RU2039580C1 - Apparatus for luminous therapeutic irradiation of human organism - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: this apparatus includes control unit, radiating source, irradiated surface, reflected ray transducer, transducer signal strength measuring unit, keyboard unit (selector), and display unit. Disclosed apparatus further incorporates sources of therapeutic light, sources of point acupunctural and electric-current treatment, auxiliary reflected radiation transducers, reflexotherapeutic feedback transducers, biological feedback transducers, psychotherapeutic treatment unit, control unit, and auxiliary feedback transducer signal measurement unit. Sources of physiotherapeutic effect are constructionally combined with respective transducers to make up final physiotherapeutic treatment device. EFFECT: more sophisticated design. 1 dwg

Description

 The invention relates to medical equipment, in particular to devices for therapeutic treatment of pathological foci with light radiation (one-component or in various combinations, including with other types of therapeutic effects).

A device for a physiotherapeutic complex effect, both in combination with several types of radiation, and with other types of physiotherapeutic effects (magnetic field, electric field, etc.) [1]
Also known is a therapeutic laser apparatus comprising a network switch, several laser probes excited by electric current, several cables for connecting laser probes to a network switch, and a control unit with a unit for setting the time and radiation power for each probe [2]
The closest in technical essence to the invention is a device [3] containing a control unit, a monochromatic radiation source connected to the control output of the control unit, the output radiation of the source is directed to the irradiated surface of the pathological focus, from which the radiation is reflected and fed to the input of the feedback photometric sensor, the output of which is connected to the input of the reflected signal measuring unit, the output of which is connected to the input of the calculation unit, and the output of the latter is corrective At the entrance to the control unit. The outputs of the setter (keyboard block) are connected to the control inputs of the control unit, and the display and signaling organs (display unit) are connected to the information outputs of the control unit.

 An advantage of the prototype device over other analogues is the presence of adaptation to a change in the reflectivity of the surface of the pathological focus during the irradiation session, which increases the accuracy of the dosage of light exposure.

 However, the lack of consideration of the initial level of reflection does not allow to accurately dose the amount of absorbed light energy (which is a direct factor in the therapeutic light exposure); the inability to specify a combination of several simultaneously acting types of light or other therapeutic effects does not allow optimal use of the most effective mechanisms of biological and physiological effects for various types of pathology and individual characteristics of the patient; the lack of deeper feedback that takes into account the biological rhythms and physiological phases of the patient’s life; the absence of psychotherapeutic effects that activate the protective forces of the patient's body during the therapeutic effect. This limits the functionality of the prototype device and its scope in practical medicine.

 The objective of the invention is to expand the functionality of the device and the expansion of its clinical application in practical medicine.

 This is achieved by the fact that in the apparatus of therapeutic light irradiation of a person, comprising a control unit, a radiation source, an irradiated surface, a reflected radiation sensor, a sensor signal measuring unit, a setter and an indication unit, additional sources of monochromatic and broadband radiation, sources of point light exposure to the points are introduced acupuncture, reflexology probes for electric shock, additional reflected radiation sensors, feedback sensors of reflexology circuits, sensor biological feedback, psychotherapeutic impact unit, source control units, additional signal measurement units from feedback sensors, and in each light therapy channel, radiation sources are structurally combined with a reflected radiation sensor in one unit, and point radiation sources are structurally combined with reflexotherapy probes electric current in one unit located in a device such as a suction cup for installation on acupuncture points. At the same time, the impact control units are digital-to-analog converters, blocks of measuring signals from sensors are multi-channel analog-to-digital converters. The block of psychotherapeutic influence contains mainly sequentially connected speech synthesizer and headphones. The control unit is a microprocessor with calibration tables of control characteristics, to the interface bus of which analog-to-digital and digital-to-analog converters are connected.

 In addition, a recording unit, a programmable read-only memory device and a speech synthesizer are introduced into the device, and for monitoring the device is equipped with calibrated reflectors installed in single blocks of light therapy channels, simulators of acupuncture control points and simulators of biologically active zones.

 The drawing shows a block diagram of the apparatus.

 The device comprises a control unit 1, a source 2-1 of monochromatic and broadband radiation and light exposure, additional sources 2-2 to 2-N of monochromatic and broadband radiation and light exposure, the irradiated surface 3, a sensor 4-1 of reflected radiation, additional sensors of reflected radiation from 4-2 to 4-N, blocks 5-1, 5-2, 5-3 signal measurements made on the basis of multi-channel analog-to-digital converters, master 7 (keyboard block), display unit 8, and in each channel light source therapy Emissions from 2-1 to 2-N are structurally combined with the corresponding reflected radiation sensors 4-1 to 4-N in one unit and form the terminals 9-1 9-N, and the sources of point radiation 10-1 10-N are combined structurally with probes 11-1 11-N for reflexotherapy with electric current in one block and form respectively the terminal devices 12-1 12-N, located in a device such as a suction cup for installation on acupuncture points 13-1 13-N, and through them on the sensors Feedback 14-1 14-N.

 Sensors 15-1 15-N biological feedback connected to the simulators 16-1 16-N biological active zones. In this case, the impact control units are digital-to-analog converters (DACs) 17 and 18 connected via a system bus 19, which use the interface bus of the microprocessor of the control unit 1.

 Analog-to-digital and digital-to-analog converters, a speech synthesizer 20, a recording unit 21, a programmable read-only memory (EPROM) 22 are connected to the interface bus 19. A psychotherapeutic block 23 and an audible signaling unit 6 are connected to the outputs of the speech synthesizer 20.

 The control unit is built on the basis of a serial microprocessor. The speech synthesizer 20 is a serial connection of the EPROM and the DAC, while the EPROM contains sequentially selected by commands from the control unit codes converted at the output of the DAC into analog audio signals.

 The block of psychotherapeutic influence 23 is a headphone worn on the patient’s ears and connected to the output of the DAC of block 20. The analog audio signals from the output of block 20 are converted in the headphone of block 23 into tests of speech psychotherapeutic effect, which are perceived by the patient’s hearing organs and mobilize defenses organism to a more active perception of the set of specified physiotherapeutic effects.

 The blocks of analog-to-digital converters of the ADC (5-1, 5-2, 5-3) and the DAC units (17-18) are well-known technical solutions based on the serial integrated circuits of the ADC and DAC, differing only in matching circuits with the system bus 19 of the device and with plug-in terminal blocks. Blocks of terminal devices 9-1 9-N channels 1-N of therapeutic light exposure are irradiator designs including light sources (lasers, semiconductor laser diodes, light emitting diodes, broadband sources of ultraviolet, visible and infrared radiation) and photometric feedback sensors, moreover, the optical axis of the radiation sources and sensors are combined so that the radiation zone of the source and the field of view of the sensor are combined, and the distance from the centers of the sources and sensors to the irradiated surface 3 was constant. As the irradiated surface, when monitoring the device, special calibrated reflectors are used, which are included in the delivery set of the device (Fig. 1) and are installed before monitoring on the aperture of terminal devices 9-1 9-N.

 The terminal devices for the acupuncture channels 12-1 12-N are, for example, metal point probes 11-1 11-N with the optical fibers of the point sources 10-1 10-N placed in them, structurally combined with a device for fixing the probes when finding points acupuncture 13-1 13-N on the patient's body.

 Electric circuits of direct current reflexology are closed due to the installation of special feedback sensors 14-1 14-N on the patient's body. When monitoring the operability of reflexology channels, blocks 12-1 12-N and feedback sensors 14-1 14-N are connected to a special simulator of acupuncture points 13-1 13-N, simulating the functions of the chains of sensitive points 13-1 13-N of a patient during reflexology.

 As a biologically active zones 16-1 16-N with a complex therapeutic effect can be used, for example, fingers of the wrist, sections of veins and arteries, chest, neck, etc. When monitoring the device, the biological feedback sensors 15-1 15-N are installed on the biorhythm simulator 16-1 16-N, which are included in the delivery of the device.

 The device operates in control and therapeutic modes. Before the monitoring mode, the terminal devices of the light therapy channels 9-1 9-N are installed with apertures on the reflecting surfaces of 3 calibrated reflectors from the apparatus set, the terminal devices of the acupuncture channels 12-1 12-N and the feedback sensors 14-1 14-N are connected to the point simulator acupuncture 13-1 13-N, biological feedback sensors 15-1 15-N to simulators 16-1 16-N biorhythm signals.

In the manufacture of control unit 1, calibration tables of control characteristics (V _in / n _out ) of exposure sources 2-1 2-N, 10-1 10-N, 11-1 11-N and characteristics and sensitivity (n _I / V _o ) feedback sensors 4-1 4-N, 14-1 14-N, 15-1 15-N for all channels and all types of influences, as well as parameters of the reflecting surface 3 calibrated reflectors, parameters of the simulator of acupuncture points 13-1 13 -N and simulator 16-1 16-N biorhythm signals.

On command from the setter 7, the control unit 1 begins the implementation of the program of the built-in health monitoring of the apparatus (Fig. 1), according to which, through the system bus 19, codes of control of radiation sources 2-1 2-N, 10-1 10- are received on the corresponding DACs 17 and 18 N and current sources 11-1 11-N. Through the calibrated reflecting surface 3, the reflected radiation from sources 2-1 of the 2-N light exposure channels is supplied to the sensors 4-1 of the 4-N of the corresponding terminal device (unit) 9-1 9-N. The signal V _o from the output of the sensors 4-1 4-N goes to the corresponding input of the ADC 5-1, the code of which through the system bus 19 enters the control unit. Last compares the code V _O with a reference value previously poised in its memory, it determines matching tolerances, and repeats the control procedure for the next transmit power levels. The control procedure covers the entire dynamic range of influences and the entire set of connected channels 9-1 9-N.

 Similarly, the monitoring of the performance of acupuncture channels and the control of the biofeedback circuit are performed.

 Control of the channel of psychotherapeutic influence (blocks 20 and 23) can be carried out by automated or automatic methods. In the first case, the medical worker, using the control unit 7, starts monitoring the audio effect and, using the terminal device 23, listens to the text of the psychotherapeutic effect, after which the response from the control unit is entered through the control unit 7 via the control unit 7 and displayed on the request. With automatic output of block 20 is connected to the additional input of a multi-channel ADC 5-3 and the control procedure is performed according to the program, as for other channels of therapeutic exposure.

 Upon completion of the control procedure, the control unit 1 provides information on the operability of the channels and the apparatus as a whole tested on the display unit 8, on the basis of which the attending physician can choose the tactics for using the apparatus. In accordance with current clinical methods, individual patient data and the type of pathology, the doctor selects the types of therapeutic effects, types of terminal devices, connects the terminal devices to the patient, sets the therapeutic effect modes for each channel using the dial (type of exposure modulation, intensity, duration) , sets the degree of synchronization between the channels of various types of therapeutic effects, as well as their synchronization with respect to biorhythms (phase of cardiac activity spine, respiration phase), after which it launches a program of complex therapeutic effects.

 The complex therapeutic treatment procedure is carried out automatically according to the program under the control of the microprocessor included in unit 1. During the treatment, a change in the patient's condition (change in the reflectivity of the irradiated surface 3 of the pathological focus, change in conductivity in the region of acupuncture points 13-1 13-N, change in the state biologically active zones 16-1 16-N). These changes are promptly taken into account during a session of complex therapy by adjusting the intensity of the corresponding effects. This ensures optimal adaptation to a particular patient (selection of an individual set of types of effects), improves the accuracy of dosage of effects (adjustment of exposure levels by promptly taking into account changes in the patient's condition using all types of feedback, as well as by preliminary calibration of the device), and also increases the effectiveness of treatment (due to the activation of protective vitality with the help of coordinated psychotherapeutic and physiotherapeutic influences, as well as due to syn ronizatsii plurality of therapeutic effects between themselves and with the phases of the biological activity of the patient's body).

 The application of the proposed multifunctional device will allow to unify and typify the applied and developed methods of complex light therapy. In turn, this will make it possible to use them more widely in practical medicine, to reduce the time for rehabilitation of patients with a decrease in the number of pharmacological drugs used. A high degree of automation and the presence of built-in performance monitoring makes the device available for use by practitioners of average skill.

 The effectiveness of the apparatus is not the sum of the efficiencies of its constituent parts, but is the result of their relationship and interaction. The apparatus, in addition to the therapeutic functions of a comprehensive physiotherapeutic treatment using individually selected combinations of light therapeutic effects together with other types of therapeutic effects, can perform the functions of diagnosing a patient's condition to clarify the tactics of subsequent therapeutic treatment.

Claims (1)

 HUMAN LIGHT THERAPEATIC RADIATION APPARATUS, comprising a control unit, a radiation source, a reflected radiation sensor, a sensor signal measuring unit, a setter and an indication unit, characterized in that a number of additional sources of monochromatic and broadband radiation and sources of point light exposure to acupuncture points are introduced into it, probes for reflexology with electric current, additional sensors of reflected radiation, feedback sensors of reflexotherapy circuits, biological sensors fraternal communication, block of psychotherapeutic influence, control blocks of exposure sources, additional blocks for measuring signals from feedback sensors, and in each channel of light therapy, radiation sources are structurally combined with a reflected radiation sensor in one unit, and point radiation sources are structurally combined with electric reflexotherapy probes current in one unit located in a device such as a suction cup for installation on acupuncture points, while the exposure control units are digital-to-analog converters, blocks for measuring signals from sensors are multichannel analog-to-digital converters, the psychotherapeutic block contains mainly speech synthesizers and headphones, the control unit is a microprocessor with calibration tables of control characteristics, analog-digital are connected to the interface bus and digital-to-analog converters, recording unit, programmable constant remembers apparatus and a speech synthesizer, and for the control device is provided with calibrated reflector positioned in channel blocks of uniform light therapy simulators control points of acupuncture and simulants biologically active zones.

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