RU2145483C1 - Method and device for diagnosing of patient clinical state - Google Patents

Abstract

FIELD: medicine. SUBSTANCE: method and device are intended for diagnostics of number of diseases accompanied by changes in patient internal state. Method consists in computer processing of multiple measurements of patient surface temperature with subsequent presentation of nature and coordinates of pathology in volume of patient's body. High accuracy of diagnostics is conditioned by disease dynamics observation. Device intended for method realization has temperature measurement unit (contact thermometer) connected to unit of main memory, memory unit connected to unit of main memory and to comparison unit, program unit connected to program realization unit and visualization unit. Temperature measurement and main memory units are arranged in autonomous case provided with connector which allows information transfer to computer. Program realization unit executes programs recorded in program unit for processing of obtained data, as a result of which coordinates and nature of pathologies in patient's body are determined. Diagnosis and location of pathology are displayed on computer monitor screen. EFFECT: extended diagnostic capabilities. 10 cl, 2 dwg

Description

 The invention relates to medicine and is intended for promptly diagnosing a patient’s health status, in particular for early detection of neoplasms.

There is a method of diagnosing a patient using a thermal imager, when according to the image of the patient’s temperature field on the device’s screen, a patient’s pathology is judged by a change in temperature relative to a previously established norm / 1 /. However, this method of diagnosis has the significant drawback that, due to the low accuracy of determining the temperature on the surface of the patient’s body, the accuracy of diagnosing and identifying pathologies deeply located in the body is relatively low. With a real error in estimating the temperature in, a qualitative diagnosis of surface temperature requires an accuracy of no worse than 10 ^{-2 o} C / 2 /. The source of an additional and very significant error in this method is the uneven nature of the body surface / the director of the radiation maximum changes with respect to the main optical axis of the thermal imager lens / and the state of the body surface / sweating, hairiness, etc. /, illegally displayed as temperature changes.

 There is also known a method for diagnosing myocarditis with rheumatoid arthritis by changing the temperature on the palm surface of the hand along the meridian of the heart / 3 /. The disadvantage of this method is its specificity for only one type of disease.

The cutaneous method is used for non-invasive diagnosis of neoplasms by the radiation of a pathological focus detected by microwave sensors on the patient’s body / 4 /. However, due to the small / comparatively / sensitivity / 0.1 ^o K / this method does not allow to evaluate the patient's condition over the entire volume of his body. In addition, the device is a rather complex system, although it provides only 12 channels of simultaneous processing.

 Closest to the proposed method and device is a method and device for thermographic examination of patients, which is based on data on the temperature of a network of points coordinated on the patient’s body. By comparing with the reference values, difference values are distinguished according to which a probabilistic diagnosis is established. The device includes a temperature measurement unit, made in the form of a matrix, a RAM unit connected to them, a unit for recording a series of programs, a program implementation unit, a comparison unit and a visualization unit / 5 /.

 The specified method and device can detect a pathological lesion in the patient’s body, but do not solve the problem of determining the depth. This is due to the fact that the basis of the assessment is only the principle of symmetry of the temperature field and the presence of a focus is judged by the violation of this symptom. In addition, the method does not allow a complete examination of the patient’s body with the identification of diseases responsible for the violation of the normal temperature field. The specified device, taken as a prototype, not providing high accuracy of measurement, does not allow to identify small pathological foci at an early stage of the disease. This is due to two factors: 1 - the error of the remote method of measuring temperature and 2 - with several sensors, their individual errors are summed. The device is also bulky, examination can only be carried out in a hospital.

 The technical result achieved through the use of the claimed method and device is to expand the medical diagnostic capabilities, increase its reliability due to the high accuracy of the study.

 The advantages obtained by the implementation of this method and device consists in increasing the efficiency of diagnosing, the possibility of diagnosing in any conditions / at home, in the field, etc. /, the possibility of detecting multiple small pathologies in the entire volume of the patient’s body, while the diagnosis is non-invasive method and does not represent absolutely no harm to the patient, while the low-skilled person can conduct an initial examination. The device that performs the initial examination is portable and relatively cheap, the system of pairing the unit of the initial examination with a computer allows, by improving the database for the patient or to assess a specific type of pathology, to continuously increase the probability of a correct diagnosis, using the computer monitor, a visual representation of the location of pathological lesions in the patient’s body is performed with a simultaneous indication of their coordinates, and it is possible to observe the dynamics of pathology.

где x₀ и y₀ - координаты полюсов изотерм на поверхности тела пациента;
T₀ - значение температуры в точке, соответствующей координате полюса изотерм, ^oC;
x, y - текущие координаты на поверхности тела пациента.The essence of the proposed method is as follows. Diagnosis is carried out in at least two identical steps. The purpose of the first stage is to obtain basic patient data. The purpose of the subsequent steps is to conduct the diagnosis itself. The sequence of the stage: on the patient’s body, in a certain sequence, 200 temperature measurements are taken at certain points - the duration of all measurements together is about five minutes. Each measurement is stored in the memory block of the meter. The very first examination for a particular patient is carried out with his obviously good health and is basic. The results of all these first 200 measurements are recorded in the computer's memory bank. Subsequent or subsequent steps are the actual diagnosis of the patient’s health status. The difference between the subsequent stages from the first is that from the temperature values obtained in the second or subsequent stages of the matrices, the base matrix / obtained at the first stage / is subtracted. Using the obtained difference matrix on the surface space of the simulated body of a particular patient, isotherms are constructed using the closed-flow method, after which their poles on the surface of the said body are determined. In the vicinity of the poles, temperature gradients are estimated. Data on the gradients and coordinates of the occurrence of pathological lesions are determined in accordance with the program, the algorithm of which connects these values with the depth of the lesion. Thus, three-dimensional coordinates of the focus are determined, and consequently, the organs of the patient's body affected by a pathological change. Therefore, in addition to the coordinates, a conclusion is made on the monitor screen about the likelihood of an appropriate diagnosis obtained on the basis of basic studies and thermographic atlases. The algorithm for calculating the depth of occurrence Z ₀ uses the dependence obtained in / 6 /

where x ₀ and y ₀ are the coordinates of the poles of the isotherms on the surface of the patient's body;
T ₀ is the temperature at the point corresponding to the coordinate of the pole of the isotherms, ^o C;
x, y are the current coordinates on the surface of the patient’s body.

Temperature measurements are carried out by the contact method using temperature sensors in the measurement mode, when the accuracy and efficiency of the measurement are stimulated by the measurement mode, in which instead of reaching the asymptotic section of the sensor, the steepness of the derivative with respect to the measurement time is used in the initial portion of the rise / fall / temperature during the measurement,
In addition to the network of coordinate points on the patient’s surface, the measurement is also carried out at a number of characteristic points, where the adequacy of the temperature measurement to the corresponding state of health is essential / for example, some acupuncture points /.

 A device for diagnosing a patient’s clinical condition includes a temperature measuring unit, a random access memory unit connected to it by a communication channel, a program implementation unit, and a comparison unit, a visualization unit, and a program unit connected to it via communication channels. The device is equipped with additional communication channels and a memory unit connected via additional communication channels to the comparison unit and the RAM unit. The temperature measurement unit is made in the form of a contact thermometer, providing the measurement accuracy two orders of magnitude higher compared to the prototype. This is due to the absence of factors masking the temperature change during its assessment by measuring the radiant flux from the patient’s body, as well as due to the simulation of the measured temperature by the slope of its time derivative at the beginning of the measurement cycle. The temperature measuring unit and the RAM unit are located in a stand-alone case. In this case, the communication channel connecting the memory block with the random access memory block can be implemented, for example, in the form of a cable with a connector. The temperature measuring unit may have said communication channel in the form of a radiotelephone channel.

 Supplying the device with the indicated communication channels allows you to expand the device's ability - it can be used outside the hospital, on patient calls, which increases the convenience of its operation.

 In FIG. 1 shows a block diagram of a device for diagnosing a patient’s clinical condition.

 A method for diagnosing a patient’s clinical condition is as follows.

 At the initial, for example, preventive examination, a network of points is planned on the patient's body. This network can be an elastic shirt with holes, it can be realized by projecting onto a patient’s body a network of points with an optical project, the optics of which can scale this network to each specific body / features of the patient’s figure /.

 In accordance with the chosen coordinate system on the body / coordinates x and y / these points form nine circular tiers along the height of the body with a certain step for each tier, so that the formed network of points covers all vital organs in their projections onto the body surface.

 When examining a certain internal organ (for example, the stomach), the points are applied only on a part of the body in the area of the projection of this organ. In this case, characteristic points can also be included in the number of applied points (for example, acupuncture points).

 At each target point, the surface temperature of the skin is measured in a definite and non-changing order; this data is recorded in the RAM of the meter. The information thus obtained is the initial / reference / base for the proposed diagnostic method.

 In case of patient complaints or during repeated examination, performed after a certain period of time, the temperature measurement procedure is repeated exactly.

 After that, the newly obtained database is compared with the base one by one and the pathological changes in the patient’s body are judged by the results of temperature changes. So, malignant neoplasms have an elevated temperature, neurotic pathologies have an elevated temperature. In accordance with this, after converting the network of differential temperatures into fields of isotherms, at the poles of these isotherms there will accordingly be maxima or minima, the coordinates of which on the patient's body will indicate to which vital internal organs these changes correspond. According to the above coordinates, in accordance with the above algorithm, the depth of the pathological focus is determined, which makes it possible to identify the lesion of one or another vital organ of the patient. The nature of the disease is estimated from the data on the temperature of the pathology, its size and location. The technique linking the change in temperature on the patient’s body with the coordinates on the surface of his body is approved by the Ministry of Health of the Russian Federation / 7 /.

A device for diagnosing a patient’s clinical condition includes a temperature measuring unit 1 made on the basis of a contact thermometer with increased accuracy / no worse than 10 ^{-2 o} C /, a random access memory unit 2 connected to a temperature measuring unit by a communication channel 3, a memory unit 4, where information channel 5 transfers information from the RAM block 2, program block 6, the comparison block 7 connected to the memory block 4 by the communication channel 8, which receives information about the database, and the communication channel 9, which receives the result Tata reevaluation unit programs 10, communication channel 12 connected to the comparison unit 7, and a channel 13 makes it possible - with a visualization unit / computer monitor /.

 The temperature measuring unit and the RAM block can be made in a separate case in the form of a stand-alone device 15, and channel 5 - in the form of a cable that can be detachably connecting the device to the memory unit 4.

 In order to examine the largest possible number of patients on call with the same amount of RAM, the device can be equipped with a radiotelephone communication unit. At the same time, the transmitter 16 is located in the device, and the receiver 17 is located in the memory unit 4.

The memory block 4 and the program block 6 can be made in the form of a computer diskette on which are recorded: the necessary information about the patient and the history of his illness, basic data on the temperature network, as well as:
- a program for comparing the bases of reference and current values,
- a program for constructing isotherms from the differential values of the temperature of the matrices and determining the poles of these isotherms,
- a program that implements the calculation of the depth of the focus of the pathology according to the above algorithm,
- A program for recognizing the nature of the pathology and issuing information on the monitor screen.

 The functions of the comparison unit, visualization unit 14, and program implementation unit may be performed by a computer.

 The device operates as follows.

Using the temperature measuring unit 1 in a predetermined sequence, the temperature is measured at the nodes of the coordinate grid and at the characteristic points previously marked on the patient’s body. To accurately measure the temperature and to shorten the examination time, a simulation of the temperature increment is used by measuring the slope of the curve of the temperature increment at the beginning of each measurement, which is equivalent to measuring the temperature at the end of the standard measurement cycle. This principle is illustrated in FIG. 2, by the example of measuring two temperatures T ₁ and T ₂ . Replacing the measurements of T ₁ or T _{2 with a} measurement of temperature increments δT ₁ or δT ₂ , carried out after the time Δt, counted using a crystal oscillator, quantizing the counter in the form of the number of pulses N, gives an order of magnitude more accurate value of the measured value T and the measurement time is reduced a thousand times, which ensures the efficiency of measurements. Here are indicated: T ₀ is the initial temperature, τ is the time constant of the thermometer, t is the current time, ΔT ₁ and ΔT _{2 are} excess values for the measured temperatures, K ₁ and K ₂ are ΔT ₁ / Δt and ΔT ₂ / Δt tending to the angle the slope of the time-dependent temperature rise curves T ₁ and T _2, respectively.

 The temperatures thus measured in the form of a sequence of counting pulses are transmitted via communication channel 3 to the main memory unit 2. The obtained primary temperature data base is transmitted via communication channel 5 to memory unit 4 / to the computer’s diskette /, where the patient information is also recorded.

 Upon repeated examination, the temperature is measured at the same points and in the same sequence as in the previous cycle, and these values are also sent to the memory unit 4. After that, the information obtained again is processed using the comparison unit 7, for which, in accordance with the program from the secondary cycle database, the primary database is subtracted term-by-term and the differential temperature database is formed. This data is transmitted via communication channel 12 to the program implementation block 10, which, using commands from block 6 via channel 11, executes all the commands written on the floppy disk: it builds isotherms, finds the poles of the isotherms and, in accordance with the specified algorithm, determines the sizes and coordinates and the nature of the pathological focus.

 The data obtained in the form of a probabilistic diagnosis, coordinates and sizes of foci depicted on a patient’s body scale are illustrated on a computer screen.

When used as a temperature sensor of a resistance thermometer / τ ~ 1 s / and an intrinsic error of 10 ^{-3 o} C, the duration of a complete examination of the patient together with the diagnosis will not exceed 15 minutes, which makes it possible to use this method and device for mass examination of the population.

 Ultrasound, gamma, and NMR tomographs currently used for similar purposes, for all their advantages, have a harmful effect on the patient with certain radiations acting as tools, and the duration of the examination cycle, as, for example, in the case of tomographs, can reach several hours. As a result of this, and also because of the high cost, they are not used in mass surveys.

 The proposed device is inexpensive, convenient to use. The data recorded on a floppy disk can be processed on a computer in the absence of the patient, which is convenient for both the doctor and the patient.

 The proposed method is harmless, takes a short time in the diagnosis and at the same time gives a high reliability of the diagnosis, can provide mass prevention and examination of the population.

Sources of information taken into account
1. Japanese application N 60-8818, A 61 B 5/00, 1985

 2. Thermal imaging medical equipment and the practice of its application. Leningrad, GOI, 1985, p. 140, L.M. Klyukin, S.A. Kirillov-Postnikov "On the possibility of introscopy for thermal diagnosis of the surface by liquid crystal temperature sensors".

 3. USSR Author's Certificate N 1747024 A 61 B 5/00, 1989

 4. "Raskat" - a multi-channel medical radio-thermal mapping system of the NGO "Vega-M", RF, Moscow, 1994.

 5. US patent N 4310003 A 61 B 5/00, 128/736, 1982

 6. Letters to the Journal of Technical Physics, vol. 6, no. 10, 1980, p. 615-619.

 L. M. Klyukin, V. A. Namiot "On the possibility of detecting a small body in semi-infinite space."

 7. "Instructions for use" of the contact local liquid crystal thermometer for express diagnostics TERMOKON TZhD-01 ", approved by the Ministry of Health of the Russian Federation 02.03.93.

Claims (10)

1. A method for diagnosing a patient’s clinical condition, namely, that the patient’s body temperature is measured at points coordinated on the surface of the body, the data are sent to a memory unit for further processing in order to identify pathological foci inside the patient’s body, characterized in that they perform preliminary basic measurement of the temperature of the points of the patient’s body with a obviously good state of health, compare the current values of temperatures measured at the same points and in the same sequence In this case, as in the baseline examination, isotherms are constructed using the difference between the current and baseline temperatures, the coordinates of the poles of these isotherms are determined, the depth of the pathological focus in the patient’s body is calculated by the formula

where T ₀ is the temperature at the point corresponding to the coordinate of the pole of the isotherms, ^o C;
x, y - current coordinates of the difference field, rel.
x ₀ , y ₀ - coordinates of the pole of the isotherms, rel.
Z ₀ - the depth of the pathological focus, rel.
T is the current value of the difference field, ^o C.  2. The method according to claim 1, characterized in that the network of points at which the measurement is made covers any part of the patient’s body to be examined, or his whole body.  3. The method according to PP. 1 and 2, characterized in that the temperature is measured by the contact method.  4. The method according to claims 1 to 3, characterized in that the temperature is additionally measured at points of the patient’s body, for example, biologically active, according to the temperature of which additional information is obtained on the state of a number of vital organs of the patient’s body.  5. The method according to claims 1 to 3, characterized in that the obtained isotherms are verified in order to increase the reliability of the diagnosis by the criteria of continuity in size and space.  6. A device for diagnosing a patient’s clinical condition, including a temperature measuring unit, a random access memory unit connected to it by a communication channel, a program implementation unit and a comparison unit, a program unit and a visualization unit connected to it via communication channels, characterized in that it is provided with additional channels communication and a memory unit connected via additional communication channels with the comparison unit and the RAM unit.  7. The device according to claim 6, characterized in that the temperature measuring unit is based on a contact thermometer.  8. The device according to PP.6 and 7, characterized in that the temperature measuring unit is equipped with a crystal oscillator with a counter of a fixed number of pulses, after the arrival of the last of which the temperature measurement is stopped.  9. The device according to PP.6 - 8, characterized in that the measurement unit and the RAM unit are located in a standalone housing with the possibility of detachable connection to a computer.  10. The device according to claim 9, characterized in that it is equipped with a radiotelephone communication unit, the transmitter of which is connected to the random access memory unit, and the receiver is connected to a computer.

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