RU2053806C1 - Juna-1 biocorrector - Google Patents

Abstract

FIELD: medical equipment. SUBSTANCE: JUNA-3 biocorrector has radiation transducer unit 1, physiological transducers unit 2, heat-radiation transducer 3, data processing units 4 and 5, converter 6, correction unit 7, control unit 8, initial conditions unit 9. Data processing units 4 and 5 includes amplifiers units 10 and 11, controlled switch gears 12 and 13, memory units 14 and 15, comparison and evaluation units 16 and 17. EFFECT: higher efficiency. 1 dwg

Description

 The invention relates to medical equipment and can be used for therapeutic and prophylactic purposes.

 Known stimulator of June, containing a control unit connected to a correction unit, and a thermal radiation sensor (patent N 1774878, class A 61 N 1/375, 1990) prototype.

 However, this device does not take into account the change in the state of either a single organ to which the impact is directed, or the general functional state of the patient at a given time.

 The proposed biocorrector controls the overall functional state of both the whole organism and individual organs, which allows to increase the range of exposure modes of the device, taking into account individual indicators of the patient’s functional state.

 The specified technical result is achieved by the fact that the proposed biocorrector contains a control unit connected to the correction unit, a thermal radiation sensor, a physiological sensor unit, a radiation sensor unit, two data processing units, a converter and an initial conditions unit, and each of the data processing units contains an amplifier unit , a managed switch, a memory unit, and a comparison and evaluation unit, while the outputs of the radiation sensor unit and the thermal radiation sensor through series-connected amplifier unit, control the inventive switch, the memory unit and the comparison and evaluation unit of the first data processing unit are connected to the first input of the converter, and the outputs of the physiological sensor unit through series-connected amplifier units, the managed switch, the memory unit and the comparison and evaluation unit of the second data processing unit are connected to the second input of the converter in addition, the output from the data processing units of the managed switch is connected to the second input of the comparison and evaluation unit, and the output of the converter is connected to the input of the correction unit while the outputs of the control unit are connected to the control inputs of the amplifier unit, managed switches, memory units and comparison blocks of each of the data processing units, as well as to the control inputs of the correction unit, converter and initial conditions unit, while the outputs of the latter are connected to the initial installation inputs conditions of comparison and evaluation blocks.

 New in comparison with the prototype in the biocorrector is that a physiological sensor block, a radiation sensor block, two data processing blocks, a converter and an initial conditions block are introduced into it, and each of the data processing blocks contains an amplifier block, a controlled switch, a memory block and a block comparing and evaluating, while the outputs of the block of radiation sensors and the sensor of thermal radiation through sequentially connected block of amplifiers, a managed switch, a memory block and a block comparing the estimates of the first data processing unit with connected to the first input of the transducer, and the outputs of the physiological sensor unit through series-connected amplifier unit, a managed switch, a memory unit and a comparison and evaluation unit of the second data processing unit are connected to the second input of the converter, in addition, the output in each of the data processing units of the managed switch is connected with the second input of the comparison and evaluation unit, the output of the converter is connected to the input of the correction unit, while the outputs of the control unit are connected to the control inputs of the units fields, controlled switches, memory units, and comparison and evaluation units of each of the data processing units, as well as with the control inputs of the correction unit, converter, and initial conditions block, while the outputs of the latter are connected to the seedlings of setting the initial conditions of comparison and evaluation blocks.

 The inclusion in the feedback device, which provides the removal of radiation parameters and the patient’s functional state, as well as the assessment of the parameters being removed and their transfer to the biocorrector input, allows to take into account the patient’s functional state at the time of the correction.

 The inclusion in the device of blocks of radiation sensors and physiological sensors installed on the patient, the assessment of attentive parameters and the consideration of the results obtained during the correction process allows you to select exposure modes for each patient individually.

 Thus, the set of essential features of the device allows for the correction of the organ or patient, taking into account their indicators, to provide feedback.

 Currently, it is known that the physical field of biological objects includes infrared (IR) radiation of 8-14 microns, microwave (microwave) radiation in the range of 8-30 cm, alternating electric field with a frequency of 10 Hz and others.

 Therefore, the block of radiation sensors must contain radiation sensors of all ranges in order to provide the most complete information about the organ to which the effect is directed.

 At the same time, when carrying out the correction, it is necessary to take into account the functional state of the whole organism and of a single organ to which the action is directed.

 Based on the foregoing, the block of physiological sensors of the proposed device contains various sensors of physiological parameters, for example, blood vessels, pressure, pulse, respiration and others. Specifically, which of the radiation sensors or physiological parameters will be used at the moment, the biotherapist determines in advance in accordance with the methodology of the exposure and the characteristics of the organ to which the exposure is directed.

 The control unit sets the necessary gain of the parameters to be taken, connects sequentially, according to a predefined program, the radiation sensors and physiological sensors, and also generates the control signals necessary for the operation of the memory blocks, a comparison and evaluation unit, a converter, a correction block, and an initial conditions block.

 The correction unit can be performed similarly to the stimulator described in the prototype.

 The drawing shows a biocorrector Juna-3, a block diagram.

 The device comprises a unit 1 of radiation sensors, a unit 2 of physiological sensors, a heat radiation sensor 3, data processing units 4 and 5, a converter 6, a correction unit 7, a control unit 8, and an initial condition unit 9. Blocks 4 and 5 of the data processing includes, respectively, blocks 10 and 11 of the amplifiers, managed switches 12 and 13, blocks 14 and 15 of the memory, blocks 16 and 17 of comparison and evaluation.

 Biocorrector is used as follows.

 The patient is placed in front of the correction unit. Install radiation sensors and physiological sensors on it according to the selected program.

 In block 9 of the initial conditions, the initial values of all the estimated parameters are set. Connect the device to a power source (not shown in the drawing) and begin the course of exposure according to the program entered into the control unit.

 In the process of correction, to which the influence of radiation sensors and taking parameters from physiological sensors is directed, signals from blocks 1, 2 and 3 of radiation sensors and physiological sensors are fed through amplifier blocks to the input of controlled switches 12 and 13. According to the program of control unit 8, the switches transmit current information signals from each of the sensors to memory units 14 and 15 and comparison and evaluation units 16 and 17. In the latter, the current value of this parameter is compared with its value at the previous moment and the given initial value, coming respectively from memory blocks 14 and 15 and block 9 of the initial conditions. Next, blocks 16 and 17 evaluate the results in accordance with a predetermined algorithm. The results obtained from the outputs of blocks 16 and 17 are fed through a converter 6 to the input of a correction block 7, which changes its output parameters depending on both the program of the current course of exposure and the results of the evaluation of studies of the current functional state of the patient and radiation parameters taken from the patient.

 The proposed biocorrector allows you to increase the effectiveness of the impact both by automating the dosed radiation, and by changing the program of the exposure in accordance with the assessment of the results of the exposure and the general physiological condition of the patient.

Claims (1)

 BIO CORRECTOR JUNA-3, comprising a control unit connected to a correction unit including emitters, characterized in that it further includes a physiological sensor unit, a radiation sensor unit, a thermal radiation sensor, a converter, an initial condition unit and two data processing units, each of which contains the amplifier unit, a managed switch, a memory unit and a comparison and evaluation unit, while the outputs of the radiation sensor unit and the thermal radiation sensor through sequentially connected amplifier unit, the switch, the memory unit and the comparison and evaluation unit of the first data processing unit are connected to the first input of the converter, and the outputs of the physiological sensor unit through series-connected amplifier unit, the managed switch, the memory unit and the comparison and evaluation unit of the second data processing unit are connected to the second input of the converter wherein the output of each managed switch is connected to the second input of the comparison and evaluation unit, and the output of the converter is connected to the input of the correction unit, and the outputs of the unit The boards are connected to the control inputs of the amplifier blocks, controlled switches, memory blocks and comparison blocks of each of the data processing blocks, as well as to the input of the converter and the initial condition block, the outputs of which are connected to the input inputs of the initial conditions of the comparison and evaluation blocks.