JP4238140B2 - Biological electrical characteristic value measuring apparatus and meridian organ function diagnostic apparatus - Google Patents

Description

Technical field
The present invention relates to a technique for measuring electrical characteristics of a living body from a response current when a step voltage is applied with a pair of electrodes attached to the living body, and a technique for diagnosing meridian organ function of the living body from the electrical characteristics.
Background art
In the field of oriental medicine, the existence of a meridian system stretched throughout the body of the human body is recognized, and the state of organs and motor organs is thought to be closely related to meridians. Organ and musculoskeletal diseases are considered to appear as abnormal meridians. By finding a meridian acupuncture point in an abnormal state and applying stimulation to it with needles, heat, electricity, etc. Indirect treatment of the disease is performed.
However, since there are countless acupoints in the human body, it is difficult to find acupuncture points in an abnormal state. For this reason, in general, as an initial step of diagnosis in oriental medical treatment such as acupuncture and hemorrhoids, the arrangement of acupoints that are related in nature, that is, the meridian strength (falseness) is determined. As a machine for assisting such oriental medical treatment, a device for measuring the response current when a step voltage is applied to the acupoint and measuring the truth of the meridian has been put into practical use. It is empirically known that if the meridians are abnormal, the waveform of the response current when a step voltage is applied to the acupuncture changes, and the above device has been developed based on this empirical rule. Conventionally, various methods have been proposed as methods for judging meridian abnormality from the measured response current. For example, the device disclosed in Japanese Examined Patent Publication No. 2-33381 calculates a feature value as a point of diagnosis from the measured response current as numerical data, and includes a step as shown in the graph (a) of FIG. From the waveform of the response current shown in the graph (b) of FIG. 11 obtained when a voltage is applied, the peak value (initial current value) I_P, Stable value I when polarization occurs_S, Polarization time T from the peak value to the stable value (= t_S-T_P), Five parameters of fluctuation time area (total amount of mobile charge) IQ and tangent slope tan θ (= di / dt) at an arbitrary time with respect to the current waveform are calculated as diagnostic data, and the calculation result is displayed on the display. In addition, the apparatus disclosed in Japanese Patent Application Laid-Open No. 8-168469 is focused on the fact that the average waveform obtained by averaging the waveforms obtained by a plurality of acupoints hardly changes even when there is an abnormality in any of the meridians. By displaying the acupuncture point waveform to be diagnosed in comparison with the average waveform, it is possible to determine a meridian abnormality from the waveform shape itself.
By the way, in Oriental medicine, the concept of “Yin Yang” and the concept of “virtuality” are used to express the health balance of the body. “Yin-yang” indicates the constitution, and “false” indicates the presence or absence of physical strength. In addition, the activity of the human body is expressed by the concept of “ki”. In Oriental medicine, “ki” is the health of the human body, and the activity indicating the metabolic rate and immunity. It is divided into the cheerfulness that is, and Yin Yang is discussed from the strength of each. Therefore, in order to perform appropriate oriental medical treatment, accurate determination of these “yin and yang” and “false” is necessary.
However, the above-described conventional apparatus can make a vague diagnosis of “virtuality” indicating physical strength, but cannot diagnose “yin-yang” indicating physical constitution. This is not only a medical reason that the human body was not adequately characterized by classification and comparison of glory and health, but with conventional devices, measurement that can accurately determine “Yin-yang” and “Fairness” is possible. There is also a technical reason that data cannot be obtained. For example, in the apparatus disclosed in Japanese Examined Patent Publication No. 2-3338, a plurality of parameters are listed as diagnostic data. However, for a diagnostic method using these parameters, the peak value I_PIt is not specifically shown except. Further, in the apparatus disclosed in Japanese Patent Application Laid-Open No. 8-168469, the presence or absence of meridian abnormality can be determined by comparison with the average waveform, but it must be a subjective and vague determination.
Under such circumstances, the inventor of the present application first studied what useful data can be obtained from the response current when the step voltage is applied. Here, the schematic diagram shown in FIG. 12 is a diagram showing the principle that a response current flows when a step voltage is applied to the skin. As shown in FIG. 12, the human skin has a two-layer structure of an epidermis 100 that is a stratum corneum and a dermis 101 through which blood flows, and the epidermis 100 and the dermis 101 are separated by a basement membrane 102. Yes. When a pair of electrodes 110A and 110B are attached to the surface of the skin, that is, the surface of the epidermis 100, and a step voltage is applied between the electrodes 110A and 110B, the current enters the epidermis 100 from the positive electrode 110A and passes through the basement membrane 102. It flows into the dermis 101. Then, the current flows through the dermis 101 and again flows from the epidermis 100 to the negative electrode 110B through the basement membrane 102. At this time, a charge (Na⁺, Cl⁻Etc.) accumulates and polarization occurs, and the response current gradually decreases.
FIG. 13 replaces the above principle with a circuit diagram. The resistor 120 in FIG. 13 corresponds to the resistance in the dermis 102, and the resistor 122 and the capacitor 121 correspond to the electric resistance and electric capacity of the basement membrane 102, respectively. Of these three elements, in particular, the resistance of the dermis 102 (resistance 120) is the electrical resistance of the extracellular fluid in the body, and its resistance value R₀It is expected that the metabolism of the body will be shown. Further, the electric capacity of the basement membrane 102 corresponds to the amount of electrolyte in the vicinity of the basement membrane, and it is expected that the excess or deficiency of the electrolyte in the body will be indicated by the capacitance value C. At this time, the electric capacity 123 in the dermis 102 indicated by a broken line can also be taken into consideration. However, since this capacity is sufficiently large, it is usually unnecessary to consider its influence.
When considered in relation to the above-mentioned “Yin Yang”, the electrical resistance of the extracellular fluid is considered to be the likelihood of chemical changes in the body, that is, the life activity environment. It can be interpreted as showing the truth of In addition, the amount of electrolyte in the vicinity of the basement membrane is considered to be the degree of extracellular environment, that is, the activity of cells on the peripheral surface. Can be interpreted. In this way, the inventor models the resistance value R of the resistor 120 by modeling the skin into an electrical equivalent circuit as shown in FIG.₀Thus, it has been found that it is possible to quantitatively diagnose the trueness of gloomy and quantitatively diagnose the trueness of cheerfulness by the capacitance value C of the capacitor 121.
Next, the present inventor makes the above-mentioned resistance value R₀And earnestly researched about the measuring method of capacitance value C. As a result, it was found that measurement can be performed by the following method. First, when a step voltage is applied to the circuit of FIG. 13, the waveform of the response current obtained is very similar to the waveform of the response current when the step voltage is applied to the skin (the waveform shown in the graph (b) of FIG. 11). ing. This means that the circuit of FIG. 13 properly represents the electrical characteristics of the skin. When the waveform shown in the graph (b) of FIG. 11 is considered as a response current waveform when a step voltage is applied to the circuit of FIG._PUsing the following equation (1), the resistance value R₀Can be expressed.
I_P= E / R₀  ... (1)
This initial current amount I_PIs listed as one of the diagnostic parameters in the device disclosed in Japanese Patent Publication No. 2-33381. In Equation (1), E is the voltage value of the applied step voltage.
On the other hand, the capacitance value C can be expressed by the following formula (2) using the variation time area IQ.
IQ = E × C × R²/ (R + R₀)²  ... (2)
This variation time area IQ is also listed as one of diagnostic parameters in the conventional apparatus disclosed in Japanese Patent Publication No. 2-33381. Therefore, the resistance value R, which is the judgment data for “Yin-yang”, can be obtained using the parameters obtained with the conventional apparatus.₀It is also considered that the capacitance value C can be measured. However, as can be seen from equation (2), in order to obtain the capacitance value C using the variation time area IQ, it is necessary to obtain the resistance value R of the base film 102. This resistance value R is the resistance value R of the dermis 101.₀And stable value I when polarization occurs_SThe resistance value R can be obtained using₀The fluctuation rate is large compared to, and always includes a certain amount of error. Further, the fluctuation time area IQ itself obtained from the waveform diagram includes a considerable error. Therefore, the capacitance value C cannot be accurately measured by the method obtained from the variation time area IQ shown in the equation (2).
In addition, when the electric capacity 123 of FIG. 13 is considered, it is considered that the response current continues to be gradually attenuated from the beginning of voltage application even after the polarization is completed by the electric capacity 121 on the skin surface. When the fluctuation time area IQ is calculated as the total sum of the actual measurement values, an error due to the gentle attenuation becomes large.
The present invention was devised in view of the above problems, and the electric characteristics indicating the electric capacity of the basement membrane when the skin of a living body is modeled by a three-element circuit, that is, the amount of electrolyte in the vicinity of the basement membrane. An object of the present invention is to provide a measuring apparatus capable of accurately measuring a value.
It is another object of the present invention to provide a diagnostic apparatus and a diagnostic program that can accurately diagnose the state of meridian organ function using the measurement result of the electrical characteristic value.
Disclosure of the invention
As a result of diligent research, the present inventor calculated the basement membrane capacitance value C from the initial current change amount di (0) / dt as shown in the formula (3), and thereby caused the resistance of the basement membrane having a large variation rate. It has been found that the capacitance value C can be accurately measured without being affected by errors.
di (0) / dt = E / (C × R₀ ²) = I_P ²/ (C × E) (3)
According to this calculation method, since the capacitance value C of the basement membrane can be measured immediately at the initial stage when the step voltage is applied, it is not necessary to measure until the polarization occurrence time as in the prior art. There is also an advantage that external influences in time and influences of fluctuations in electrical characteristics in the body can be ignored.
Furthermore, even if the electric capacity in the dermis is taken into account, the initial decay of the response current due to this electric capacity is moderate, and according to the above calculation method, the capacitance value C hardly includes an error. In addition, when the capacitance in the dermis is taken into account, it is conceivable to calculate the capacitance value C by comparing the polarization due to the capacitance of the basement membrane and the polarization due to the capacitance in the dermis. It is necessary to continue to apply voltage until time, and there is a risk of causing fluctuations in electrical characteristics in the body. On the other hand, according to the calculation method, such a problem does not occur.
A first electrical characteristic value measuring apparatus according to the present invention uses the above-described calculation method, and applies a voltage that applies a step voltage between a pair of electrodes that are mounted on the skin of a living body as in the prior art. An initial current amount measuring means for measuring an initial current amount of a response current flowing between the electrodes when a step voltage is applied by the voltage applying means, and an initial change amount of the response current per predetermined time. It has an initial current change amount measuring means to measure, and furthermore, a data creation means for creating measurement data as a function of a value obtained by dividing the square value of the initial current amount by the initial current change amount, and outputting the created measurement data And an output means for performing the operation.
With such a configuration, it is possible to accurately measure the capacitance value C of the basement membrane, that is, the electrical characteristic value indicating the amount of electrolyte in the vicinity of the basement membrane, abnormal meridian organ function without subjective judgment, In particular, it has become possible to more quantitatively determine abnormalities related to the truth of cheerfulness (health), which is the spirit of activity.
The second electrical characteristic value measuring apparatus according to the present invention further enables comprehensive diagnosis. Similar to the first electrical characteristic value measuring apparatus, a pair of electrodes, a voltage applying means, and an initial current amount measurement. A first measurement data as a function of the initial current amount, and a square of the initial current amount divided by the initial current change amount as a function of a value obtained by dividing the square of the initial current amount by the initial current change amount. (2) A data creation means for creating measurement data is provided, and each measurement data is output by an output means.
According to such a configuration, the resistance value R of the dermis₀The first measurement data that correlates with can indicate the trueness of the spirit as an organ, and the second measurement data that correlates with the capacitance value C of the basement membrane is the energy as the activity. Can show the truth of cheerfulness. Therefore, according to this measuring device, it is possible to judge abnormality of meridian organ function by two-dimensional positioning of yin and yang rather than one-dimensional judgment of the presence or absence of physical strength as in the past. It is possible to sufficiently assist complicated oriental medical diagnosis.
In addition, the inventor has determined that the resistance value R of the dermis₀Multiplied by the capacitance value C of the basement membrane C × R₀And the resistance value R of the dermis₀The value C / R obtained by dividing the capacitance value C of the basement membrane by₀It has been found through clinical trials that it is possible to properly determine the true or false trueness of Yin and Yang even with a two-dimensional determination method centered on and. Therefore, the present inventor also provides an electrical characteristic value measuring apparatus (third electrical characteristic value measuring apparatus of the present invention) having the following configuration. This third electrical characteristic value measuring apparatus includes a pair of electrodes, a voltage applying means, an initial current amount measuring means, and an initial current change amount measuring means, as in the second electrical characteristic value measuring apparatus, First measurement data is created as a function of the initial current amount multiplied by the value obtained by dividing the square value of the current amount by the initial current change amount, and the square value of the initial current amount is divided by the initial current change amount. Data generating means for generating second measurement data as a function of a value obtained by dividing the value obtained by dividing by the initial current amount, and outputting each measurement data by the output means.
Even with a measuring device with such a configuration, it is possible to judge abnormalities in meridian organ functions based on the two-dimensional positioning of yin and yang rather than the one-dimensional judgment of the presence or absence of physical strength, i.e. the presence or absence of physical strength. This makes it possible to sufficiently assist complicated oriental medical diagnosis.
In addition, apart from the first to third electrical characteristic value measuring devices described above, data creation for creating first measurement data as a function of the initial current amount and creating second measurement data as a function of the initial current change amount It is also possible to provide a measuring device including means (other components are the same as those of the first and second electric characteristic value measuring devices). Since the capacitance value C of the basement membrane can be calculated using the initial current amount and the initial current change amount as shown in the equation (3), if measurement data correlated with these values can be obtained, This is because the capacitance value C of the basement membrane can be calculated again using an arithmetic device.
In addition, the measuring method of the initial current amount and the initial current change amount in each of the above measuring devices is preferably based on the following method. First, the amount of current flowing between the electrodes is sampled at a predetermined cycle by the sampling means. Then, the first sampling value sampled by the sampling means is acquired as the initial current amount by the initial current amount measuring means, and the deviation between the first sampling value and the second sampling value is initialized by the initial current change amount measuring means. Obtained as the amount of current change. According to this method, the resistance value R of the dermis is obtained with only two data.₀In addition, the capacitance value C of the basement membrane can be accurately measured. Of course, the initial current change amount may be calculated using any other two sampling values such as using the first sampling value and the third sampling value.
Each of the above measuring devices connects a computer to a measuring terminal, measures the response current flowing between the electrodes when a step voltage is applied between a pair of electrodes mounted on the skin of a living body, and measures the computer. It can be realized by reading and executing the following electrical characteristic value measurement program. Each of the electrical property value measurement programs shown below is a measurement program that causes a computer to function as a measurement device that measures an electrical property value of a living body based on an electrical signal from a measurement terminal.
First, a first electrical characteristic value measurement program of the present invention includes an input unit that receives an electrical signal from a measurement terminal, an initial current measurement unit that measures an initial current amount of a response current that flows between the electrodes from the electrical signal, and Obtained by dividing the initial current change amount by the initial current change amount and the initial current change amount measuring means for measuring the change amount of the response current flowing between the electrodes immediately after the start of the application of the step voltage from the electric signal. The computer is caused to function as a measurement apparatus including data generation means for generating measurement data as a function of a value to be output and output means for outputting measurement data. By reading this measurement program into a computer connected to the measurement terminal and executing it, the above-described first electrical characteristic value measuring apparatus of the present invention is realized.
The second electrical characteristic value measurement program of the present invention includes an input means for inputting an electric signal from a measurement terminal, an initial current measuring means for measuring an initial current amount of a response current flowing between the electrodes from the electric signal, An initial current change amount measuring means for measuring a change amount of the response current flowing between the electrodes immediately after the start of application from the start of application of the step voltage from the signal, and first measurement data as a function of the initial current amount are created. Causing a computer to function as a measurement apparatus including data generation means for generating second measurement data as a function of a value obtained by dividing the square value by an initial current change amount, and output means for outputting each measurement data It is characterized by. By reading this measurement program into a computer connected to the measurement terminal and executing it, the above-described second electrical characteristic value measuring apparatus of the present invention is realized.
The third electrical characteristic value measurement program of the present invention includes an input unit that receives an electrical signal from a measurement terminal, an initial current measuring unit that measures an initial current amount of a response current that flows between the electrodes from the electrical signal, A value obtained by dividing the initial current change amount by the initial current change amount, and an initial current change amount measuring means for measuring the change amount of the response current flowing between the electrodes immediately after the start of application of the step voltage from the signal. The first measurement data is created as a function of the value obtained by multiplying the initial current amount by multiplying the initial current amount by the initial current change amount, and the second measurement result is obtained by dividing the square value of the initial current amount by the initial current change amount. A computer is caused to function as a measuring apparatus including data generating means for generating measurement data and output means for outputting each measurement data. By reading this measurement program into a computer connected to the measurement terminal and executing it, the above-described third electrical characteristic value measuring apparatus of the present invention is realized.
Furthermore, the present inventor also provides a meridian organ function diagnostic apparatus to which the above measuring apparatus is applied. First, the first meridian organ function diagnostic apparatus of the present invention includes a pair of electrodes that are mounted on the skin of a living body and a voltage applying unit that applies a step voltage between the electrodes, as in the prior art. Then, the initial current amount of the response current flowing between the electrodes when the step voltage is applied by the voltage applying means is measured by the initial current amount measuring means, and the initial change amount of the response current per predetermined time is changed. It is measured by the quantity measuring means, and the electrical characteristic value calculation means calculates the electrical characteristic value of the living body as a function of the value obtained by dividing the square value of the initial current amount by the initial current change amount. Furthermore, a database storing the relationship between the above-mentioned electrical characteristic values and the meridian organ function state of the living body is provided, and the meridian organ function state corresponding to the electrical characteristic value calculated this time is retrieved from the database by the retrieval means. The search result searched by the search means is displayed on the display means.
According to such a configuration, when there is an abnormality in the meridian organ function in relation to the truth of cheerfulness (health) as the activity, the content of the abnormality is automatically displayed on the display means. Is done. Therefore, according to this diagnostic apparatus, complicated oriental medical diagnosis can be facilitated, and assistance in determining a treatment plan that requires skill can be sufficiently provided.
Further, the second meridian organ function diagnostic apparatus of the present invention includes a pair of electrodes, a voltage applying means, an initial current amount measuring means, and an initial current change amount measuring means as in the first meridian organ function diagnostic apparatus. The first electrical characteristic value of the living body is calculated as a function of the initial current amount, and the second electrical characteristic value of the living body is calculated as a function of a value obtained by dividing the square value of the initial current amount by the initial current change amount. Electrical characteristic value calculating means for calculating is provided. The database stores the relationship between each electrical characteristic value and the meridian organ function state of the living body, and the meridian organ function state corresponding to each electrical characteristic value calculated this time is retrieved from the database by the search means. The search is performed, and the search result searched by the search means is displayed on the display means.
According to such a configuration, the abnormality of the meridian organ function is determined based on the two-dimensional positioning of the yin and yang and the truth, and the content of the abnormality is automatically displayed on the display means. Therefore, according to this diagnostic apparatus, it is possible to further facilitate the complicated oriental medical diagnosis, and it is possible to more fully assist in the determination of a treatment plan that requires skill.
Similar to the first meridian organ function diagnostic apparatus, the third meridian organ function diagnostic apparatus of the present invention includes a pair of electrodes, a voltage application means, an initial current amount measuring means, an initial current change amount measuring means, and a first In addition to electrical characteristic value calculation means having the same function as the meridian organ function diagnostic apparatus, temporary storage means for temporarily storing electrical characteristic values detected at a plurality of locations in the living body is provided. The database stores the relationship between the characteristics of the set of electrical characteristic values detected at a predetermined location of the living body and the meridian organ function state of the living body, and is calculated and stored in the temporary storage means this time. The meridian organ function state corresponding to the set of electrical characteristic values is searched from the database by the search means, and the search result searched by the search means is displayed on the display means.
The fourth meridian organ function diagnostic apparatus of the present invention is similar to the second meridian organ function diagnostic apparatus in that a pair of electrodes, voltage application means, initial current amount measuring means, initial current change amount measuring means, In addition to electrical merit value calculation means having the same function as the meridian organ function diagnostic apparatus of No. 2, it further comprises temporary storage means for temporarily storing electrical characteristic values detected at a plurality of locations in the living body in order. The database stores the relationship between the characteristics of each set of electrical characteristic values detected at a predetermined location of the living body and the state of the meridian organ function of the living body, and is calculated and stored in the temporary storage means. The meridian organ function state corresponding to each set of electrical characteristic values is searched from the database by the search means, and the search result searched by the search means is displayed on the display means.
According to the configurations of the third and fourth meridian organ function diagnostic apparatuses, in addition to the operational effects obtained by the configurations of the first and second meridian organ function diagnostic apparatuses, respectively, A more comprehensive diagnosis based on a set of physical characteristic values becomes possible, which can be further used for determining a treatment plan.
Preferably, in each of the above-described diagnostic apparatuses, a treatment method corresponding to the state of each meridian organ function is also stored in the database. And the treatment method according to the meridian organ function state concerning this diagnosis is searched from the database by the search means and displayed on the display means. Thus, by suggesting not only treatment points but also treatment methods, it becomes possible to facilitate the determination of treatment plans that require skill.
Each of the above diagnostic devices inputs the measurement data (electrical characteristic values) obtained by each of the above-described electrical characteristic value measuring devices of the present invention to a computer, and reads and executes the following meridian organ function diagnostic program on the computer This can be achieved. Each of the meridian organ function diagnostic programs shown below is a diagnostic program that causes a computer to function as a diagnostic device for diagnosing the meridian organ function of a living body based on the electrical characteristic values of the living body.
First, according to the first meridian organ function diagnosis program of the present invention, a function of a value obtained by dividing the square value of the initial current amount of the response current by the change amount of the response current immediately after the start of the application of the step voltage is obtained. A database that stores the relationship between the electrical characteristic value and the state of the meridian organ function of the living body, the input means for inputting the electrical characteristic value, and the input electrical characteristic value. The computer is made to function as a diagnostic apparatus including a search unit that searches a corresponding meridian organ function state from a database and an output unit that outputs a search result searched by the search unit to a display. By reading this diagnostic program into a computer and executing it, the first meridian organ function diagnostic apparatus of the present invention is realized.
The second meridian organ function diagnosis program of the present invention is obtained by dividing the function of the initial current amount and the square value of the initial current amount of the response current by the change amount of the response current immediately after the start of the application from the start of the step voltage application. A database of the relationship between each electrical property value and the state of the meridian organ function of the living body, and input means for inputting each electrical property value, The computer functions as a diagnostic device comprising search means for searching meridian organ function states corresponding to each input electrical characteristic value from a database, and output means for outputting the search results searched by the search means to a display. It is characterized by letting. By reading this diagnostic program into a computer and executing it, the above-mentioned second meridian organ function diagnostic apparatus of the present invention is realized.
According to the third meridian organ function diagnosis program of the present invention, a function of a value obtained by dividing the square value of the initial current amount of the response current by the change amount of the response current immediately after the start of the application of the step voltage is an electrical function. A database that stores the relationship between the characteristics of a set of electrical characteristic values detected at a predetermined location of a living body and the state of meridian organ function of the living body, and the electrical characteristic values detected at a predetermined location. Input means, search means for searching meridian organ function states corresponding to the set of input electrical characteristic values from the database, and output means for outputting the search results searched by the search means to the display As a diagnostic device provided, the computer is made to function. By reading this diagnostic program into a computer and executing it, the above third meridian organ function diagnostic apparatus of the present invention is realized.
The fourth meridian organ function diagnosis program of the present invention is obtained by dividing the function of the initial current amount and the square value of the initial current amount of the response current by the change amount of the response current immediately after the start of the application of the step voltage. A database that stores the relationship between the characteristics of each set of electrical property values detected at a predetermined location of the living body and the state of the meridian organ function of the living body, and a predetermined function. Input means for inputting each electrical characteristic value detected at a location, search means for searching meridian organ function states corresponding to the set of input electrical characteristic values from the database, and search performed by the search means It is characterized by making a computer function as a diagnostic apparatus provided with the output means which outputs a result to a display machine. By reading this diagnostic program into a computer and executing it, the above-described fourth meridian organ function diagnostic apparatus of the present invention is realized.
In each of the above diagnostic programs, preferably, a treatment method according to the state of each meridian organ function is stored in a database, and the treatment method according to the meridian organ function state related to the current diagnosis is searched from the database by the search means. Then, the computer is caused to function as a diagnostic device that outputs the search result to the display device by the output means.
BEST MODE FOR CARRYING OUT THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
(A) First embodiment
FIG. 1 is a block diagram showing a configuration of an electrical characteristic value measuring apparatus 1 as a first embodiment of the present invention. This electrical property value measuring device 1 is a device that applies step voltage to the skin of a patient and measures data (electrical property value of a living body) useful for diagnosis of meridian organ function from the response current at that time. As shown in FIG. 1, it comprises a measuring device 10, a data processing device 20, and a display (display means) 50.
The measuring device 10 has a function of applying a step voltage to the skin of a living body and a function of measuring a response current at that time, and includes a pair of electrodes 11A and 11B, a step voltage generating device (voltage applying means) 12. , An ammeter 13, a data sampling circuit (sampling means) 14, a clock generation circuit 15, and two memories 16 and 17. The electrodes 11A and 11B are means for applying a step voltage to the skin of a living body, and a step voltage is applied between the step voltage generator 12 and the electrodes 11A and 11B by turning on a trigger switch (not shown). ing. The voltage generated by the step voltage generator 12 is normally set to about 3V.
The amount of current flowing between the electrodes 11A and 11B due to the application of the step voltage is constantly measured by the ammeter 13. The amount of current measured by the ammeter 13 is A / D converted at a predetermined timing by the data sampling circuit 14 and is taken in as a digital signal. Sampling timing by the data sampling circuit 14 is controlled by a clock signal output from the clock generation circuit 15. The clock generation circuit 15 generates a first sampling command pulse signal (first command signal) in synchronization with the application of the step voltage by the step voltage generator 12, and after a predetermined minute time, the second sampling command pulse signal ( 2nd command signal) is generated. As shown in FIG. 2, the data sampling circuit 14 captures the current amount I from the ammeter 13 in synchronization with the first command signal and the second command signal, and captures the current amount in synchronization with the first command signal. I₁, Is the current amount I stored in the first memory 16 and captured in synchronization with the second command signal.₂Is stored in the second memory 17. The amount of current I stored in each memory 16, 17₁, I₂Are processed in the data processing device 20 described below.
The data processing device 20 uses the current amount I obtained by the measuring device 10.₁, I₂Is read from each of the memories 16 and 17 via an input interface (input means) (not shown) and performs appropriate processing to calculate an electrical characteristic value for diagnosis, and an initial current amount calculation circuit ( Initial current amount measuring means) 21, initial current change amount calculating circuit (initial current change amount measuring means) 22, and electrical characteristic value calculating circuit (data creating means, electrical characteristic value calculating means) 23. . The initial current amount calculation circuit 21 is a means for calculating the current amount of the response current that flows immediately after the application of the step voltage. Here, the current amount I is calculated from the first memory 16._lAnd read the initial current I_PIt is said. The initial current change amount calculation circuit 22 is a means for calculating the initial change amount of the response current per predetermined time. Here, the current amount I read from the first memory 16 is here.₁And the current amount I read from the second memory 17₂And the deviation is calculated as the initial current change amount di (0) {di (0) = I₁-I₂}.
The electrical characteristic value calculation circuit 23 has an initial current amount I calculated by the initial current amount calculation circuit 21._PAnd an initial current change amount di (0) calculated by the initial current change amount calculation circuit 22, and means for calculating an electrical characteristic value.₀The electric resistance calculation circuit 24 for calculating the electric capacitance value C and the electric capacitance value calculation circuit 25 for calculating the electric capacitance value C. These electrical resistance values R₀And the capacitance value C are the electrical characteristic values of the living body when the skin is modeled into the electrical equivalent circuit shown in FIG.₀Corresponds to the magnitude of the electrical resistance of the extracellular fluid, and the capacitance value C corresponds to the amount of electrolyte in the vicinity of the basement membrane. The electrical resistance calculation circuit 24 calculates the initial current amount I from the above equation (1)._PBy substituting₀Is calculated. On the other hand, the electric capacitance value calculation circuit 25 calculates the initial current amount I from the above-described equation (3)._PAnd the initial current change amount di (0) are substituted to calculate the electric capacitance value C. In the equation (3), dt is the amount of current I₁, I₂The sampling interval is equal to the clock cycle by the clock generation circuit 15.
Each electrical characteristic value (electric resistance value R calculated by the electric resistance calculation circuit 24 and the electric capacitance value calculation circuit 25)₀, Electric capacity value C) is output to the display device 50 via the output interface (output means) 29. The display format in the display device 50 may be a simple numerical display, but here, it is displayed as a coordinate point on a two-dimensional map as shown in FIG. In the map of FIG. 3, the vertical axis represents the electric capacitance value C, and the horizontal axis represents the electric resistance value R.₀The reciprocal of is taken. As described above, the amount of electrolyte in the vicinity of the basement membrane indicated by the capacitance value C is considered to be the degree of extracellular environment, that is, the activity of cells on the peripheral surface. It can be interpreted that it shows the truth of cheerfulness (defense). Also, the electric resistance value R₀The electrical resistance of the extracellular fluid is considered to be the susceptibility to chemical changes in the body, that is, the life activity environment. be able to. Therefore, according to the map shown in FIG. 3, it is possible to show the truth of cheerfulness (defense) on the vertical axis and the truth of cheerfulness (glory) on the horizontal axis.
As described above, according to the electrical characteristic value measuring apparatus 1 of the present embodiment, the dermis electrical resistance value R indicating the trueness of negativeness (glory).₀And the capacitance value C of the basement membrane showing the truth of cheerfulness (defense) can be obtained as measurement data. Therefore, by using the electrical characteristic value measuring apparatus 1 of the present embodiment for diagnosis, a map as shown in FIG. 3 is used instead of the vague truth, that is, the one-dimensional determination of the presence or absence of physical strength. Therefore, it is possible to determine the abnormality of the meridian organ function of the patient by the two-dimensional positioning of Yin Yang and Fiction. That is, the electrical characteristic value measuring apparatus 1 of the present embodiment can sufficiently support a complicated oriental medical diagnosis.
Moreover, according to the electrical characteristic value measuring apparatus 1 of the present embodiment, only two pieces of measurement data (current amount I₁, I₂), Electrical resistance value R₀Since the capacitance value C can be measured accurately, the measurement is completed at the initial stage when the step voltage is applied. Accordingly, there is no need to measure until the time of occurrence of polarization as in the prior art, and there is also an advantage that the influence of external influences within the measurement time and fluctuations of electrical characteristics within the body can be ignored.
The electrical characteristic value measuring device 1 of the present embodiment may be configured as a dedicated device combining electric circuits. However, only the measuring device 10 uses a dedicated measuring terminal, and the data processing device 20 is a general-purpose computer. It may be used. In this case, the functions of the elements 21, 22, 23, 24, and 25 constituting the data processing device 20 can be realized by reading a dedicated program (electrical characteristic value measurement program) into a computer and executing it.
(B) Second embodiment
FIG. 4 is a block diagram showing the configuration of the electrical characteristic value measuring apparatus 2 as the second embodiment of the present invention. The electrical characteristic value measuring apparatus 2 is characterized in that a data conversion circuit 26 is newly provided in the data processing apparatus 20 of the electrical characteristic value measuring apparatus 1 of the first embodiment.
The data conversion circuit 26 includes a multiplication circuit 27 and a division circuit 28. In the multiplication circuit 27, the electrical resistance value R calculated by the electrical resistance value calculation circuit 24.₀Is multiplied by the electric capacity value C calculated by the electric capacity value calculating circuit 25 to obtain a new electric characteristic value C × R.₀Is calculated. Further, in the divider circuit 28, the electric capacitance value C is converted into the electric resistance value R.₀Divided by the new electrical characteristic value C / R₀Is calculated. And these new electrical characteristic values C × R₀, C / R₀Is output to the display device 50. Output electrical characteristic value C × R₀, C / R₀Are displayed as coordinate points on a two-dimensional map as shown in FIG. In the map of FIG. 5, the vertical axis represents the electrical characteristic value C × R.₀And the horizontal axis shows the electrical characteristic value C / R₀Is taken. When considered in relation to Yin Yang, this map shows the hidden positive and negative on the positive side of the vertical axis and the negative and positive on the negative side. In addition, the positive side of the horizontal axis indicates both hidden and positive, and the negative side indicates both Yin and Yang.
Therefore, even when the electrical characteristic value measuring apparatus 2 of the present embodiment is used for diagnosis, it is not a vague reality as in the past, that is, a one-dimensional determination of the presence or absence of physical strength, but a two-dimensional representation of Yin Yang and truth. It is possible to judge the abnormality of the meridian organ function of the patient by the positioning. That is, the electrical characteristic value measuring apparatus 2 of the present embodiment can sufficiently support a complicated oriental medical diagnosis as in the first embodiment.
As in the first embodiment, the electrical characteristic value measuring device 2 of the present embodiment can be configured as a dedicated device combining electric circuits, or a data processing device using a measuring terminal dedicated to the measuring device 10 only. 20 can also be configured using a general-purpose computer.
(C) Third embodiment
FIG. 6 is a block diagram showing a configuration of the meridian organ function diagnostic apparatus 3 as the third embodiment of the present invention. This meridian organ function diagnostic apparatus 3 uses the electrical characteristic value measuring apparatus 1 of the first embodiment, and a data analysis apparatus 30 is newly added to the configuration of the electrical characteristic value measuring apparatus 1 shown in FIG. It has a combined configuration.
The data analysis device 30 is configured so that each electrical characteristic value (electric resistance value R calculated by the data processing device 20) is calculated.₀, Based on the electric capacitance value C), it has a function of diagnosing the state of the meridian organ function of the patient, and comprises a feature determination device 31, a search device (search means) 32, and a database 33. The feature determination device 31 determines an electrical feature of the affected part (meridian) by comparing each calculated electrical characteristic value with a threshold value. For example, when the electric capacity value C is larger than the threshold value, it is determined that “the electric capacity value C is large”, and conversely, when it is smaller than the threshold value, it is determined that “the electric capacity value C is small”. In accordance with such electrical characteristics, the database 33 stores symptoms and constitutions (states of meridian organ function) expected from each electrical characteristic and recommended treatment methods as shown in FIG. ing. The search device 32 searches the database 33 using the electrical characteristics determined by the feature determination device 31 as a search condition, reads out the symptoms, constitutions and treatment methods expected from the electrical characteristics determined this time from the database 33, Output to the display 50. At this time, on the display device 50, the symptom / body constitution expected from each electrical characteristic of the affected area and the treatment method thereof may be displayed, and at the same time, the balance between yin yang and reality may be displayed using the map shown in FIG.
In order to understand the relationship between Yin Yang's reality and meridian organ function in oriental medicine, specialized knowledge is required, and the diagnosis method is extremely complicated. However, according to the meridian organ function diagnostic apparatus 3 of this embodiment, For example, the abnormality of the meridian organ function is diagnosed by the two-dimensional positioning of Yin and Yang and the content of the abnormality is automatically displayed on the display device 50 together with the treatment method. Therefore, by using the meridian organ function diagnostic apparatus 3 of the present embodiment for diagnosis, it is possible to facilitate complicated oriental medical diagnosis. That is, the meridian organ function diagnosis apparatus 3 of the present embodiment can sufficiently assist in determining a treatment plan for oriental medical treatment that requires skill.
The meridian organ function diagnosis apparatus 3 of the present embodiment may be configured as a dedicated apparatus combining electric circuits. The measurement apparatus 10 and the data processing apparatus 20 are dedicated apparatuses, and the data analysis apparatus 30 is a general-purpose computer. You may make it use. In this case, the functions of the elements 31, 32, and 33 constituting the data analysis device 30 can be realized by reading a dedicated program (meridian organ function diagnosis program) into a computer and executing it. Alternatively, a general-purpose computer may be used for the data processing device 20 and the data analysis device 30 by using a measurement terminal dedicated to the measurement device 10 only. In this case, the function of the data processing device 20 and the function of the data analysis device 30 can be provided in one computer.
(D) Fourth embodiment
FIG. 8 is a block diagram showing the configuration of the meridian organ function diagnostic apparatus 4 as the fourth embodiment of the present invention. The meridian organ function diagnostic apparatus 4 of the present embodiment can comprehensively diagnose the state of the meridian organ function of a patient from measurement data (electrical characteristic values) at a plurality of locations on the body.
For this reason, the data analysis device 40 according to the present embodiment has each electrical characteristic value (electrical resistance value R) measured at a plurality of locations on the body.₀, Electric capacity value C), a temporary storage device 44 having a plurality of memories 45A to 45N is provided. Each electrical characteristic value calculated by the data processing device 20 is stored in the memories 45A to 45N in the order of measurement by the measurement device 10. The data analysis device 40 includes a temporary storage device 44, a feature determination device 41, a search device 42, and a database 43.
The feature determination device 41 determines the electrical feature of the affected part as a feature of the set of each electrical property value by collating each electrical property value stored in the temporary storage device 44 with a predetermined determination formula. For example, when the average value of all the electric capacity values C is smaller than a predetermined threshold, it is determined that “the average value of the electric capacity values C of the entire meridians is small”. Further, when the difference between the average value of the capacitance value C of the upper body and the average value of the capacitance value C of the lower body is larger than a predetermined threshold value, it is said that there is a difference between the average values of the capacitance values C of the upper and lower bodies. Judgment is made. Further, when the meridian is focused on a specific meridian, when the difference between the average value of the capacitance value C of the left half and the average value of the capacitance value C of the right half is larger than a predetermined threshold, It is determined that the left-right difference of the capacitance value C is large.
In accordance with such electrical features, the database 43 stores symptoms and constitutions (states of meridian organ function) expected from each electrical feature and a recommended treatment method, as shown in FIG. ing. The search device 43 searches the database 43 using the electrical characteristics determined by the feature determination device 41 as a search condition, reads out the symptoms, constitutions, and treatment methods expected from the electrical characteristics determined this time from the database 43, Output to the display 50. Although omitted in FIG. 9, the database 43 also stores data for diagnosis based on the electrical characteristic values at a single location, as in the third embodiment. Also in the present embodiment, the display 50 displays the symptoms / structures expected from the electrical characteristics of the affected area and the treatment method thereof, and at the same time, displays the balance between yin yang and reality through the map shown in FIG. Also good.
With such a configuration, according to the meridian organ function diagnostic apparatus 4 of the present embodiment, the meridian organ function abnormality can be detected by two-dimensional positioning of yin and yang as in the meridian organ function diagnostic apparatus 3 of the third embodiment. Diagnosis and the contents of the abnormality can be automatically displayed on the display 50 together with the treatment method, and more comprehensive based on a set of electrical characteristic values obtained at a plurality of locations on the body. Diagnosis is also possible. Therefore, by using the meridian organ function diagnostic apparatus 3 of the present embodiment for diagnosis, it can be further used to determine a treatment plan for oriental medical treatment that requires skill.
As in the third embodiment, the meridian organ function diagnostic device 4 of the present embodiment can be configured as a dedicated device combined with an electric circuit, or the measuring device 10 and the data processing device 20 can be configured as a dedicated device. Only the analysis device 30 can be configured using a general-purpose computer. Alternatively, only the measurement device 10 can be used as a measurement terminal, and the data processing device 20 and the data analysis device 30 can be configured using a general-purpose computer.
(E) Fifth embodiment
FIG. 10 is a block diagram showing a configuration of a meridian organ function diagnosis system as a fifth embodiment of the present invention. The meridian organ function diagnosis system 5 of the present embodiment is configured by connecting a server 80 and a plurality of diagnosis terminals 70 via a communication network 60 such as a telephone network.
In this meridian organ function diagnosis system 5, the server 80 corresponds to the data analysis devices 30 and 40 according to the third and fourth embodiments, and the database 81 provided in the server 80 is the third and fourth embodiments. This corresponds to the databases 33 and 43. The function of the server 80 as a data analysis device is the same as that of the data analysis device 30 according to the third embodiment or the data analysis device 40 according to the fourth embodiment. The diagnostic terminal 70 corresponds to the measuring device 10 and the data processing device 20 according to the third and fourth embodiments. The function as a measuring device and the function as a data processing device of the diagnostic terminal 70 are the same functions as the measuring device 10 and the data processing device 20 according to the third and fourth embodiments. Measurement data (electrical characteristic values) obtained by measurement by the diagnostic terminal 70 is transmitted to the server 80 via the communication network 60, and data analysis is performed in the server 80 to predict expected symptoms and constitutions (meridians) The treatment method to be recommended as the organ function state is searched from the database 81. This search result is transmitted from the server 80 to the diagnostic terminal 70 via the communication network 60 and displayed on the display device 50.
With such a configuration, according to the meridian organ function diagnosis system 5 of the present embodiment, the diagnosis data of the database 81 of the server 80 can be shared by the plurality of diagnosis terminals 70. When updating the diagnostic data in the database, the meridian organ function diagnostic apparatus according to the third and fourth embodiments needs to update the database for each diagnostic apparatus when there are a plurality of diagnostic apparatuses. Therefore, it is sufficient to update only the diagnostic data in the database 81 of the server 80. Therefore, there is an advantage that it is possible to save time and effort for updating the diagnostic data, and it is possible to always perform diagnosis using the latest diagnostic data in each diagnostic terminal 70.
(F) Other
Although the five embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the spirit of the present invention. For example, in each embodiment, the electrical resistance value R is used as the electrical characteristic value of the living body.₀The electric capacitance value C is calculated, but only the electric capacitance value C or the electric resistance value R₀Of course, it is also possible to calculate only. The electric capacity value C indicates the truth of cheerfulness (defense), and the electric resistance value R₀Since it is thought that it shows the truth of insanity (glory), even if only one of them, the meridian organ function based on the truth of at least cheerfulness (defense) or the truth of insanity (glory) Diagnosis is possible.
In each embodiment, only one pair of electrodes is described. However, it is of course possible to provide an electrode group composed of a plurality of electrodes and measure electrical characteristic values at a plurality of locations at once. .
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an electrical characteristic value measuring apparatus as a first embodiment of the present invention.
FIG. 2 is a diagram for explaining a data measurement method in the electrical characteristic value measuring apparatus of FIG.
FIG. 3 is a diagram showing a two-dimensional map displayed on the display in the electrical characteristic value measuring apparatus of FIG.
FIG. 4 is a block diagram showing a configuration of an electrical characteristic value measuring apparatus as a second embodiment of the present invention.
FIG. 5 is a diagram showing a two-dimensional map displayed on the display in the electrical characteristic value measuring apparatus of FIG.
FIG. 6 is a block diagram showing a configuration of a meridian organ function diagnostic apparatus as a third embodiment of the present invention.
FIG. 7 is a diagram showing the stored contents of the database in the meridian organ function diagnostic apparatus of FIG.
FIG. 8 is a block diagram showing a configuration of a meridian organ function diagnostic apparatus as a fourth embodiment of the present invention.
FIG. 9 is a diagram showing the stored contents of the database in the meridian organ function diagnostic apparatus of FIG.
FIG. 10 is a block diagram showing a configuration of a meridian organ function diagnosis system as a fifth embodiment of the present invention.
FIG. 11 is a diagram showing a data measurement method in a conventional measuring apparatus, where graph (a) shows the time change of voltage and graph (b) shows the time change of response current.
FIG. 12 is a schematic diagram showing the principle that a response current flows when a step voltage is applied to the skin.
FIG. 13 is a diagram in which the principle shown in FIG. 12 is replaced with an equivalent circuit.

Claims (9)

A pair of electrodes (11A, 11B) attached to the skin of the living body;
Voltage applying means (12) for applying a step voltage between the pair of electrodes (11A, 11B);
An initial current amount measuring means (21) for measuring an initial current amount of a response current flowing between the pair of electrodes (11A, 11B) when a step voltage is applied by the voltage applying means (12);
Initial current change amount measuring means (22) for measuring an initial change amount per predetermined time of the response current flowing between the pair of electrodes (11A, 11B) when a step voltage is applied by the voltage applying means (12). )When,
Data creation means (25) for creating measurement data as a function of a value obtained by dividing the square value of the initial current amount by the initial current change amount;
An electrical characteristic value measuring device comprising output means (29) for outputting the measurement data. A pair of electrodes (11A, 11B) attached to the skin of the living body;
Voltage applying means (12) for applying a step voltage between the pair of electrodes;
An initial current amount measuring means (21) for measuring an initial current amount of a response current flowing between the pair of electrodes (11A, 11B) when a step voltage is applied by the voltage applying means (12);
Initial current change amount measuring means (22) for measuring an initial change amount per predetermined time of the response current flowing between the pair of electrodes (11A, 11B) when a step voltage is applied by the voltage applying means (12). )When,
Data creation means (24) for creating first measurement data as a function of the initial current amount and creating second measurement data as a function of a value obtained by dividing the square value of the initial current amount by the initial current change amount 25)
An electrical characteristic value measuring apparatus comprising output means (29) for outputting each measurement data. A pair of electrodes (11A, 11B) attached to the skin of the living body;
Voltage applying means (12) for applying a step voltage between the pair of electrodes (11A, 11B);
An initial current amount measuring means (21) for measuring an initial current amount of a response current flowing between the pair of electrodes (11A, 11B) when a step voltage is applied by the voltage applying means (12);
Initial current change amount measuring means (22) for measuring an initial change amount per predetermined time of the response current flowing between the pair of electrodes (11A, 11B) when a step voltage is applied by the voltage applying means (12). )When,
First measurement data is created as a function of a value obtained by multiplying the initial current amount by a value obtained by dividing the square value of the initial current amount by the initial current change amount, and the square value of the initial current amount is set to the initial current amount. Data creation means (24, 25, 27, 28) for creating second measurement data as a function of a value obtained by dividing the current change amount by the initial current amount;
An electrical characteristic value measuring apparatus comprising output means (29) for outputting each measurement data. Sampling means (14) for sampling the amount of current flowing between the pair of electrodes (11A, 11B) at a predetermined period;
The initial current amount measuring means (21) is configured to acquire the first sampling value sampled by the sampling means (14) as the initial current amount,
The initial current change amount measuring means (22) is configured to acquire a deviation between the first sampled value and the second sampled value sampled by the sampling means (14) as the initial current change amount. The electrical characteristic value measuring device according to any one of claims 1 to 3, wherein the electrical property value measuring device is any one of claims 1 to 3. A pair of electrodes (11A, 11B) attached to the skin of the living body;
Voltage applying means (12) for applying a step voltage between the pair of electrodes;
An initial current amount measuring means (21) for measuring an initial current amount of a response current flowing between the pair of electrodes (11A, 11B) when a step voltage is applied by the voltage applying means (12);
Initial current change amount measuring means (22) for measuring an initial change amount per predetermined time of the response current flowing between the pair of electrodes (11A, 11B) when a step voltage is applied by the voltage applying means (12). )When,
An electrical characteristic value calculating means (25) for calculating an electrical characteristic value of the living body as a function of a value obtained by dividing the square value of the initial current amount by the initial current change amount;
A database (33) storing the relationship between the electrical characteristic value and the meridian organ function state of the living body;
Search means (32) for searching the meridian organ function state corresponding to the electrical characteristic value calculated this time from the database (33);
A meridian organ function diagnostic apparatus, comprising: display means (50) for displaying a search result searched by the search means (32). A pair of electrodes (11A, 11B) attached to the skin of the living body;
Voltage applying means (12) for applying a step voltage between the pair of electrodes (11A, 11B);
An initial current amount measuring means (21) for measuring an initial current amount of a response current flowing between the pair of electrodes (11A, 11B) when a step voltage is applied by the voltage applying means (12);
Initial current change amount measuring means (22) for measuring an initial change amount per predetermined time of the response current flowing between the pair of electrodes (11A, 11B) when a step voltage is applied by the voltage applying means (12). )When,
A first electrical characteristic value of the living body is calculated as a function of the initial current amount, and a second electrical characteristic value of the living body is obtained as a function of a value obtained by dividing the square value of the initial current amount by the initial current change amount. Electrical characteristic value calculating means (24, 25) for calculating characteristic values;
A database (33) storing the relationship between each electrical characteristic value and the meridian organ function state of the living body;
Search means (32) for searching meridian organ function states corresponding to the electrical characteristic values calculated this time from the database;
A meridian organ function diagnostic apparatus, comprising: display means (50) for displaying a search result searched by the search means (32). A pair of electrodes (11A, 11B) attached to the skin of the living body;
Voltage applying means (12) for applying a step voltage between the pair of electrodes (11A, 11B);
An initial current amount measuring means (21) for measuring an initial current amount of a response current flowing between the pair of electrodes (11A, 11B) when a step voltage is applied by the voltage applying means (12);
Initial current change amount measuring means (22) for measuring an initial change amount per predetermined time of the response current flowing between the pair of electrodes (11A, 11B) when a step voltage is applied by the voltage applying means (12). )When,
An electrical characteristic value calculating means (25) for calculating an electrical characteristic value of the living body as a function of a value obtained by dividing the square value of the initial current amount by the initial current change amount;
Temporary storage means (45A to 45N) for temporarily storing the electrical characteristic values detected in a plurality of locations of the living body in order;
A database (43) storing the relationship between the characteristics of the set of electrical characteristic values detected at a predetermined location of the living body and the meridian organ function state of the living body;
Search means (42) for retrieving meridian organ function states corresponding to the set of electrical characteristic values calculated this time and stored in the temporary storage means (45A to 45N) from the database (43);
A meridian organ function diagnostic apparatus, comprising: display means (50) for displaying a search result searched by the search means (42). A pair of electrodes (11A, 11B) attached to the skin of the living body;
Voltage applying means (12) for applying a step voltage between the pair of electrodes (11A, 11B);
An initial current amount measuring means (21) for measuring an initial current amount of a response current flowing between the pair of electrodes (11A, 11B) when a step voltage is applied by the voltage applying means (12);
Initial current change amount measuring means (22) for measuring an initial change amount per predetermined time of the response current flowing between the pair of electrodes (11A, 11B) when a step voltage is applied by the voltage applying means (12). )When,
A first electrical characteristic value of the living body is calculated as a function of the initial current amount, and a second electrical characteristic value of the living body is obtained as a function of a value obtained by dividing the square value of the initial current amount by the initial current change amount. Electrical characteristic value calculating means (24, 25) for calculating characteristic values;
Temporary storage means (45A to 45N) for temporarily storing the electrical characteristic values detected at a plurality of locations of the living body in order;
A database (43) storing the relationship between the characteristics of the set of electrical characteristic values detected at a predetermined location of the living body and the meridian organ function state of the living body;
Search means (42) for searching meridian organ function states corresponding to the respective sets of electrical characteristic values calculated and stored in the temporary storage means (45A to 45N) from the database (43);
A meridian organ function diagnostic apparatus, comprising: display means (50) for displaying a search result searched by the search means (42). The database (33 or 43) further stores a treatment method according to the state of each meridian organ function,
The search means (32 or 42) is configured to search the database (33 or 43) for a treatment method corresponding to the meridian organ function state related to the current diagnosis and display it on the display means (50). The meridian organ function diagnostic apparatus according to any one of claims 5 to 8, wherein the meridian organ function diagnostic apparatus.

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