of a physiotherapeutic device.

Figure 1 shows a General view of a physiotherapeutic device.

Figure 2 shows the therapeutic head.

Figure 3 shows a structural diagram of a physiotherapeutic device.

The physiotherapeutic device (see Fig. 1) comprises a housing 1, on the control panel of which channels 2 are located, including four independent channels 2 for connecting therapeutic heads 3 for conducting light-vacuum and electromagnetic therapy and one channel 2 for conducting exogenous therapy. The control buttons and vacuum regulators are not shown in the drawing. The therapeutic head (see figure 2) contains a vacuum applicator 4, a light emitter 5, made in the form of a block of LEDs, an electromagnetic emitter 6, a temperature sensor of the light emitter (DTI) 7 and a sensor of the intensity of the reflected light flux (DIOSP) 8, as well as an electrical wire 9 and a vacuum wire 10 with a filter 11.

The control unit consists (see Fig. 3) of a central processor, made in the form of a single-board computer 12, connected to the controller 13 and the controller 14. The controller 13, connected to the electromagnetic pulse generator 15 and the light pulse generator 16, is designed to control and generate electromagnetic and light pulses. The controller 14, connected to the vacuum pulse generator 17, is designed to generate pneumatic pulses by controlling electro-pneumatic valves using powerful power switches (not shown in the diagram). The therapeutic heads 3 (one therapeutic head is conventionally shown in FIG. 3) are connected to an electromagnetic pulse generator 15, a light pulse generator 16 and a vacuum pulse generator 17 through channels 2 using an electric wire 9 and a pneumatic pipe 10. A temperature sensor 7 of the light emitter 5 and an intensity sensor the reflected light flux 8 is connected to the controller 13. The sensor for measuring the temperature of the body 18 and the heart rate sensor 19 are installed with the possibility of connecting to the controller 14 through the control panel The device located on the housing 1. The device contains an external electromagnetic emitter 20 connected to the controller 13. The housing 1 is made in the form of a case and is equipped with a closing compartment 21 for spare therapeutic heads 3 and replaceable vacuum applicators 4. A monitor 22 is installed in the housing cover 1, made in the form of a TFT panel.

Physiotherapeutic device operates as follows. The therapeutic heads 3 are connected with a vacuum applicator 4 through channels 2 to an electromagnetic radiation generator 15, a light pulse generator 16 and a vacuum pulse generator 17. In this case, the sensors DTI 7 and DIOSP 8 are connected to the controller 13. The body temperature sensor 18 and the heart rate sensor 19 connect to the controller 14 through the connectors on the control panel. Turn on the power to the device.

The individual treatment parameters are set in accordance with the patient’s condition and the program compiled on the basis of the technique: session time, therapeutic frequency, vacuum depth, magnetic pulse frequency. Install vacuum applicators 4 at the treatment site, create a vacuum and carry out the treatment.

When conducting a patient examination, the values of the following parameters are continuously displayed on the display screen: cardiointerval M, heart rate, heart rate, Sigma standard deviation, 7DX variational amplitude, AMO mode amplitude, and Hav rhythm index. In this case, any two indicators can be displayed on the chart.

In the event of a sharp change in the parameters on the monitor screen with an inadequate effect of treatment on the patient's body and the occurrence of physiological overload, the device gives an alarm and automatically turns off all treatment modes. At the same time, the reason for this condition of the patient is reflected on the monitor screen. Thus, the claimed physiotherapeutic device provides effective and safe treatment for the patient.

Clinical example. Under observation were 9 people with a diagnosis of duodenal ulcer. The diagnosis was made as a result of fibrogastroscopy. All patients had clear clinical manifestations of the disease. The treatment was carried out daily for 10 days. A therapeutic head with a red LED emitter located inside the vacuum applicator was installed on the projection of the cubital vein. The following treatment parameters were established: total power of 25 mW, vacuum pulse frequency of 15 pulses / min, light pulse frequency of 9.6 Hz, session time of 15 minutes In addition, the pain zone was illuminated in the area of the stomach and duodenum for 2 minutes for each of 10 points in the area of pain and around it. At the same time, magnetic therapy was carried out with frequencies that suppress the vital activity of bacteria Helicobacter and compilobacter. On 3-4 days, all patients completely stopped the pain syndrome, they felt better, their sleep and appetite returned to normal, and repeated fibrogastroscopy was performed on days 10-12. The phenomena of superficial gastritis and a fresh, non-deforming scar in the area of the ulcer were observed. Two patients did not have a scar.

Clinical example 2. A 62-year-old patient with a diagnosis of coronary heart disease, grade 2 hypertension, post-infarction cardiosclerosis received the following treatment: 10 sessions of light-pulse therapy with a frequency of 89 Hz for 25 min. The projection of the emitter was installed on the cubital vein and was illuminated for 2 min 10 points around the heart muscle. There was a decrease in cholesterol, an improvement in the cardiogram, and a decrease in triglycerides. An ECG revealed an improvement in coronary circulation, improved microcirculation of capillaries according to conjunctival biomicroscopy. The patient noted an improvement in overall health and increased performance.

Claims (5)

1. Physiotherapeutic device comprising a housing and a control unit located therein with light and vacuum pulse generators, therapeutic heads containing a vacuum applicator and a light emitter connected to the control unit by means of electric vacuum wires, characterized in that it further comprises an electromagnetic pulse generator, sensors body temperature and heart rate connected to the control unit, as well as an external electromagnetic emitter for bioresonance apii, connected to an electromagnetic pulse generator, the therapeutic head is equipped with an electromagnetic emitter, a light emitter temperature sensor and a reflected light flux intensity sensor, while the control unit is made in the form of a processor and controllers connected to light, electromagnetic and vacuum pulse generators, the vacuum applicator is removable , the case is made in the form of a case, on the cover of which a TFT-type monitor is located. 2. The physiotherapeutic device according to claim 1, characterized in that the external electromagnetic emitter is made in the form of a belt or loop. 3. The physiotherapeutic device according to claim 1, characterized in that the housing is equipped with a lockable compartment for interchangeable therapeutic heads and vacuum applicators. 4. The physiotherapeutic device according to claim 1, characterized in that the electrovacuum wire, light and electromagnetic emitters are sealed in the body of the therapeutic head with a dielectric compound. 5. The physiotherapeutic device according to claim 1, characterized in that the vacuum wire is equipped with a filter.