RU2208385C2 - Device for determination of condition of biological object - Google Patents

Abstract

FIELD: biology and medicine. SUBSTANCE: the device has a microprocessor, storage unit, display unit, signaling unit, power unit, triggering circuit, digital-to-analog converter, analog-to-digital converter, current regulator, signal conditioner, sensitivity regulator, resistance regulator and a measuring chamber. The latter consists of the main and force-balance, and a tangible transducer. The measuring chamber is made in the form of a sleeve of hydrophobic material with vent holes enveloped by a heat shunt and installed on heat-insulating supports, the sleeve is covered with a heat shield, the tangible transducer is installed at the edge of the sleeve, and the main and force-balance transducers installed in it are separated by a heat mirror. EFFECT: expanded functional potentialities of investigations at determination of the condition of a biological object, simplified investigations and measurement in the real time scale. 3 cl, 2 dwg

Description

 The invention relates to the field of comparative research of biological objects and can be used in biology and medicine.

 Currently, various variants of physical information carriers are offered outside the body of a living organism - from aura to electromagnetic radiation of various ranges. However, a study is more interesting (Science News, 17, 2000, p. 268), according to which the body, like any physical body, creates a concentration from a gas or solution in the boundary layer at the interface, i.e. skin, due to adsorption. Therefore, a method for studying samples of the gas component of a bioobject (GKB) as a real product of vital activity of living matter is proposed. At the same time, one of the most important characteristics of the biological object’s vital processes is the dynamics of the evolution of the gas component by the biological object or the rate of rise of the HCB, the use of which, taking into account calibration coefficients, makes it possible to monitor changes in one or another diagnostic parameter of the biological object. The calibration coefficient of a specific parameter of a bioobject is determined by the ratio of the rate of rise of HCB and the value of a parameter measured after a single exposure to a bioobject with a specific test drug acting on a specific parameter of a bioobject, and the level of the parameter is measured simultaneously by known methods. GKB slew rate measurement is carried out using a specific measuring chamber. Subsequent measurements of the GKB slew rate of this bioobject with the same measuring chamber and the use of the established calibration coefficient make it possible to determine the value of this particular parameter and, thus, monitor the state of the bioobject. Such a calibration factor can be set for many parameters of a biological object that have diagnostic value and standards.

 Known tools for the study of biological objects (see RF patent 2121669, publ. 1998), in which biological samples of the test and control biological objects are burned, the corresponding measurement parameters are formed, they are compared and the state of the biological object under study is determined, for which a measuring chamber is used, the electrodes of which are connected to a power source.

 Known means do not determine the state of a biological object by the organic gas component emitted by the skin of the studied object, as well as the dynamics of the release of the gas component by the biological object, do not allow to monitor certain parameters of the biological object and are difficult to implement.

 The objective of the present invention is to develop simple means for determining the state of a biological object based on the analysis of the gas component emitted by it, the dynamics of the evolution of the gas component of the biological object and the use of the rise rate of the gas component of the biological object to monitor certain parameters of the biological object.

 The technical result consists in expanding the functionality when determining the state of a biological object by studying the parameters of the gas component of a biological object, the dynamics of the gas component of a biological object and using the rate of rise of the gas component of a biological object to monitor specific parameters of a biological object, simplifying the method of determining the state of a biological object and monitoring individual parameters of a biological object and real-time measurements.

 The result is achieved in that in the device for determining the state of a biological object containing a measuring chamber, the electrodes of which are connected to a power source, the measuring chamber is made in the form of a glass with ventilation holes in the bottom, covered with a heat shield, surrounded by a thermal shunt and mounted on heat-insulating supports, the electrodes are made in the form of the main and compensating thermocatalytic sensors installed in the glass and separated by a heat shield, installed on the wall of the glass as a powerful sensor connected to a microprocessor connected to an indication unit, a memory unit, an alarm unit, a trigger element and a digital-to-analog converter, some of the terminals of the compensating and main thermocatalytic sensors are connected respectively to a current regulator and a resistance regulation unit, and other conclusions are combined and connected to a signal conditioner and sensitivity adjustment unit, the power source is connected to a current stabilizer and a resistance regulation unit, the output of which is connected n with a signal shaper connected to the microprocessor and the sensitivity control unit, a digital-to-analog converter is connected to a current stabilizer.

 A specific, but not limiting, embodiment of the device is shown in FIGS. 1, 2, which show a microprocessor 1, a memory unit 2, an indication unit 3, an alarm unit 4, a power unit 5, a trigger element 6, a digital-to-analog converter 7, and an analog- digital converter 8, current stabilizer 9, signal driver 10, sensitivity controller 11, resistance controller 12, measuring chamber 13, main and compensating thermocatalytic sensors 14, 15, tactile sensor 16, measuring chamber is made in the form of stacks 17 of a hydrophobic material with ventilation holes 18, 19 surrounded by a thermal shunt 20 and mounted on heat-insulating supports 21, the glass is covered with a heat shield 22, a tactile sensor 16 is installed on the edge of the glass, the main and compensating thermocatalytic sensors 14, 15 are installed in the glass, separated thermal mirror 23, shutter 24 glasses.

The shunt 20 is made of metal with high heat capacity and serves to delay the passage of heat flow of the test body (37 ^o C).

 The thermal mirror 23 is made of metallized plastic to eliminate heat exchange between the sensors 14, 15 in the infrared range. The sensor 15 serves to exclude the influence of the temperature gradient of the body and compensates for temperature drifts in the medium of the measuring chamber 13, not associated with the receipt of HKB.

The essence of the invention consists in burning the gas component of the control and studied biological objects - the atmosphere and the person, the formation of measurement parameters - U _sensors , and the activity of the zone from which the gas component of the biological object (GCB) was removed is determined by the difference in parameters. At the same time, it is taken into account that the signal during the burning of human HCB is always higher than the signal when burning the HCB atmosphere, because in the HCB of a person contains organic components. Carrying out a step-by-step study of the skin, establish the distribution of the areas of allocation of HCB and the zone with the highest level of allocation of HCB - these are the palms of the hands and soles of the feet. In these zones, the speed of reaching the maximum value of the measurement parameter is measured, it is recorded as the rate of rise of the gas component of the biological object. When conducting tests for various drugs and other forms of exposure to specific diagnostic parameters of a biological object, they simultaneously determine the level of the measured parameter by known methods and simultaneously record the rate of rise of the gas component of the same biological object using a specific measuring chamber. From the ratio of the slew rate of the gas component and the measured value of the parameter, a calibration factor is determined for this characteristic. Subsequent measurements of the GKB slew rate of this bioobject with the same measuring chamber and the use of the established calibration coefficient make it possible to determine the value of this particular characteristic and, thus, monitor the state of the bioobject. Such a calibration factor can be set for individual specific parameters of a biological object that have diagnostic value and standards.

 The device operates as follows. After power is turned on by element 6, the microprocessor 1 sets the “Warm-up” operating mode, in which the signal taken from the sensors 14, 15 is transmitted through the former 10 to the input of the analog-to-digital converter of the microprocessor 1, which converts the signal with a frequency of 1 kHz into a digital code fed to the microprocessor .

 The microprocessor 1 through the converter 7 by the stabilizer 9 sets in the sensors 14, 15 the current necessary for the mode adequate to the combustion temperature of the investigated component of the circuit.

 Every second, the digital code of the signal of the shaper 10 is compared with the data of the previous account, and with a difference of more than 0.1 mV, the current adjustment in the sensors 14, 15 is repeated until the signal value <0.1 mV, which will correspond to the established thermal regime of the measuring chamber . After that, the microprocessor 1 will give the user through block 4 a sound signal about readiness for work. Then, by the regulator 12, the voltage on the converter 8 is set close to zero and is displayed in block 3. The "Measurement" mode starts.

The investigated body surface is placed by this signal on the screen 22 of the measuring chamber 13, the signal from the sensor 16 is recorded by the microprocessor 1 as the beginning t _o of measurement with recording in the arithmetic-logical unit (ALU) of the microprocessor 1 the signal value taken from the former 10. Upon receipt of fuel components of the HKB to the sensor 14 due to their combustion, a temperature occurs above a value determined by the current of the stabilizer 6, and its (sensor) resistance increases.

An error signal appears on the shaper 10, which is amplified and fed to the ADC 8. A digital code corresponding to the increased value of the signal is entered into the ALU of the microprocessor 1, where the values of the ADC counts are summarized 8. After every second, the ALU of the microprocessor 1 compares the data with the previous value of the ALU, continuing this iterative process until the signal level drops below 1 mV. This corresponds to the thermo-equilibrium state of the gas mixture in the measuring chamber 13, when the temperature increase due to the combustion of gases is compensated by the increasing influence of the thermal conductivity of the combustion products having a lower molecular weight. The amplitude value of the measurement parameter U _{sensors is} fixed. Carrying out a step-by-step study of the skin, establish the distribution of the areas of allocation of HCB and the zone with the highest level of allocation of HCB - these are the palms of the hands and soles of the feet. In these zones, the speed of reaching the maximum value of the measurement parameter is measured, it is recorded as the rate of rise of the gas component of the biological object. For this, along with fixing the time t ₀ , the time t _{1 is} also fixed by the microprocessor 1, and the GKB burning time is formed (t _gop = t ₁ -t ₀ ). At the same time, the amplitude value of the parameter U _sensor.max = A _max is fixed and the rate of rise of the _HKB is determined as V = A _max / t _gop .

 At the signal of block 4, a command is issued to remove the body surface from the screen of the measuring chamber 13.

After opening the measuring chamber 13, the gas component leaves its volume, the signal at the input of the former 10 begins to fall. The microprocessor fixes its lower minimum value U _sensor.min = A _min at the moment of the occurrence of thermal equilibrium in an open measuring chamber.

 Microprocessor 1 makes corrections to the value of the slew rate of HKB V due to the low rate of change of the signal near the points of thermal equilibrium. Data on the value of the slew rate of the HKB are displayed in block 3 and recorded in block 2 as data of the current speed value.

 In the "Analysis" mode, the microprocessor 1 provides a comparison of the current speed with the average values accumulated in block 2 for this patient for a certain period of research. After analyzing this data, the microprocessor program 1 updates this data.

 In order to quickly monitor the various characteristics of bioobject homeostasis using the rate of rise of HCB, it is necessary to formulate calibration coefficients. For example, when conducting a test for glucose exposure, which determines the blood sugar level, the sugar level is simultaneously determined by the ONE NOUCH glucometer and simultaneously the slew rate of the gas component of this bioobject is recorded using the measuring chamber 13. The calibration coefficient is determined from the slew rate of the gas component and the measured parameter value K for this parameter. Subsequent measurements of the rate of increase in HCB of this biological object and the use of the established calibration coefficient K allow us to determine the sugar content in the blood at each measurement and, thus, monitor the state of the biological object, moreover, by a non-invasive method. Such a calibration factor can be set for any specific parameter of a bioobject having diagnostic value and standards, such as cholesterol, adrenaline, insulin, etc. The limit values of the parameters are entered into the memory unit 2, and when their values are exceeded, the microprocessor 1 gives the user, through unit 4, an audio signal about the critical value of the parameter.

 The volume of memory unit 2 allows you to accumulate data on many patients on one device.

 Thus, the advantages of the invention are to expand the functionality in determining the state of a biological object by studying the parameters of the gas component of a biological object, the dynamics of the gas component of a biological object and using the rate of rise of the gas component of a biological object to monitor certain parameters of a biological object, simplifying the means of determining the state of a biological object and monitoring individual bioobject parameters and real-time measurements, which can significantly increase the diagnostic value of the study of the parameters of HCB and use it in a domestic environment.

Claims (3)

 1. A device for determining the state of a biological object, containing a measuring chamber, electrodes and a power source, characterized in that the measuring chamber is made in the form of a glass of hydrophobic material with ventilation holes in the bottom, covered with a heat shield, surrounded by a thermal shunt and mounted on heat-insulating supports, the electrodes are made in the form of a main and compensating sensors installed in a glass and separated by a thermal screen-mirror, a tactile sensor is installed on the glass wall connected to a microprocessor that is connected to an indication unit, a memory unit, an alarm unit, and a digital-to-analog converter, some of the terminals of the compensating and main sensors are connected respectively to a current stabilizer and resistance regulator, while the other conclusions are combined and connected to a signal former and sensitivity regulator, power supply connected to a current stabilizer and a resistance regulator, the output of which is connected to a signal conditioner connected to a microprocessor and a regulator and void, a digital to analog converter connected to the current stabilizer.  2. The device according to claim 1, characterized in that thermocatalytic sensors are used as the main and compensating sensors.  3. The device according to claim 1, characterized in that the heat shield-mirror is made of metallized plastic.

Images