JP2660533B2 - Bioelectric signal search device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION <Industrial Application Field> The present invention relates to a device for searching for a bioelectric signal, and more particularly, to applying an electric stimulation signal to a certain acupoint on a human or animal body surface, The present invention relates to a device that searches for a biological response to a stimulus signal, obtains characteristic information on the distribution and movement of bioelectric water in a living body, diagnoses a disease, monitors a health condition, and confirms a therapeutic effect of a treatment.

Background of the Invention In recent years, the Chinese academic community has developed field theory, information technology and traditional Chinese medicine, especially pathways (channels and side branches ... coll)
Based on the theory of aterals, he has expanded his research and conducted a number of experiments on life information, one of the most important characteristics of living organisms. In particular, using the latest exploration equipment, “Qigong” (Qi Gong) and deep breathing instructor “Gong” (Fa
Measurement tests have been performed on various aspects of the Qi emission phenomenon called Gong) or the isotope tracing of the pathway, with remarkable results. The results of these studies were published in Shanghai Science and Technology Pu
blishing House, August 1980, "NATURE JOURNAL" Vol. 3, No. 8, pp. 563-566, "A Preliminary Study on the Provision and Acceptance of the Humanist Code by the Human Body (A Preliminary Study)
on the Dispatching and Accepting of Vitalist−Code
by Human Body "and also published in September 1980, Volume 3, ninth
No. 681 to 682, "Experimental Research of the Acupuncture Points a"
long the Pericardium Meridan) "
Also published in Shanghai Science and Technology Publishing Company in 1981, "SCI-ENCE YEAR
Book, pages 134-141, "The Reserch Reproduction and Application of
Specific Life). These reports are incorporated herein by reference.

According to medical theory, the body world reveals this in two ways. One is to have a static object (mass) and the other is not a static object but an energy
gy: These are different fields). These two things have a high degree of correlation, with all having a static object possessing its own natural resonance frequency. Biological solids are treated as a morphological system consisting of cells, tissues and organs, and also as an information system consisting of cell position signals, electrocardiogram recorder signals, electroencephalograph recorder signals, and various types of radiation. Have been. These two systems interact and coexist in the same biological solid. The traditional Chinese medicine meridian system, when analyzed according to the operating principles, belongs to the inseparable part of the human body's vital information system. The distribution and movement of a field in a biological information system is subject to change due to abnormalities in any tissue or organ of the biological solid, and is independent of functional abnormalities or organic changes. Therefore, important information on the health of the biological solid can be obtained by searching for the distribution and movement of the field of the vital information system.

According to the clinical experience of traditional Chinese medicine, if any abnormality occurs in one organ in the human body, along the meridian corresponding to this organ, a unique acupoint (acupoint) showing high sensitivity to certain contact and acupuncture, for example. Some can be found on the hands, some on the feet or on the arms and legs), and it has long been known that acupuncture on this acupuncture point always yields satisfactory results. I have. This phenomenon is well explained by the Chinese medicine meridian theory and is often used in clinical diagnosis for clinical purposes. However, such acupuncture phenomena or all similar phenomena related to the meridians and acupuncture points have individual differences, and the application of such phenomena to medical treatment is all based on the patient's subjective state, and is quantitatively searched and evaluated. There is no physical means to perform this, and consequently there are significant limitations on the application of the phenomenon to clinical practice. Therefore, searching for acupuncture points by new search means was extremely interesting in the field of research.

2. Description of the Related Art Conventionally, various devices have been known as devices for searching for acupuncture points and obtaining characteristic information based on them. By using these devices, it is possible to search for changes in various physical parameters such as resistance, potential, magnetic field, temperature, pressure-sensitive point, etc. at different points on the body surface, and to find areas showing abnormal values. . The diagnosis and treatment of the disease can be performed according to the quantitative change of the searched physical parameters.

Traditionally, people have learned that when they have some form of illness, they can look for a decrease in skin resistance or an increase in potential at a specific site on the skin. Then, based on the knowledge, a device for searching for the skin resistance or potential at a specific position was designed. However, since the strength of the bioelectric field distributed and moving within the biological solid is very small, the difference between the distribution and movement of the bioelectric field between the normal state and the abnormal state, especially in the initial stage, is extremely large. It is small. In addition, due to individual differences and environmental interference, it is difficult to search for bioelectricity, and it is even more difficult to obtain useful information from bioelectricity. In this case, assuming that only a reception-only device is used to search for a characteristic value of bioelectricity, for example, using a high-sensitivity potentiometer that senses a small change in potential at the acupoint, the search sensitivity and interference suppression capability of the device Must be extremely high, and any environmental interference will be strictly controlled to eliminate the above difficulties and obtain effective search results. However, this will obviously make the search device and search method extremely complex and expensive, and it is still difficult to distinguish small changes in acupoint potential from environmental interference. For these reasons, statistically meaningful search results cannot be obtained for the diagnosis of early stage diseases.
In order to solve such a problem, a device for searching for a change in resistance of the acupoint and confirming a specific acupoint has been designed. This applies a voltage to the living body and at the same time searches for a current passing through the acupuncture point, thereby obtaining useful information. According to this type of search, many demands are not placed on physical means and environmental control. However, in this type of search, a relatively large stimulation voltage (usually 10-20 V or more) and a strong pressure are applied to the acupuncture points by the electrodes, and artificial distribution and movement of normal bioelectricity in the living body are artificially performed. Is changing. Therefore, the search itself interferes with the living body, makes it impossible to approach effective information, and causes an abnormal change in the living body.

In order to solve various problems of the prior art, the theory of pathways and traditional Chinese medicine acupuncture have led to certain principles regarding the distribution and movement of electromagnetic fields of living organisms, which is one of the human body's vital information systems. Form two inseparable parts, and even where appropriate means are constructed to resolve both environmental and exploratory interference with the human body's electromagnetic field,
Important information giving the status of the meridian system and the vital information system can be obtained by exploring the electrical parameters at different acupoints, which can be used in the diagnosis of disease and also demonstrate the therapeutic effect of the therapeutic process We propose that it can be helpful.

<Summary of the Invention> Based on the above recognition, the present invention seeks a bioelectric signal to be reduced during medical treatment by applying a stimulus of an appropriate amplitude to a specific acupoint of the human or animal body, and at the same time, simultaneously searches for the bioelectric signal. An apparatus for searching for a biological response to a signal and analyzing the magnitude of the amplitude with respect to the time response characteristic of the signal to obtain important vital information and using the information to diagnose and treat a disease is provided.

The amplitude and the waveform of the stimulus signal according to the present invention are selected based on comprehensive experiments, and the method of applying the stimulus signal to the living body has a good balance between the bioelectric signal of the living organism and the stimulus signal of the device. To determine. In this way, the stimulus signal of the device will not cause significant interference with the distribution and movement of the electromagnetic field of the living organism, and the biological response to the stimulus signal, especially in the early stages, will reduce illness and health. In order to distinguish, important vital information that is extremely significant in a statistical sense can be provided.

The biological response to the stimulus signal of the present invention is a very small amplitude current signal in the range of 10 ^-4 to 10 ^-11 A depending on various pathological abnormalities. For this reason, in the present invention, a very small current as small as about 10 ⁻¹² A can be amplified, and the operation area is 10 ⁻¹¹ to 1
It is necessary to employ an amplifier at 0 ^-4 A. It is preferable to employ a logarithmic microcurrent amplifier or an exponentially scaled linear microcurrent amplifier to meet the requirements of this current change region. This amplifier must have good interference suppression capability during the search period when its input terminal is in direct contact with the human body.

The micro-current signal of a living organism responding to the stimulus signal of the present invention is a time-amplitude at which a certain relationship is recognized between the curve shape of the value searched for at a certain acupoint and the disease that affected the human body. Represents a characteristic curve. For this reason, both the signal amplitude and the time response curve shape are useful for disease diagnosis.
Due to these characteristics, a signal processing circuit for processing a response signal is provided in the device of the present invention. In addition, the output device of the device can display a time response curve.

When the device of the present invention is used for searching for acupoints, and particularly for searching for the non-invasive search electrode according to the present invention, different pressures exerted on the epidermis by the electrode have various effects on the local physical state of the skin. This changes the specific resistance of the skin and the microcirculation of local blood that affect the search accuracy. On the other hand, very strong pressures themselves are strong external stimuli to the acupoints, changing the state of the local bioelectric field. In order to guarantee an accurate search, the electrode pressure applied to the acupoint must be as low as possible and the pressure value must be kept constant over the entire search period. In this way, the search is performed under substantially the same conditions at different persons and at different times. In addition, environmental factors such as temperature, humidity, etc. also affect the specific resistance of the skin, and thus the comparability of the search results. The pressure applied to the acupoint by the electrode is kept constant during the search operation by the adjustable elastic structure specially provided for the electrode according to the present invention, and the environmental temperature and humidity are compensated appropriately by adjusting the pressure. Is done.

As described above, the problems of the two aspects that occur during the acupoint search period are solved by the search device according to the present invention.
On the other hand, the interference generated in the distribution state of the electromagnetic field in the living body by the search itself is kept as small as possible by strictly controlling the stimulation signal and the stimulation of the acupuncture point on the skin by the search electrode. On the other hand, the amount of information obtained during the search period is
This is significantly increased by employing a wide-area micro-current amplifier, a signal processing circuit for processing a time response curve of a micro-current signal, and an output device for displaying a search result thereof. In this way, the device of the present invention can search for a lot of important information that cannot be obtained by any conventional device.

According to a preferred embodiment of the bioelectric signal searching device according to the present invention, the device includes a searching electrode which is a conductor; a reference electrode which is also a conductor; a stimulus signal generating circuit connected to the reference electrode; A micro-current amplifier connected to the electrodes;
A signal processing circuit including a flip-flop, an adjustable delay circuit, and a sampling and holding circuit connected to the amplification circuit; and an output device connected to the signal processing circuit. The present invention is from 0.5 to
A stimulation voltage in the range of 3.0 V is applied to the reference acupoint and the acupuncture point to be searched through the reference electrode and the searching electrode,
Form an electrical loop. And 10 ^-11 to 10 ^{-4 of them}
Microcurrent signals in the ampere range are amplified by the microcurrent amplifier circuit and provided to the signal processing circuit. In the signal processing circuit, the current signal is sampled according to a predetermined delay time, and the result of the sampling is displayed by an output device, recorded, or stored as needed.

According to another preferred embodiment of the device of the present invention, the device comprises: a search electrode; a reference electrode; a stimulus signal generating circuit connected to the reference electrode; a micro-current amplifier circuit connected to the search electrode; / D converter, a central processing unit (CPU), a signal processing circuit including a storage device and an I / O interface connected to the amplifier; and a control board and an output device both connected to the interface. It consists of. In the present invention, an electrical loop is formed by applying a stimulation voltage in the range of 0.5 to 3.0 V to the reference acupoint and the acupoint to be searched through the reference electrode and the searching electrode, respectively. Then, the micro current signal in the range of 10 ^-11 to 10 ^-4 amp is amplified by the micro current amplifier circuit and further supplied to the signal processing circuit. The signal processing circuit performs real-time processing on the amplified microcurrent, and thereafter, a time response curve, characteristic parameters of the curve, and related information input via a control board are displayed on an output device and recorded. Is stored. Alternatively, it is subjected to additional processing such as statistical analysis and comparison with a normal value.

According to yet another preferred embodiment of the device of the present invention, the device comprises: a search electrode; a reference electrode; a stimulus signal generating circuit connected to the reference electrode; a micro-current amplifier circuit connected to the search electrode; At least one pair of parallel-connected comparison circuits connected to the output terminal of the amplification circuit; and at least one pair of display devices respectively connected to the comparison circuit. The apparatus applies a stimulation voltage in the range of 0.5 to 3.0 V to the reference acupoint and the acupoint to be searched through the reference electrode and the searching electrode to form an electric loop. Then, the micro current signal in the range of 10 ^-11 to 10 ^-4 amp is amplified by the micro current amplifier circuit. If the magnitude of the searched micro-current is greater than a predetermined low threshold, one of the comparison circuits connected to the amplifier circuit is activated, and a display device (for example, an LED such as an LED) connected thereto is activated. )
And the search results are illustratively shown. If the magnitude of the searched current is smaller than the predetermined high threshold value, another comparison circuit operates to drive another display device. If the magnitude of the searched current is between the high threshold value and the low threshold value, that is, if it is within the normal range, the two parallel-connected comparator circuits operate together. At the same time, both display devices are driven and the search results are qualitatively shown.

When the device of the present invention is used in an actual search, the reference electrode is applied to a reference acupoint located on the midline of the human body, for example, on the forehead of the forehead, on the top of the head, on the vertebrae on the back of the neck, and there. A stimulus voltage is applied. At the same time, the search electrode searches for each of the acupoints throughout the human body and obtains information from each of these acupoints.

An object of the present invention is to provide a device that searches for distribution and movement of a bioelectric field of a living tissue and obtains characteristic parameters therefrom.

Another object of the present invention is to search for acupoints in the human or animal body to obtain important information for diagnosing a disease and confirming the therapeutic effect of a treatment, thereby providing new information for medical diagnosis and confirmation. It is an object of the present invention to provide a bioelectric signal search device that provides an approach.

Yet another object of the present invention is to satisfy the requirements of traditional Chinese medicine theory and clinical practice, and to diagnose disease and confirm the therapeutic effect of treatment according to the characteristic electrical parameters of meridians and acupoints. Accordingly, it is an object of the present invention to provide a search device for making a sufficient foundation for objectively, quantitatively, and automatically performing a diagnostic method of traditional Chinese medicine.

Other objects, features and advantages of the present invention will become more apparent by describing in detail a preferred embodiment of the present invention with reference to the accompanying drawings. In the drawings, the same symbols represent the same elements or the same features.

<Embodiment> The concept of a bioelectric signal search apparatus according to the present invention and a detailed description of a preferred embodiment will be described below with reference to the accompanying drawings.

FIG. 1 shows a block diagram of a search device of the present invention. First
In the figure, reference numeral 10 indicates the entire search device, and reference numeral 20 indicates a search electrode as a conductor having a signal line 203 and a control line 2011. Reference numeral 30 denotes a reference electrode as a conductor formed of a metal sheet, and may be any search electrode commonly used for medical use. Reference numeral 40 is a stimulus signal generation circuit,
Reference numeral 50 indicates a microcurrent amplifier circuit, reference numeral 60 indicates a signal processing circuit, and reference numeral 70 indicates an output device. Details of the above circuit will be described below.

FIG. 2 shows a statistical distribution state of a response current value with respect to a stimulus voltage, which is searched under the same search condition from a healthy person group using the apparatus of the present invention. The data is obtained by placing a reference electrode on the forehead of the forehead, applying different stimulation voltages thereon, and simultaneously sensing the same group of search points using the search electrodes. In FIG. 2, the horizontal axis represents the value of the stimulation voltage Vs expressed in volts (V), and the vertical axis represents the negative logarithmic value N of the searched response current I expressed in amps (A). Here, for example, I ₁ = 10 ^-7 A, N =
At 7, N = −1og I ₁ . FIG. 2 shows the stimulation current
If Vs is greater than 3.0 V, the variance of the search value is small, indicating that the search device is stable, which means that increasing the stimulation voltage has no effect. The stimulation voltage is
If it is less than 1.0 V, the current search value changes greatly as the stimulation voltage changes, while the variance of the search results for the same group of people increases significantly. This indicates that the search is significantly affected by environmental factors. FIG. 2 shows that when the stimulation voltage is too small (less than 1.0 V), the variance of the search value is large, it is difficult to perform statistical processing, and it is possible to obtain effective information for diagnosing a disease. Show difficult things.

FIG. 3 shows the relationship between different values of the stimulation voltage and the negative logarithmic mean of the response currents searched from several groups of patients. The search is performed under the same conditions using the search device of the present invention on several groups of patients previously diagnosed by other medical means and known to have different diseases.
In FIG. 3, the horizontal axis and the vertical axis are the same as in FIG.
Curve 3 is a diagram showing the average value of the statistical distribution shown in FIG. Curve 1 was searched from a group of patients with a manic psychological disorder, curve 2 was searched from a group of patients with a mildly abnormal autonomic nervous system, curve 4 was searched from a group of patients with a mild metabolic disorder, and curve 5 was It was searched from a group of cancer patients in advanced stages. As can be seen from the curves shown in FIG. 3, as the stimulation voltage increased, the search values obtained from patients with severe problems (shown in curves 1 and 5) became more healthy (curves 3). (See curve 2), while patients with minor problems (shown in curves 2 and 4) have a higher search value for healthy individuals (shown in curve 3). It is approaching. Given the variance of clinically searched values (as shown in FIG. 2), it is difficult to distinguish search values for healthy individuals from those for patients with mild abnormalities. In other words, if the stimulation voltage is too strong, a signal corresponding to a minor abnormality is derived by this strong external signal, making it impossible to diagnose the disease in the early stages. Looking at Figure 3, the stimulation voltage V _s is 1.0
It can be seen that the difference between the curves is most distinguishable when within the 3.0V range.

Combining the data shown in FIGS. 2 and 3, when searching for electrical signals of the human body with the device according to the invention, the stimulation voltage should be selected from the range of 1.0 to 3.0 V, preferably 2.0 V It is concluded that it is desirable.

FIG. 4 shows an exemplary embodiment of the stimulus signal generation circuit 40 shown in FIG. In FIG. 4, reference numeral 401 denotes a flip-flop having a very sharp front edge and an adjustable width at its output terminal under the control of a stimulus voltage or signal Vs issued by a signal processing circuit. Generate a step signal. The amplitude of this step signal is clamped to 2.0 V by the clamp diode 402, and thereafter, the step signal is supplied to the reference electrode as a stimulation signal Vs.
Fluctuations in the amplitude of the stimulus voltage Vs are reduced to less than 1% by using the clamp diode 402, thereby avoiding the search current fluctuations caused thereby. According to the concept shown in FIG. 4, any conventional stabilized power supply can be used as the power supply for the stimulus signal generation circuit of the present apparatus, and a step signal having a sharp front edge is generated under the control of the signal processing circuit. If this is the case, a more accurate current search can be performed.

FIG. 5 shows an embodiment of the micro-current amplifier circuit 50 shown in FIG. In Figure 5A, reference numeral 50A denotes an amplifier circuit as a whole, surrounded by a dotted line block 501A indicates a logarithmic micro-current amplifier formed by an operational amplifier OP, and a transistor T _1a. Block 502A surrounded by a dotted line
Indicates a temperature compensation circuit, I ₁ is a low current source, T _1b is a block 50
This transistor forms a transistor connection with the 1A transistor _T1a . The transistor T _1b is
Compensate for the parallel part of the temperature drift of _1a . On the other hand, R _A and R
Compensates for the slope portion of the temperature drift of the transistors T _1a, determines the gain of the compensation circuit. Block 503A enclosed by a dotted line indicates an inverting circuit, the amplified current signal is inverted by the operational amplifier OP _3. W ₁ is a potentiometer for adjusting the 0 position of the output, W ₂ is another potentiometer for adjusting full range of the output. No.
In FIG. 5A, diodes D ₁ , D ₂ and D ₃ are each used for clamping. The logarithmic micro-current amplifier shown in FIG. 5A is used to amplify micro-current signals in the range of 10 ^-11 to 10 ^-4 amps, requiring that the minimum operating current of the operational amplifier OP _{1 be} 10 ^-12 A Is done. This is a requirement achieved by the prior art and will not be described in detail.

FIG. 5B shows another embodiment of the microcurrent amplifier circuit 50 shown in FIG. In FIG. 5B, reference numeral 50B indicates the entire amplifier circuit. T ₁ and T ₂ are junction FET (field effect) transistor constituting a differential input stage of the circuit. While T ₃
And R ₃ form the equivalent impedance of the constant current source of the differential amplifier. T ₄ and T ₅ form a differential amplifier in the second stage. _Re is a constant current resistance. Voltage adjustment diode D
Controls the drain voltage of the transistors T ₁ and T ₂ in a suitable linear portion to form a negative feedback amplifier to operate with T ₃ simultaneously stabilizes the operating point of T ₁ and T _2. T _o
Forms the emitter follower as the output stage of the circuit,
Among them, r ₁ and r ₂ are used to prevent unexcited oscillation. When the circuit shown in Figure 5B is constituted by independent elements, the characteristics of T ₁ and T ₂ should be well matched. For this purpose, a junction FET 2N4416 or 2N3823 manufactured by Texas Corporation of the United States or a 3DJ series (such as 3DJ2F) manufactured by China is used. In this case, the gate current is required to be 10 ^-12 A or less. In FIG. 5B, a switch S and a cascaded resistor network N form this amplifier circuit according to the service index of the current sought. The relationship between input and output in each scale is linear.

FIG. 6 shows time response curves of currents searched from several groups of patients. The search is made using the present invention to people with different diseases under the same conditions. Diagnosis of the disease is made in advance by other diagnostic means. This search is performed using a step signal of 2.0 V as the stimulation voltage. In FIG. 6, the abscissa indicates the time expressed in seconds (s) including the zero point corresponding to the front edge of the step signal, and the ordinate indicates the negative logarithmic value N of the response current. Sixth
In the figure, the five curves correspond to the same five groups of people as in FIG. 3, that is, curve 3 is searched from the normal control group and curve 1 is from the patient group with manic psychosis. Curve 2 was searched from a group of patients with mildly abnormal autonomic nervous system, curve 4 was searched from a group of patients with mild metabolic abnormalities, and curve 5 was searched from a group of cancer patients in advanced stages. Things. As can be seen from the curves shown in FIG. 6, when the search device according to the invention is used to search at a particular acupoint, patients with different illnesses have different aspects of the response current time. There is a change. The response to the change in current for this purpose is also effective for diagnosis. Sixth
According to the figure, the time response curves of patients with severe illness (curves 1 and 5) have a significant difference from the time response curves of normal control (curve 3), but mild illness (curves 2 and 5). It can be seen that the time response curve of the patient with curve 4) has a tendency to approach that of the normal control curve 2 as time changes. It is clear from the data of FIG. 6 that the response current values sought from patients with different illnesses within the range of 1-2 seconds have the most discernable differences, and therefore the sampling and holding circuit When used to sample the response current, the sampling time should be delayed from the front edge of the stimulus signal by 1-2 seconds, preferably 1.5 seconds. It should be noted that the data shown in FIGS. 2 and 3 are all sampled with a time delay of 1.5 seconds. On the other hand, if the curve shown in FIG. 6 is sampled at many measurement points, it is possible to search for the rise, peak value and slope of the slope of the time response curve, thereby diagnosing the disease and the degree of the disease. It is effective for diagnosing.

FIG. 7A shows an embodiment of the signal processing circuit 60 shown in FIG. This apparatus is characterized in that a time response curve is sampled at a predetermined time and useful information corresponding to the characteristics of the curve shown in FIG. 6 is obtained. In Figure 7A, a block 60A surrounded by a dotted line shows a signal processing circuit as a whole, reference numeral 601 has an input signal V ₁ issued from the trigger switch for searching the electrode 20, and the signal V ₁ the two output signals V ₂ and V ₃ occurs when activated by. V ₃ wherein is provided to stimulus signal generating circuit 42 shown in FIG. 1 in order to control the generation of the stimulation signal.
On the other hand the signal V ₂ is supplied to adjustable delay circuit 602, and controls the generation of the sampling frequency signal Vtau. Reference numeral 603 indicates a sampling and holding circuit. The thing is, under the control of the sampling frequency signal Vtau, samples the amplified signals I ₂ corresponding to the micro-current signal I ₁ with an output of the micro-current amplifying circuit 50 shown in Figure 1. The sampled signal is supplied to the output device 70 as a signal I _3. Since all the blocks shown in FIG. 7A are conventionally known, detailed description thereof will be omitted.

FIG. 8 shows the waveform of the corresponding signal on the connection point shown in FIG. 7A. V ₁ wherein is an operation signal that is supplied by at Keru trigger switch to search for electrodes post surgery. Spotted A ₁ before the operation signal is determined by the user's interaction with the search for the electrode. Width between A ₁ and B ₁ are determined by the time to put on the acupuncture points of the patient for searching the electrode body. A ₁ and the next operation signal A ₂ of the interval, also is determined by the user's interaction with the following acupuncture points.
Thus, both the width of each operating signal and the interval between the two operating signals are determined by the operation of the device. V ₂ indicates a negative pulse generated by flip flop 601. The width of these negative pulses is defined in advance in accordance with the requirements of the circuit 603, before spotted is defined as A ₁ and A ₂ by Buchi previous V _1. V ₃ is flip-flop 601
Positive pulse generated by the circuit shown in FIG.
40 controls the generation of a step or pulse signal. The width of V _3, the sampling and holding circuit 603
Is determined in advance according to the request. I ₂ represents the output of the amplifier circuit. The output corresponds to a response current through a particular acupoint receiving a stimulation voltage. Waveform I ₂ corresponds to the family of curves shown in Figure 6. Beveled edge at point C I ₂ corresponds to the rear end of V _3. When the stimulation current becomes zero, I ₂ slopes in an exponential curve. Vτ is a sampling frequency signal generated by the adjustable delay circuit 602, and its front edge is a negative pulse V ₂
Is a negative pulse signal having a front edge that keeps a predetermined delay time i (for example, i = 1.5 s) from the front edge. This makes the sixth
It ensures that the sampling of the time response curve shown in the figure is performed at a specific point. I ₃ is the sampling and holding circuit 603
And displayed on the output device 70 in an analog or digital manner. In the embodiment shown in Figure 7A, the adjustable delay circuit 602, between the V ₂ sampling intervals, one is replaced by the time sequence circuit which generates a multiple of the sampling frequency signal is not further multiplex sampling circuit It should be noted that multiple sampling as well as parallel outputs can be employed to provide useful information about the time response curve such as slope, peak value, etc.

FIG. 7B shows another embodiment of the signal processing circuit 60 shown in FIG. Here, a block 60 surrounded by a dotted line
B indicates a signal processing circuit as a whole, and reference numeral 601 indicates a flip-flop similar to that shown in FIG. 7A. Sign 60
4 is an A / D converter for converting an analog output I ₂ of the amplifier circuit 50 into a digital signal to be processed by the CPU 605. Once more actuation signals V _2, CPU 605 is an A / D converter in accordance with the operation program stored in advance in the storage device 606
The digital output of 604 is processed and then supplied to output device 701 via I / O interface 607. CPU605
Output includes a time response curve of a current obtained by searching for a rise curve, a peak value, a slope curve, a time to reach a peak value, a difference between a search value and a normal value, and the like at the acupoint. . Information such as the patient's name, age, gender, code of the searched acupoints, date and time, etc.
3 and later provided for performing storage and statistical processing. Each portion 701, 702, 703 is known in the prior art and will not be described in further detail. If time response curve alone needed, the output signal I ₂ of the amplifier circuit 50 may be directly supplied to a conventional oscilloscope or curve tracer. This allows the signal processing circuit 60 and the output device 70 for processing and displaying the curve to be replaced by these conventional devices. These conventional devices are known in the prior art and need not be described in further detail.

FIG. 9 shows a flowchart of the operation program in the CPU 605 of FIG. 7B. Wherein the program is started from step 100 by Buchi previous signal V ₂ provided by the flip-flop 601. Step 110 is A / D
This is an instruction fetching step for extracting the digitized signal output from the converter. The extracted data is stored in the internal storage device 606 in the storage step 120 for later use. Parameters such as the rise curve, peak value, slope curve, and time of peak value in the time response curve are calculated from the data extracted in step 130, and the calculated data is further compared with a previously stored normal value, or It is subjected to statistical processing. In step 140, the search result is supplied to the output device 701, where it is displayed and printed, or output to the external storage device 702 and stored therein. Thereafter, the program reaches stop step 150. All of these processes are known in the prior art and will not be described in further detail. In addition, further processing of the data provided by the device is beyond the scope of the present invention and will not be described.

FIG. 10 illustrates the structure of an exemplary embodiment of the search electrode shown in FIG. Here, reference numeral 20 denotes a search electrode as an entire configuration, and reference numeral 201 denotes a mental probe as an inner conductor having a diameter in a range of 1.0 to 2.0 mm, and a non-inverted contact with the acupoint skin. It has a smooth tip to make it work. Reference numeral 202 denotes a mental / shielding layer as an external conductor that covers the periphery of the electrode (mental probe) and shields the entire mental probe 201 from environmental interference. Reference numeral 203 denotes the mental probe 2
1 shows a concentric cable having an inner conductor connected to 01 and an outer conductor connected to a shielding layer 202. Code 20
Reference numeral 4 denotes a spring having one end fixed to the shielding layer 202 via the insulator 2014 and the other end fixed to the mental probe 201 via another insulator 2013. Reference numeral 205 denotes a hair spring. By employing the configuration of the spring 204 and the hair spring 205, the mental probe 201 can move in the axial direction with respect to the shielding layer 202, and the spring 204 directs the mental probe 201 to its normal position. Elastically biased. The hair spring 205 enables a good electrical connection during the axial movement of the mental probe 201. Therefore, the pressure applied to the acupoint
The spring 204 keeps a constant value during the search operation. Reference numeral 206 denotes an insulated pin having one end extending through a slot provided in the shielding layer 203 and the other end fixed to the mental probe 201. This causes the pin 206 to move with the mental probe, triggering the switch 207 to send an operating signal over line 2011 to the signal processing circuit.
Supply 60. Reference numeral 208 denotes an insulating tube that insulates the mental probe 201 from the shielding layer 202 so that the mental probe 201 can move in the axial direction. Reference numeral 209 denotes a tube that can move along the shielding layer 202 while maintaining the connection with the shielding layer 202, thereby changing the length of the portion where the mental probe 201 protrudes from the end face of the tube. When the mental probe touches the acupoint in the skin, the tip of the mental probe and the adjustable insulating tube 209
The pressure applied to the skin because both of its front ends contact the skin, when the mental probe is retracted from its normal position to a position where its tip and the front end of the tube 209 are flush. Is determined by the elastic force applied to the mental probe 201 by the spring 204. When the tube 209 is adjusted to move rearward along the shielding layer 202, the distal end portion of the mental probe 201 protruding outward from the tube 209 becomes longer. Therefore, the pressure applied to the acupoint during the search operation is further increased. The opposite case can be similarly considered. In this way, the pressure of the mental probe can be adjusted quantitatively and well. Reference numeral 2010 is a search insulated housing that insulates between the shielding layer and the user's hand to avoid interference caused by the user's hand. Reference numeral 2012 denotes an insulating layer that insulates the wire connected to the mental probe from the shielding layer. As evident in FIG. 10, the searched signal I ₁ is output via the inner conductor of the concentric cable 203 and the operating signal V ₁ is output via line 2011,
This prevents interference between these two outputs. The switch 207 and the line 2011 are provided outside the shielding layer 202.

FIG. 11 shows another embodiment of the signal processing and display portion of the device of the present invention. In the present embodiment, the signal processing circuit 60 shown in FIG. 1 includes a pair of comparators connected in parallel, and the output device 70 includes a pair of light emitting diodes (LEDs) connected to one of the comparators. It is comprised including.
The qualitative display of the search result is satisfied by the very simple circuit of this embodiment. In FIG. 11, reference numeral 610A denotes a first comparator having an inverting input terminal connected to the output terminal of the amplifier circuit 50. Its non-inverting input terminal is connected to the threshold voltage V _th1, the output terminal is connected to LED710A. Reference numeral 610B denotes a second comparator having a non-inverting input terminal connected to the output terminal of the amplifier circuit 50. The comparator has an inverting input terminal connected to the threshold voltage V _th2 , and an output terminal connected to the second LED 710B. An output terminal of the second comparator 610B, transistor T _1, between the constructed LED710B comprise clamping diodes D _1, and the resistor r are cut-off circuit 630 is connected. The first and second threshold voltages V _th1 and V _th2 are respectively similar to the voltage _dividing network 62.
Generated by 0. Voltage divider network 620 is configured to include dividing resistors connected in series clamp diode D ₂ and a set. During the search operation, the output signal I ₂ of the amplifier circuit 50 produces an input signal U ₂ to the non-inverting input terminal of the inverting input terminal and the comparator 610B of the comparator 610A. Analysis of this circuit shows that when V _th1 <U ₂ <V _th2 , both comparators 610A and 610B
Is negative, indicating that _two LEDs are illuminated and that U2 is in the normal range. If U ₂ <V _th1 , the output of comparator 610A is positive, the output of comparator 610B is negative,
A does not work, LED 710B works. When U ₂ <V _th2 ,
The output of comparator 610A is negative, comparator 610B is positive, LED 710A emits light, but LED 710B does not operate. By selecting circuit parameters, V _th1
It can be selected according to the level of I ₁ = 10 ^-8 A, and V _th2
Can be selected according to the level of I ₁ = 10 ⁻⁶ A.
And the above circuit is I ₁ <10 ^-8 A (LED710A does not emit light and LED710A
B emits light), 10 ^-8 <10 ^-6 A (lights both LEDs 710A and 710B) and 10 ^-6 A <I ₁ (LED 710A emits light and LED 710B does not emit light). In this way,
The searched microcurrent signal has a normal value of 10 ⁻⁸ <10
It is qualitatively indicated with a range of ^-6 A. When the search electric loop is open, that is, when I ₂ = 0 and U ₂ = 0, the output of the comparator 610A becomes a positive voltage and the output of the comparator 610B becomes a saturated negative voltage. This is conducting by the potential drop transistor T ₁ is generated in the resistor r while conducting clamping diode D ₁ of the cut-off circuit 630, LED is cut off. Therefore, if U ₂ = 0, none of the LEDs 710B emits light, and no error occurs in the display when the electric loop for searching is opened.

As is clear from the circuit shown in FIG. 11, the circuit only displays the search result qualitatively, so that both the demand for the circuit and the cost are low. Therefore, the circuit can be used without any trouble in daily use. On the other hand, since the step signal and the sampling and holding circuit are not employed in this embodiment, the user can hold the search electrode that moves continuously on the skin until an abnormal display occurs. In this way, by using the present apparatus, it is possible to search for and apply a particular special acupoint.

FIG. 12 shows the relationship between the pressure applied to the acupoints of the skin by the search electrode of the present invention and the environmental temperature and humidity. As described above, when the pressure acting on the skin by the mental probe of the search electrode changes, the search accuracy is affected. On the other hand, environmental temperature and humidity change the blood circulation in the small blood vessels of the skin and thus the specific resistance of the skin,
It also affects search accuracy. ADVANTAGE OF THE INVENTION The search electrode which concerns on this invention can compensate the influence of the change of temperature and humidity by adjusting the pressure with which a mental probe withstands acupoints of skin. FIG. 12 shows the relationship between the pressure and the temperature. The horizontal axis represents the temperature expressed in degrees Celsius (° C.), and the vertical axis represents the pressure expressed in grams. Twelfth
The curves shown correspond to low temperatures, where a 20% increase in temperature results in a 20 gram decrease in pressure. In the search device of the present invention, the elastic force of the spring 204 is proportional to the compression length, and the pressure applied to the acupoint by the mental probe changes the position of the adjustable tube 209 so that the mental probe protrudes from the tube 209. Is substantially adjusted by changing the length. And the tube shown in Figure 10.
209 is graduated based on the curve shown in FIG. 12, and a position corresponding to the temperature is displayed.

With the exception of the search electrodes shown in FIG. 10, needles for acupuncture can be used as search or reference electrodes for this device.
Therefore, it is convenient for an acupuncturist to use the apparatus of the present invention for diagnosing and operating a disease. When the needle is used as a search electrode and, if necessary, as a reference electrode, skin resistance does not affect the search by the invasive electrode and the stimulation generated by the circuit 40 shown in FIGS. The voltage is selected to be about 0.5V, and a substantially similar search result is obtained.

Although the principle and structure for searching for a bioelectric signal according to the present invention have been described in detail with reference to the drawings, those skilled in the art will appreciate that many modifications and repetitions of the above embodiment can be made without departing from the spirit and scope of the present invention. It is clear to do the sequencing. Therefore, these examples are used only for explanation and understanding of the present invention, and do not limit the scope of the present invention.

[Brief description of the drawings]

FIG. 1 is a block diagram illustrating the configuration of the device of the present invention, FIG. 2 is a graph showing statistical results of response currents searched by applying different stimulus voltages to healthy people, FIG.
FIG. 5 is a diagram showing a relationship between a stimulus voltage and a response current corresponding to people having different health problems, FIG. 4 is a diagram showing an embodiment of a stimulus signal generation circuit shown in FIG. 1, and FIG. 5A. And the first
FIG. 5B shows two different embodiments of the micro-current amplifier circuit shown in FIG. 1, respectively, and FIG. 6 corresponds to people with different health problems with particular stimulation voltages applied. FIG. 7A and FIG. 7B show two different embodiments of the signal processing circuit shown in FIG. 1, respectively. FIG. 8 shows the waveforms appearing at the connection points shown in FIG. 7A. FIG. 9, FIG. 9 is a program flowchart used in the embodiment shown in FIGS. 7A and 7B, FIG. 10 is a sectional view showing an exemplary embodiment of the search electrode shown in FIG. 1, and FIG. FIG. 9 is a circuit diagram showing a third embodiment of the search device according to the present invention.
FIG. 12 is a diagram showing the relationship between the pressure applied to the skin search point by the search electrode of the present invention and the environmental temperature and humidity. 20 …… Search electrode, 30 …… Reference electrode, 40 …… Stimulation signal generation circuit, 50 …… Micro current amplification circuit, 50A, 50B …… Amplification circuit, 60,60A, 60B …… Signal processing circuit, 70… … Output device, 201… Mental probe (inner conductor), 202…
Blocking layer (outer conductor), 203: Concentric cable, 204: Spring (elastic body), 207: Trigger switch, 208:
... insulating layer, 209 ...... insulating tube, 401 ...... flip-flop, 501A ...... logarithmic micro-current amplifier, 502A ...... temperature compensation circuit, 503A ...... inverting circuit, T _1, T ₂ ...... junction FET
(First-stage differential amplifier), T ₄ , T ₅ ... Transistors (second-stage differential amplifier), S... Selection switch, N.
Resistor network, 601 …… Flip flop, 602…
... Adjustable delay circuit, 603 ... Sampling and holding circuit, 604 ... A / D converter, 605 ... Central processing unit (CPU),
606: Internal storage device, 607: I / O interface, 6
10A first comparator, 610B second comparator, 701
Output device, 702 …… External storage device, 703 …… Keyboard,
V _th1 ... low threshold voltage, V _th2 ... high threshold voltage, 71
0A, 710B …… Light emitting diode (LED)

 ──────────────────────────────────────────────────続 き Continued on the front page (72) Inventor U Du Minh, China Shanghai Honsil 100 Hao 18 Hao Lo Shirou (No address) (56) References JP-A-1-99556 (JP, A) JP JP-A-62-90165 (JP, A) JP-A-61-128942 (JP, A) JP-A-57-43752 (JP, A) JP-A-56-34348 (JP, A)

Claims (14)

(57) [Claims] A search electrode; a reference electrode; an amplification circuit connected to the search electrode and amplifying a searched signal; a stimulation signal generation circuit connected to the reference electrode and applying a stimulation voltage. A signal processing circuit connected to an output terminal of the amplifier circuit and processing an output signal of the output terminal; and an output device connected to an output terminal of the signal processing circuit and displaying a search result. In the bioelectric signal searching device, the stimulus voltage generated by the stimulus signal generation circuit is
A DC voltage in the range of 0.5～3.0V, the amplifier circuit is constituted by a micro electric amplifier, 10 ^-11
A bioelectric signal search device in which microcurrents in the range of ~ 10 ^-4 amps are amplified. 2. The micro electric amplifier according to claim 1, further comprising: a logarithmic micro electric amplifier, a temperature compensating circuit, and an inverting circuit. The logarithmic micro current amplifier has an input terminal connected to the search electrode. An output terminal connected to an input terminal of the temperature compensation circuit, wherein the temperature compensation circuit has an output terminal connected to an input terminal of the inversion circuit, and an output of the inversion circuit is an input of the inversion circuit. 2. The bioelectric signal search device according to claim 1, wherein the bioelectric signal search device outputs an output signal applied to a terminal and proportional to a negative logarithmic value of the microcurrent. 3. The amplifying circuit includes a first differential amplifier, a second differential amplifier, an emitter / follower, and a feedback circuit including a selection switch and a resistor network. The first differential amplifier has an input terminal connected to the search electrode, and an output terminal connected to an input terminal of the second differential amplifier, wherein the second differential amplifier comprises: An output terminal connected to an input (base) terminal of the emitter / follower;
The follower has its output supplied to the input terminal of an output processing circuit, the feedback circuit is connected between the input terminal of the first differential amplifier and the output terminal of the emitter follower, and the gain of the amplifier circuit is used for the selection. 2. The bioelectric signal search device according to claim 1, wherein the bioelectric signal search device is configured to perform exponentially graduated linear amplification of a microcurrent within a range changed by a switch. 4. The search electrode comprises: an inner conductor; an outer conductor covering the inner conductor; a concentric cable having an inner conductor and an outer conductor connected to the inner conductor and the outer conductor, respectively; And an insulating layer that insulates each of the outer conductors from each other at a search end, wherein the inner conductor retains a non-inverting contact with a skin acupoint while the outer conductor is insulated from the skin during the search. The bioelectric signal search device according to claim 1, wherein 5. The search electrode includes: an inner conductor formed by an acupuncture needle; an outer conductor covering the inner conductor; and an inner conductor and an outer conductor connected to the inner conductor and the outer conductor, respectively. A concentric cable, and an insulating layer that insulates each of the inner conductor and the outer conductor from each other at a search end portion. The bioelectric signal search device according to claim 1, wherein the device is insulated from the skin, and a stimulation voltage generated by the generation of the stimulation signal is a DC voltage in a range of 0.5 to 1.5V. 6. The search electrode is fixed to the inner conductor and the outer conductor at their ends using insulating properties, and is configured to be able to move the inner conductor in the longitudinal direction with respect to the outer conductor. 5. The bioelectric signal searching device according to claim 4, wherein the bioelectric signal searching device is configured to include an elastic body that keeps the pressure applied to the acupoints by the inner conductor constant. 7. The search electrode is provided at a search end of the outer conductor which can be adjusted in a length direction of the outer conductor, thereby changing an adjustable length of the inner conductor with respect to the outer conductor. 7. The bioelectric signal search device according to claim 6, further comprising pressure adjusting means for changing a pressure applied to the acupoint via the internal conductor by the elastic body. 8. The signal processing circuit includes a delay circuit and a sampling and holding circuit, wherein the sampling and holding circuit outputs an output signal of the amplification circuit for a delay time controlled by the delay circuit. 2. The bioelectric signal search device according to claim 1, wherein the bioelectric signal search device is configured to sample the data, hold the sampled signal, and supply the sampled signal to the output device. 9. The signal processing circuit includes an A / D converter, a central processing unit (CPU), a storage device, an interface circuit, and a keyboard. An input terminal connected to an output terminal of the amplifier circuit for converting an analog signal into a digital signal, the digital signal is sent to the CPU via a data bus, and the CPU is stored in the storage device. 2. The bioelectric signal search according to claim 1, wherein the digital signal is processed in accordance with an operation routine and a command input via the keyboard, and a processing result is sent to the output device via the interface circuit. apparatus. 10. The signal processing circuit supplies a high threshold signal and a low threshold signal, respectively.
A threshold voltage dividing circuit having two output terminals, connected to the output of the amplifier circuit and the outputs of the high threshold signal and the low threshold signal, to determine the range of the output signal; A pair of comparators for comparing the output of the amplifier circuit with the high threshold signal and the low threshold signal, respectively; a comparison result connected to the output terminal of the comparator and corresponding to the output signal of the comparator And a cut-off circuit that cuts off the output of the comparator when the output signal of the amplifier circuit is 0 and maintains the display device as it is. 2. The bioelectric signal search device according to 1. 11. The rope electrode further comprises a trigger switch for generating an activation signal when the inner conductor contacts the acupoint at a predetermined pressure, and the signal processing circuit is connected to the trigger switch. And a flip-flop that receives a signal from the trigger switch and generates a control signal for the signal processing circuit and the stimulus signal generation circuit in response to the activation signal. 7. The bioelectric signal searching device according to claim 6, further comprising a circuit controlled by the flip-flop to generate a stimulus signal. 12. The search electrode further includes a trigger switch for generating an activation signal when the inner conductor comes into contact with the acupoint at a predetermined pressure, and the signal processing circuit further includes a trigger switch. And a flip-flop configured to supply a control signal to the delay circuit by receiving the operation signal and generate a delay signal in the delay circuit, wherein the stimulus signal generation circuit controls the flip-flop. The bioelectric signal search device according to claim 8, further comprising a circuit that generates the stimulus signal. 13. The search electrode further includes a trigger switch for generating an activation signal when the inner conductor contacts the acupoint at a predetermined pressure, and the signal processing circuit is connected to the trigger switch. Receiving the operation signal, starting a processing routine of the CPU, and including a flip-flop for processing the searched signal, wherein the stimulus signal generation circuit is controlled by the flip-flop, 10. The bioelectric signal search device according to claim 9, comprising a circuit for generating a signal. 14. The delay circuit supplies an output signal,
9. The bioelectric signal search according to claim 8, further comprising: controlling a sampling and holding circuit, sampling an output signal of the amplification circuit with a predetermined delay time in a range of 1.0 to 2.0 seconds, and holding the sampled signal for output. apparatus.