JP4422997B2 - Disease recovery state determination device and program - Google Patents

Description

  The present invention relates to an affected area recovery state determination device and a program for determining the recovery state of an affected area based on a bioimpedance value of a human body.

  As a health index representing the health level of the human body, for example, there is a body fat percentage. As a health index estimation apparatus that estimates body fat percentage, which is one of the health indices, there is a body fat scale using a bioelectrical impedance method (BIA). This body fat meter can easily determine health indicators related to fat distribution such as the body fat percentage and visceral fat area index of the subject, and the measurement of such health indicators enables daily health management. In recent years, it has become popular in ordinary households because it can be easily performed.

  In this body fat scale, height, weight, age, etc., which are body specifying information for specifying the body of the subject, are previously input to the body fat scale, and then the bioimpedance value of the subject is measured. Then, the measured body bioimpedance value and the body specific information such as height, weight and age inputted in advance are calculated based on the measured values by the reference standard method described later. By substituting into the estimation formula, the body fat percentage of the subject is estimated and displayed. Here, the estimation formula used when obtaining the health index such as the body fat percentage is selected from parameters to be described later that are highly correlated with the health index to be estimated. It is obtained by measuring indices and parameters and performing regression analysis of each measured measurement data. Reference standard methods include computed tomography (CT-Scan), dual energy X-ray absorption (DEXA), magnetic resonance imaging (MRI), underwater weight weighing, and the like. The parameters include the subject's height, weight, age, bioimpedance value, and the like.

By the way, the bioimpedance value used in the body fat meter is a predetermined alternating current in the body of the subject, such as muscle, interstitial fluid, plasma, cerebrospinal fluid, lymph fluid, etc. This is electrical data obtained by flowing through a conduction path such as external liquid. When the amount of the extracellular fluid of the subject changes, the bioimpedance value also changes according to the change of the amount of the extracellular fluid. Therefore, by measuring this bioimpedance value, not only the above-described estimation of the body fat percentage of the subject but also a health index relating to the moisture content of the subject can be easily obtained. Therefore, in recent years, a blood circulation state display device that measures a bioimpedance value of a subject and estimates a blood circulation state that is one of health indicators related to the water content of the subject based on the measured bioimpedance value. Has been proposed (see, for example, Patent Document 1). In general, when the body is in a fatigued state, the blood circulation state in the body is getting worse. That is, the blood circulation state and the fatigue level in the body are strongly related to each other. Therefore, in recent years, health management guideline advice that measures the bioimpedance value of a subject and estimates the degree of fatigue, which is one of the health indicators related to the moisture content of the subject, based on the measured bioimpedance value. An apparatus has been proposed (see, for example, Patent Document 2). Thus, today, by measuring the bioelectrical impedance value of a subject, it is possible to estimate not only the body fat percentage of the subject but also the blood circulation state and fatigue level of the subject. .
Japanese Patent Laid-Open No. 11-076189 JP 2000-023936 A

  By the way, a part of the subject's body is exposed to extracellular fluids such as blood and lymph due to bacterial infections due to trauma such as bruises, cuts or stab wounds, skin disorders accompanied by inflammation, insect bites, sunburn, drug rashes, etc. When the swelling occurs and swelling occurs, the amount of water significantly increases in the swollen portion (hereinafter referred to as the affected part), and thus the bioimpedance value of the subject decreases.

  However, conventional health index estimation devices such as a blood circulation state display device and a health management guideline advice device use a bioelectrical impedance value, but in the first place estimate the blood circulation state and fatigue level of a subject. The state of the affected area cannot be estimated. On the other hand, since the bioimpedance value fluctuates within a day, it is not easy to accurately measure changes in the bioimpedance value of the affected area. Therefore, conventionally, the state of the affected area of the subject and the recovery tendency thereof could not be estimated easily.

  The present invention was made in order to solve such problems, and it is possible to easily know the state of the affected area such as the bruise and inflammation of the subject and the recovery tendency of the state, and the affected area recovery state determination An object is to provide an apparatus and a program.

In order to solve the above-mentioned problem, an affected area recovery state determination device according to the present invention is a measurement for measuring a bioimpedance value for each of a body part of a subject and a body part symmetrical to the one body part. And a difference in bioimpedance values measured for each of a body part having an affected part of the subject and a body part symmetrical to the one body part, and the one body part in a state without the affected part And a reference value based on a difference between bioimpedance values measured in the past for each of the one body part and the symmetrical body part, to determine a recovery state of the affected area of the subject Means.
Further, the affected area recovery state determination program according to the present invention includes a computer, a measuring unit for measuring a bioimpedance value for each of a body part of a subject and a body part symmetrical to the one body part, A difference in bioimpedance values measured for one body part having the affected part of the subject and a body part symmetrical to the one body part, and the one body part in the state without the affected part and the one Functions as arithmetic means for determining the recovery state of the affected area of the subject by comparing a reference value based on a difference in bioimpedance values measured in the past for each of the body part and the symmetrical body part It is an affected part recovery state determination program for making it happen.
In these inventions, the one body part and the body part symmetrical to the one body part may be a right arm and a left arm. The one body part and the body part symmetrical to the one body part may be a right leg and a left leg. Further, the reference value may be any one of a mode value, a median value, and an average value of differences in bioimpedance values measured in the past in a state where the affected part is not present.

When either a configuration, a technique for measuring the bioelectrical impedance value of the subject is established, hence measurement of bioimpedance values of the subject can easily performed, according to the recovery state of the diseased part of the subject Information can be easily obtained.

Further, when either a configuration, the bioelectrical impedance value of the subject which is relatively derivation does not influenced by the diurnal variation, it is possible to determine accurately the recovery trend of the affected area of the subject.

  The present invention is implemented by the configuration as described above, and an affected area recovery state determination apparatus and program capable of easily knowing the state of the affected area such as bruise and inflammation of the subject and the recovery tendency of the state are provided. There is an effect that it can be provided.

  The best mode for carrying out the present invention will be described below with reference to the drawings.

  First, the configuration of the affected area recovery state determination device according to the embodiment of the present invention will be described with reference to FIGS. 1 and 2.

  FIG. 1 is a perspective view schematically showing a configuration of an affected area recovery state determination apparatus according to an embodiment of the present invention. FIG. 2 is a plan view schematically showing a configuration of a determination display unit included in the affected area recovery state determination apparatus. Here, the affected area recovery state determination device uses the bioelectrical impedance method to determine the state of the affected area such as bruise and inflammation of the subject and the recovery tendency of the state, and the determined determination result A device that displays on a display means.

  As shown in FIG. 1, an affected area recovery state determination apparatus 1 according to the present embodiment includes an installation unit 4 and a determination display unit 2 that is detachable from the installation unit 4. Here, FIG. 1 illustrates a state where the installation unit 4 and the determination display unit 2 are isolated from each other. When the determination display unit 2 is attached to the installation unit 4, the determination display unit 2 is positioned so that the attachment / detachment unit 2 a of the determination display unit 2 is located within the storage area 4 a provided in the installation unit 4. Install. The installation unit 4 and the determination display unit 2 are electrically connected to each other by a connection cable 3. That is, the affected part recovery state determination device 1 exhibits a predetermined function as the affected part recovery state determination device 1 by the installation unit 4 and the determination display unit 2 being electrically connected to each other via the connection cable 3. Is configured to do.

  Further, as shown in FIG. 1, the installation unit 4 has a bioimpedance measurement surface 9. And on this bioimpedance measurement surface 9, each of electrodes E5, E6, E7, E8 used when measuring a bioimpedance value is disposed at a predetermined position. Here, when the subject measures his / her bioimpedance value, the subject's left leg is placed on the electrodes E5 and E6, and the right leg is placed on the electrodes E7 and E8. , Each ride. At this time, the front portion (hereinafter referred to as the thumb hill portion) of the left and right foot soles of the subject is brought into contact with the electrodes E5 and E8, and the heel portions of the left and right foot soles are brought into contact with the electrodes E6 and E7. Make contact. In addition, the bioimpedance measurement surface 9 of the installation part 4 is comprised so that the body weight of a subject can be measured here. Therefore, weight measuring means such as a load cell (not shown) is provided on the back surface of the bioimpedance measurement surface 9 so as to measure the weight of the subject on the bioimpedance measurement surface 9. Yes.

  On the other hand, as shown in FIG. 1, the determination display part 2 has the display part 5, the operation part 6, and the support parts 7a and 7b. The display unit 5 includes various information such as body identification information such as the height, age, and sex of the subject input by operating the operation unit 6 to be described later, the name of the site where the affected part is located, and the result of determining the affected part recovery state. Data is displayed. As shown in FIG. 2, the operation unit 6 includes a power ON / OFF key 6a, various mode switching keys 6b such as an initial setting mode, a measurement mode, and a registration mode, and a height, age, and Setting screen switching key 6c for switching setting screens when inputting various personal data such as gender, registration key 6d for storing the various personal data in the storage unit, and the state of the affected area of the subject And a determination key 6e for determining the recovery tendency, a numeric keypad 6f for inputting the various personal data, and a measurement key 6g for measuring the bioimpedance value of the subject. ing. By appropriately operating these various input keys 6a to 6g, the measurement of the bioimpedance value of the subject by the affected area recovery state determination apparatus 1 and the display of the determination result obtained by the measurement are performed. As shown in FIGS. 1 and 2, the determination display unit 2 is provided with support portions 7 a and 7 b that protrude in a plate shape. The support portions 7a and 7b are provided with electrodes E1, E2, E3, and E4 that are used when measuring the bioimpedance value. When the subject holds the determination display unit 2 in order to measure his or her bioimpedance value, for example, his / her left index finger is brought into contact with the electrode E1 disposed on the support unit 7a and the electrode E2 is brought into contact with the electrode E2. The determination display unit 2 is held such that the thumb is in contact with the electrode E3 disposed on the support portion 7b with the thumb of the right hand and the index finger of the right hand with the electrode E4.

  In the affected area recovery state determination apparatus 1, the electrodes E1 to E4 disposed in the determination display section 2 and the electrodes E5 to E8 disposed in the installation section 4 are together with a bioimpedance value measurement circuit 8 to be described later. A bioimpedance value measuring means for measuring the bioimpedance value of the subject is configured. More specifically, the electrode E1 and the electrode E5 are electrodes for causing a predetermined high-frequency current to flow through a current path having the index finger of the left hand of the subject and the thumb hill portion of the left leg as the measurement path ends. . The electrodes E4 and E8 are electrodes for supplying a predetermined high-frequency current to a current path with the index finger of the right hand of the subject and the thumb of the right leg as the end of the measurement path. Furthermore, the electrode 2 and the electrode 3, and the electrode 6 and the electrode 7 are used for measuring a voltage corresponding to a bioimpedance value in each part of the body of the subject via two electrodes in each of the electrodes. Electrode. The electrodes E <b> 1 to E <b> 4 are connected to the bioimpedance value measurement circuit 8 by a predetermined wiring (not shown) inside the determination display unit 2. The electrodes E <b> 5 to E <b> 8 are connected to the bioimpedance value measurement circuit 8 via the connection cable 3.

  Next, the configuration of the electric circuit of the affected area recovery state determination apparatus according to the embodiment of the present invention will be described with reference to FIG.

  FIG. 3 is a block diagram schematically showing the configuration of the electric circuit of the affected area recovery state determination apparatus according to the embodiment of the present invention.

  As shown in FIG. 3, the affected area recovery state determination device 1 includes an arithmetic processing unit 13. The arithmetic processing unit 13 includes an arithmetic unit 15 including an arithmetic processing device such as a CPU and a storage unit 16 including a storage device such as a memory. Here, the calculation unit 15 executes calculation and determination processing based on various data stored in the storage unit 16 and various routines. Further, in the storage unit 16, various input keys 6a to 6g arranged on the operation unit 6 are appropriately operated and measured via various body specifying information for specifying a subject inputted and electrodes E1 to E8. The bioimpedance values of each body part of the subject, for example, the left arm part, the right arm part, the trunk part, the left leg part, and the right leg part are stored. The storage unit 16 stores a plurality of bioimpedance values for each body part of the subject measured in the past, together with the measurement date and time. Further, the storage unit 16 calculates various reference values related to the bioelectrical impedance value of the subject obtained by the calculation unit 15 used for determining the recovery state of the affected part of the subject and the various reference values. For example, information necessary for operating the affected area recovery state determination device 1 and various programs are stored. The storage unit 16 also stores body weight data of the subject measured by weight measuring means such as the load cell 10 described later. The calculation unit 15 and the storage unit 16 are electrically connected to each other via a bus.

  On the other hand, a bioimpedance value measurement circuit 8, various input keys 6a to 6g, a display unit 5, a load cell 10, and a clock 14 are electrically connected to the arithmetic processing unit 13 via an I / O 12. ing.

  The bioimpedance value measurement circuit 8 measures the bioimpedance value for each part of the body of the subject via the electrodes E1 to E8. More specifically, this bioimpedance value measurement circuit 8 includes a voltage difference between a high-frequency current source that outputs a plurality of high-frequency currents having different frequencies, not shown here, and two different points in a current path through which the high-frequency current flows. And a voltage measuring device (not shown) for measuring the voltage. The high-frequency current source in the bioimpedance value measuring circuit 8 is electrically connected to the electrodes E1 and E5 or the electrodes E4 and E8 via an electrode changeover switch 11 described later, whereby the left hand of the subject's body. In addition, a high-frequency current having a predetermined frequency is passed through a current path having the left leg or the right hand and right leg as ends. On the other hand, the voltage measuring device in the bioimpedance value measuring circuit 8 is appropriately connected to any two of the four electrodes E2, E3, E6, and E7 via the electrode changeover switch 11 described later, and the connection is made. The voltage difference between the two electrodes is measured. Then, the bioimpedance value of the subject is determined for each body part from the current value supplied from the high-frequency current source and the voltage difference measured by the voltage measuring device. As described above, the bioimpedance value measurement circuit 8, the electrode changeover switch 11, and the electrodes E1 to E8 are used to measure the bioimpedance value for each part of the body of the subject. The bioelectrical impedance measurement circuit 8 can also determine the ratio of extracellular fluid and intracellular fluid in the subject's body.

  The various input keys 6a to 6g are as described above, and the operation unit 6 includes a power ON / OFF key 6a, a mode switching key 6b, a setting screen switching key 6c, a registration key 6d, and a determination key 6e. , A numeric keypad 6f and a measurement key 6g.

  The display unit 5 also displays various body-specific information such as the height, weight, age, and sex of the subject input by appropriately operating the various keys 6 a to 6 g of the operation unit 6, and the subject measured by the load cell 10. A reference value read from the storage unit 16 obtained based on the body weight of the examiner or a bioimpedance value of the subject's health measured in the past, or a test measured by the bioimpedance value measurement circuit 8 A bioimpedance value for each part of the person's body is displayed. In addition, an affected part recovery state determined by comparing the reference value with a bioimpedance value measured in a state where the subject has the affected part is also displayed.

  The load cell 10 constitutes a weight measuring means for measuring the body weight of the subject. The weight measuring means is configured such that when the subject is on the bioimpedance measuring surface 9 shown in FIG. 1, the weight of the subject is measured by the load cell 10. A signal related to the weight data of the subject output from the load cell 10 is amplified by an amplifier (not shown) to ensure measurement accuracy and then A / D converted. The data is input to the arithmetic processing unit 13 via / O12. Data relating to the weight data of the subject input to the arithmetic processing unit 13 is stored in the storage unit 16 as one item of the body specifying information of the subject.

  The timepiece 14 is used for the storage unit 16 to store the time when the subject measures the bioelectrical impedance value together with the measured bioelectrical impedance value.

  In addition, an electrode changeover switch 11 is connected to the above-described bioelectrical impedance value measurement circuit 8. The electrode changeover switch 11 is connected to electrodes E1 to E8 that are in contact with a predetermined part of the subject's hand or leg. This electrode changeover switch 11 appropriately switches the connection state between the electrodes E1 to E8 and the bioelectrical impedance value measuring circuit 8 necessary for measuring the bioelectrical impedance value of the subject as necessary.

  With the above configuration, in the affected area recovery state determination device 1, it is possible for the subject to input the body specifying information such as the height, weight, age, and sex of the subject by appropriately operating the operation unit 6, The operation input data is converted into a digital signal by an A / D converter as required, and then input to the arithmetic processing unit 13. And the said body specific information input into the arithmetic processing part 13 is memorize | stored in the memory | storage part 16 suitably. The subject holds the determination display unit 2 with both hands so as to be in contact with the electrodes E1 to E4 and places both legs on the electrodes E5 to E8 of the installation unit 4 as described above. Then, the bioimpedance value of the subject is measured by appropriately operating the operation unit 6, and the measured bioimpedance value is converted into a digital signal by an A / D converter as necessary, It is stored in the storage unit 16. Then, based on the information stored in the storage unit 16, the arithmetic processing unit 13 displays the state of the affected part of the subject and its recovery tendency on the display unit 5. That is, the subject can easily know the state of the affected part such as bruise and inflammation and the recovery tendency of the state based on the change in the bioelectrical impedance value by using the affected part recovery state determination device 1.

  Next, the operation of the affected area recovery state determination apparatus 1 configured as described above will be described with reference to the drawings.

  FIG. 4 is a flowchart showing an example of the operation of the affected area recovery state determination device 1. Here, a case will be described in which the state of the affected area and its recovery tendency are determined based on the change in the absolute value of the bioelectrical impedance value of the subject.

  In addition, in the affected area recovery state determination apparatus 1 according to the present invention, it is necessary to perform initial setting when the battery is attached for the first time after purchase. Therefore, the mode switching key 6b is operated to set the operation mode of the affected area recovery state determination device 1 to the initial setting mode. Then, after the operation mode of the affected area recovery state determination device 1 is set to the initial setting mode, data such as year, month, day, and time at the time of operation is input by operating the numeric keypad 6f. It should be noted that the input of data such as year, month, day, and time at the time of this operation is performed by operating the setting screen switching key 6c so that a setting screen for inputting each of year, month, date, time, etc. is appropriately displayed. Switched and done. The setting screen switching key 6c is operated for the same purpose not only when inputting the year, month, day and time but also when inputting body specifying information such as the height, weight, age and sex of the subject. . And the initial setting of the affected part recovery state determination apparatus 1 is complete | finished by the above.

  Now, in FIG. 4, when the power ON / OFF key 6a is pressed, the power of the affected area recovery state determination device 1 is turned ON (step S1). As a result, the affected area recovery state determination device 1 enters an available standby state. Thereafter, by operating the mode switching key 6b, the operation mode of the affected area recovery state determination apparatus 1 is switched to the registration mode (step S2). Then, while operating the setting screen switching key 6c, the body specifying information such as the height, weight, age and sex of the subject is registered in the storage unit 16 by operating the numeric keypad 6f and the registration key 6d. (Step S3). The input of the body specifying information of the subject in step S3 is an operation performed for classifying and specifying the subject. Then, after the body identification information of the subject is input and registered in the storage unit 16, the operation mode of the diseased part recovery state determination device 1 is switched to the absolute value measurement mode by operating the mode switching key 6b (step) S4). Subsequently, the subject holds the determination display unit 2 with both hands and gets on the installation unit 4. At this time, the subject brings the mother-child hill part on the back of the left leg into contact with the electrode E5 and the left footpad in contact with the electrode E6. Is placed on the installation section 4 so as to contact the electrode E7, the left index finger is brought into contact with the electrode E1, the left thumb is brought into contact with the electrode E2, the right index finger is brought into contact with the electrode E4, and the right thumb is brought into contact with the electrode E3. The determination display unit 2 is held so that the As described above, after the subject takes the measurement posture, the measurement key 6g disposed on the support portion 7b of the determination display unit 2 is pressed to start measuring the bioimpedance value of the subject (step) S5). In addition, in order to eliminate the influence of the deviation of moisture balance at bedtime on the measured bioimpedance value of the subject, the measurement is performed while avoiding the morning. Next, after the measurement of the bioimpedance value of the subject is started in step S5, it is determined whether or not the bioimpedance values of both arms and legs of the subject are stable (step S6). When it is confirmed in step S6 that the bioimpedance values of both arms and both legs of the subject are stable, each body part of the subject (right arm, left arm, right leg, and left leg). Measurement of the bioelectrical impedance value is started (step S7). At this time, the measured bioimpedance value for each body part of the subject is stored in the storage unit 16 together with the date and time of measurement. Further, while the bioimpedance value of the subject is being measured in step S7, a predetermined comment indicating that the bioimpedance value is being measured is displayed on the display unit 5. Next, after the bioelectrical impedance value for each body part of the subject is measured in step S7, the determination key 6e is pressed. Then, in the arithmetic processing unit 13, the time at which the previous step S <b> 7 of the subject in which the measured bioimpedance value for each body part of the subject is stored in the storage unit 16 in advance is executed. Are compared with each bioelectrical impedance value (hereinafter referred to as a reference value) for each body part in the healthy state at the same time (step S8). Here, as the reference value, one of a mode value, a median value, and an average value of bioimpedance values measured a plurality of times for each body part during the health of the subject is employed. Also, in step S8, the reason why the bioelectrical impedance value of the subject measured in step S7 is compared with the reference value for health at the same time as the time when the subject's past step S7 was executed. This is to eliminate the influence of daily fluctuations in the bioimpedance value of the subject. That is, by comparing the bioimpedance value measured in step S7 with the reference value measured at the same time, it becomes possible to accurately determine the state of the affected area of the subject and its recovery tendency. . Then, by comparing the bioelectrical impedance value for each body part of the subject with the reference value, the name of the part where the subject's affected part exists, the state of the affected part and its recovery tendency are determined, The determined result is displayed on the display unit 5 (step S9).

  Here, the display screen displayed on the display unit 5 will be described with reference to the drawings. FIG. 5 is a plan view schematically showing an example of a display screen displayed on the display unit 5. As shown in FIG. 5, the display unit 5 includes the name of the part having the affected part of the subject, the measured value of the bioimpedance value measured in the current path including the part having the affected part, and the past measured value. The reference value stored in the storage unit 16 and the recovery status of the affected area of the subject are displayed. Here, the name of the site having the affected part is the left leg, the measured bioimpedance value is 279Ω, the bioimpedance value as the reference value is 287Ω, and the recovery status of the affected part is good as a determination result It is displayed. In addition, when it determines with the recovery condition of an affected part not being unsatisfactory, that is displayed on the display part 5. FIG.

  On the other hand, FIG. 6 is a plan view schematically showing another example of the display screen displayed on the display unit 5. As shown in FIG. 6, the display unit 5 displays the name of the site having the affected part of the subject, the degree of recovery of the affected part, and the rank display of the degree of recovery. Here, the name of the site having the affected part is the left leg, the degree of recovery of the affected part is 76%, and the rank display of the degree of recovery is as shown in FIG. As described above, the display screen displayed on the display unit 5 may be the display screen shown in FIG. 6, whereby the recovery state of the affected area of the subject can be visually grasped.

  Finally, in FIG. 4, when the use of the affected area recovery state determination device 1 is finished, the power ON / OFF key 6a is pressed to turn off the affected area recovery state determination device 1 (step S10). Thereby, the affected area recovery state determination device 1 is in a use stop state.

Example 1
An embodiment of the affected area recovery state determination apparatus 1 that obtains and displays the degree of recovery of the affected area of the subject will be described below as an embodiment 1. Here, the present embodiment measures the bioimpedance value (absolute value) of the body part that has been bruised as the affected part, and determines the state of the affected part of the subject and the This is an example in which a recovery tendency is determined.

  FIG. 7 is a graph schematically showing the recovery state of the affected area of the subject over time. Here, in FIG. 7, the alternate long and short dash line indicates the reference value of the bioelectrical impedance value related to the left leg of the subject, and the dotted line indicates the change over time of the measured bioimpedance value related to the left leg of the subject. ing.

  As shown in FIG. 7, first, the measurement of the bioelectrical impedance value of the left leg is performed from the first day of measurement to the 9th day after the start of measurement in a state where the subject does not have an affected part (ie, a healthy state). It was confirmed that the reference value of the impedance value was 287Ω (one-dot chain line). Thereafter, as shown in FIG. 7, the subject bruised the left leg 12 days after the start of measurement. At this time, the bioimpedance value of the left leg of the subject decreased to 254Ω. That is, while the reference value of the bioimpedance value of the left leg of the subject was 287Ω, the bioimpedance value on the first day after bruising is 254Ω, and the difference between the reference value and the bioimpedance value after bruising is − It was found to be 33Ω. Thereafter, the bioelectrical impedance value from the start of measurement to 16 days later changes in the range of 250Ω to 260Ω. Therefore, it can be seen that the state of the bruise has not changed significantly compared to the state immediately after the bruise. However, the bioimpedance value 19 days after the start of measurement has increased to 279Ω, and the difference from the reference value of the bioimpedance value is −8Ω. That is, it can be seen that the bruise that occurred on the left leg of the subject almost recovered after 7 days from the occurrence of the bruise. At this time, the degree of recovery of the bruise occurring on the left leg of the subject is calculated as shown in Equation (1). The measurement result and reference value of the bioelectrical impedance value 19 days after the start of measurement and the recovery status of the affected area are displayed on the display unit 5 as shown in FIG. Further, the degree of recovery and determination of the affected area calculated by the equation (1) are displayed on the display unit 5 as shown in FIG.

((33Ω-8Ω) / 33Ω) × 100≈76 (%) (1)
After 19 days from the start of measurement, the difference between the bioelectrical impedance value of the subject's left leg and the reference value has changed to −15Ω (20 days later), −4Ω (21 days later), and −20Ω (22 days later). . That is, the bioelectrical impedance value of the subject's left leg is stable at a value close to the reference value. From this result, it can be considered that the bruise occurring on the left leg of the subject almost completely recovered 7 days after the occurrence of the bruise. Here, as the measurement data of the bioimpedance value after recovery from the bruise, an average value of measurement data over a plurality of days (here, measurement values on the 19th to 22nd days from the start of measurement) may be employed. As a result, it is possible to accurately determine the recovery state of the affected area without the influence of the measurement error.

  In this way, by measuring the bioimpedance value for each body part of the subject, the body based on the bioimpedance value of the subject in the health state measured in the past of each measured bioimpedance value. It is possible to obtain quantitative or qualitative information regarding the state of the affected area of the subject and the recovery tendency thereof from the amount of change with respect to the reference value for each part. In this case, a technique for measuring the bioimpedance value of the subject has already been established, and therefore the bioimpedance value of the subject can be easily measured. It can be obtained easily and accurately. In addition, since the recovery state of the affected area of the subject is quantitatively or qualitatively determined and visually displayed, the subject can easily and clearly show the recovery tendency of the affected area when the bioimpedance value changes. Can know. In addition, since the change in the measured bioimpedance value is based on the increase or decrease of extracellular fluid (interstitial fluid, plasma, cerebrospinal fluid, lymph fluid, etc.) in the affected area of the subject, Conditions such as bruises, trauma with bacterial infection, or skin disorders with inflammation, and their recovery tendencies can be suitably determined. Further, the affected area recovery determination device 1 includes a storage unit 16, and the reference value of the bioimpedance value of the subject measured in the past can be stored in the storage unit 16. It is not necessary to input the reference value every time the recovery state of the affected part is determined. That is, the trouble in determining the recovery state of the affected area of the subject is simplified. Then, by using the affected area recovery state determination device 1 and knowing the recovery state of the affected area, the subject can more effectively perform effective affected area treatment measures in daily life.

  Next, a modification of the best mode for carrying out the present invention will be described. Here, the case where the state of an affected part and its recovery tendency are determined based on the change in the relative value of the bioelectrical impedance value of the subject will be described.

  In the above description, an absolute value is used as the bioelectrical impedance value of the subject. In this modification, a relative value of the bioelectrical impedance value of the subject is used instead. That is, in a healthy state before the subject suffers trauma or the like, one body part (for example, the right arm) of the subject and a body part symmetrical to the one body part (for example, the left arm) Measure the bioimpedance value. Then, the difference (relative value) between the bioimpedance value of one body part of the subject obtained by each measurement and the bioimpedance value of the body part symmetrical to the one body part is obtained. The obtained relative value of the subject is stored in the storage unit 16 of the affected area recovery state determination apparatus 1. When measuring the bioimpedance value after the subject is injured, the bioimpedance value is measured for the body part having the affected part of the subject and the body part having the affected part and the symmetrical body part. To do. For example, when the subject has an affected part on the right leg, the bioimpedance value of the subject's right leg and the bioimpedance value of the subject's left leg are measured. Then, the difference (relative value) between the bioimpedance value of the body part having the affected part obtained by each measurement and the bioimpedance value of the body part having the affected part and a symmetrical body part is obtained. Then, the state of the affected area of the subject and the recovery tendency thereof are determined by comparing and determining the relative value in the health condition of the subject and the relative value after the subject is injured.

  Here, the operation of the affected area recovery state determination apparatus 1 in the present modification will be described with reference to the drawings.

  FIG. 8 is a flowchart showing a modified example of the operation of the affected area recovery state determination apparatus 1.

  In FIG. 8, when the power ON / OFF key 6a is pressed, the affected area recovery state determination apparatus 1 is turned on (step S1). As a result, the affected area recovery state determination device 1 enters an available standby state. Thereafter, by operating the mode switching key 6b, the operation mode of the affected area recovery state determination apparatus 1 is switched to the registration mode (step S2). Then, while operating the setting screen switching key 6c, the body specifying information such as the height, weight, age and sex of the subject is registered in the storage unit 16 by operating the numeric keypad 6f and the registration key 6d. (Step S3). Then, after the body identification information of the subject is input and registered in the storage unit 16, the operation mode of the diseased part recovery state determination device 1 is switched to the relative value measurement mode by operating the mode switching key 6b (step) S4). Subsequently, the subject holds the determination display unit 2 with both hands and gets on the installation unit 4. At this time, the subject brings the mother-child hill part on the back of the left leg into contact with the electrode E5 and the left footpad in contact with the electrode E6. Is placed on the installation section 4 so as to contact the electrode E7, the left index finger is brought into contact with the electrode E1, the left thumb is brought into contact with the electrode E2, the right index finger is brought into contact with the electrode E4, and the right thumb is brought into contact with the electrode E3. The determination display unit 2 is held so that the As described above, after the subject takes the measurement posture, the measurement key 6g disposed on the support portion 7b of the determination display unit 2 is pressed to start measuring the bioimpedance value of the subject (step) S5). Next, after the measurement of the bioimpedance value of the subject is started in step S5, it is determined whether or not the bioimpedance values of both arms and legs of the subject are stable (step S6). When it is confirmed in step S6 that the bioimpedance values of both arms and both legs of the subject are stable, each body part of the subject (right arm, left arm, right leg, and left leg). Measurement of the bioelectrical impedance value is started (step S7). At this time, the measured bioimpedance value for each body part of the subject is stored in the storage unit 16 together with the date and time of measurement. Next, after the bioelectrical impedance value for each body part of the subject is measured in step S7, the determination key 6e is pressed. Then, in the arithmetic processing unit 13, the measured bioimpedance value of one body part (for example, the right arm) of the subject and the bioimpedance value of a body part (for example, the left arm) symmetrical to the one body part. Difference (relative value) between the body part and the living body of one body part (for example, the right arm) in the past health state of the subject stored in advance in the storage unit 16. The impedance value is compared with a difference (hereinafter referred to as a relative reference value) between the one body part and the bioimpedance value of the body part that is symmetrical to the left and right (for example, the left arm) (step S8). Here, as the relative reference value, any one of a mode value, a median value, or an average value of the difference between the left and right body parts of the bioimpedance value measured multiple times for each body part when the subject is healthy. One value is adopted. Then, by comparing the bioelectrical impedance value difference between the left and right body parts of the subject with the relative reference value, the name of the part where the subject's affected part exists, the state of the affected part, and the recovery tendency thereof are obtained. The determination result is displayed on the display unit 5 (step S9).

  Here, the display screen displayed on the display unit 5 will be described with reference to the drawings. FIG. 9 is a plan view schematically showing an example of a display screen displayed on the display unit 5. As shown in FIG. 9, the display unit 5 includes a name of a site having an affected area of the subject, and a difference between left and right bioimpedance values measured by a current path having the affected area and a current path having no affected area. The relative reference value measured in the past and stored in the storage unit 16 and the recovery status of the affected area of the subject are displayed. Here, the name of the part having the affected part is the left leg, the left-right difference of the measured bioimpedance value is 3Ω, the left-right difference of the bioimpedance value as the reference value is 5Ω, and the affected part is recovered as a determination result The situation is marked as good.

  On the other hand, FIG. 10 is a plan view schematically showing another example of the display screen displayed on the display unit 5. As shown in FIG. 10, the display unit 5 displays the name of the part having the affected part of the subject, the degree of recovery of the affected part, and the rank display of the degree of recovery. Here, the name of the site having the affected part is the left leg, the degree of recovery of the affected part is 93%, and the rank display of the degree of recovery is as shown in FIG. As described above, the display screen displayed on the display unit 5 may be the display screen shown in FIG. 10, which makes it possible to visually grasp the recovery state of the affected area of the subject.

  Finally, when the use of the affected area recovery state determination device 1 is finished, the power supply ON / OFF key 6a is pressed to turn off the affected area recovery state determination device 1 (step S10). Thereby, the affected area recovery state determination device 1 is in a use stop state.

(Example 2)
Another embodiment of the affected area recovery state determination apparatus 1 for obtaining and displaying the degree of recovery of the affected area of the subject will be described below as an embodiment 2. Here, in this embodiment, the relative value of the bioimpedance value of the body part that has been bruised as an affected part is measured, and the state of the affected part of the subject and its recovery from the change over time of the relative value of the bioimpedance value. This is an example of determining a tendency.

  FIG. 11 is a graph schematically showing the recovery state of the affected area of the subject over time. Here, in FIG. 11, the alternate long and short dash line indicates a relative reference value that is a difference in bioimpedance values between the left and right body parts in the health state of the subject, and the dotted line indicates the distance between the left and right body parts of the subject after the injury. The change with time of the bioelectrical impedance value difference is shown.

  As shown in FIG. 11, first, the measurement of the bioelectrical impedance value difference between the left and right body parts in a state where the subject does not have an affected part (that is, in a healthy state) is performed from the first day of measurement until 9 days later. It was confirmed that the relative reference value of the examiner was 5Ω (one-dot chain line). Thereafter, as shown in FIG. 11, the subject bruised the left leg 12 days after the start of measurement. At this time, the bioelectrical impedance value difference between the left leg and the right leg of the subject increased to 34Ω. That is, it was found that the difference between the relative reference value of the subject and the bioimpedance difference after bruising was + 29Ω. Thereafter, the bioelectrical impedance value difference from the start of measurement to 16 days later changes in the range of 15Ω to 30Ω. Therefore, it can be seen that the state of the bruise has not changed significantly compared to the state immediately after the bruise. However, the difference in bioelectrical impedance value 19 days after the start of measurement has decreased to 3Ω, and the difference from the relative reference value is −2Ω. That is, it can be seen that the bruise that occurred on the left leg of the subject almost recovered after 7 days from the occurrence of the bruise. At this time, the degree of recovery of the bruise occurring on the left leg of the subject is calculated as shown in Equation (2). The measurement result of the bioelectrical impedance value difference, the relative reference value, and the recovery status of the affected area 19 days after the start of measurement are displayed on the display unit 5 as shown in FIG. Further, the degree of recovery and determination of the affected area calculated by the equation (2) are displayed on the display unit 5 as shown in FIG.

((29Ω-2Ω) / 29Ω) × 100≈93 (%) (2)
After 19 days from the start of measurement, the difference between the bioelectrical impedance value difference of the subject's left leg and the relative reference value has changed to + 2Ω (after 20 days), −4Ω (after 21 days), and + 3Ω (after 22 days). . That is, the bioelectrical impedance value difference between the left leg and the right leg of the subject is stable at a value close to the relative reference value. From this result, it can be considered that the bruise occurring on the left leg of the subject almost completely recovered 7 days after the occurrence of the bruise. Here, as the data of the difference between the bioimpedance value after recovery from the bruise and the relative reference value, the average value of the measurement data over a plurality of days (here, the measurement values on the 19th to 22nd days from the start of measurement) May be adopted. As a result, it is possible to accurately determine the recovery state of the affected area without the influence of the measurement error.

  Next, the relationship between the determination result of the recovery state of the affected part by the affected part recovery state determination device of the present invention and the subjective symptoms of the patient having the affected part will be described with reference to the drawings.

  FIG. 12 is a correlation diagram showing the relationship between the change over time in the bioelectrical impedance value of the subject and the change over time in the subjective symptoms. As shown in FIG. 12, it can be seen that the determination result of the recovery state of the affected area based on the measurement of the bioelectrical impedance value and the subjective symptoms of the patient having the affected area are substantially the same except for the 15th day. In addition, about the 15th day, although the pain is relieved from the previous day, the bioimpedance value is worse than the previous day. As a result, even if the pain is relieved, the affected area has not fully recovered, and it can be considered that attention is still necessary.

  In this way, even using the difference (relative value) between the bioelectrical impedance values between the left and right body parts, the state of the affected area of the subject and its recovery tendency can be determined. Further, since the state of the affected area and its recovery tendency are determined and displayed in the same manner as in the case of using the absolute value of the bioelectrical impedance value, the subject can easily know the state of the affected area and its recovery tendency. Moreover, the effect that the influence of the daily fluctuation | variation of a subject's bioimpedance value can be excluded is acquired by based on the difference of the bioimpedance value between right-and-left body parts. That is, it becomes possible to determine the state of the affected area and its recovery tendency more accurately.

  The affected area recovery state determination apparatus and program according to the present invention are an affected area recovery state determination apparatus and a program capable of easily knowing the state of the affected area such as bruise and inflammation of the subject and the recovery tendency of the state. Useful.

It is a perspective view which shows typically the structure of the affected part recovery state determination apparatus which concerns on embodiment of this invention. It is a top view which shows typically the structure of the determination display part which the affected part recovery state determination apparatus which concerns on embodiment of this invention has. It is a block diagram which shows typically the structure of the electric circuit of the affected part recovery state determination apparatus which concerns on embodiment of this invention. It is a flowchart figure which shows an example of operation | movement of the affected part recovery state determination apparatus which concerns on embodiment of this invention. It is a top view which shows typically an example of the display screen displayed on the display part of the affected part recovery state determination apparatus which concerns on embodiment of this invention. It is a top view which shows typically the other example of the display screen displayed on the display part of the affected part recovery state determination apparatus which concerns on embodiment of this invention. It is a graph which shows typically a recovery state with time of an affected part of a subject. It is a flowchart figure which shows the modification of operation | movement of the affected part recovery state determination apparatus which concerns on embodiment of this invention. It is a top view which shows typically an example of the display screen displayed on the display part of the affected part recovery state determination apparatus which concerns on embodiment of this invention. It is a top view which shows typically the other example of the display screen displayed on the display part of the affected part recovery state determination apparatus which concerns on embodiment of this invention. It is a graph which shows typically a recovery state with time of an affected part of a subject. It is a correlation diagram which shows the relationship between the time-dependent change of a subject's bioelectrical impedance value, and the time-dependent change of a subjective symptom.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Affected part recovery state determination apparatus 2 Judgment display part 2a Desorption part 3 Connection cable 4 Installation part 4a Storage area 5 Display part 6 Operation part 6a Power ON / OFF key 6b Mode switching key 6c Setting screen switching key 6d Registration key 6e Judgment key 6f Numeric keypad 6g Measurement key 7a, 7b Support part 8 Bioimpedance value measurement circuit 9 Bioimpedance measurement surface 10 Load cell 11 Electrode changeover switch 12 I / O
13 Calculation Processing Unit 14 Clock 15 Calculation Unit 16 Storage Unit E1 to E8 Electrode

Claims (8)

Measuring means for measuring a bioimpedance value for each of a body part of a subject and a body part symmetrical to the one body part;
A difference in bioimpedance values measured for one body part having the affected part of the subject and a body part symmetrical to the one body part, and the one body part in the state without the affected part and the one A computing means for determining a recovery state of the affected area of the subject by comparing a reference value based on a difference in bioimpedance values measured in the past for each of the body part and the symmetrical body part; An affected area recovery state determination device is provided. The affected part recovery state determination apparatus according to claim 1, wherein the one body part and a body part symmetrical to the one body part are a right arm and a left arm. The affected part recovery state determination apparatus according to claim 1, wherein the one body part and a body part symmetrical to the one body part are a right leg and a left leg. The reference value is any one of a mode value, a median value, or an average value of differences in bioimpedance values measured in the past in a state where the affected part is not present. The affected area recovery state determination device. Computer
Measuring means for measuring a bioimpedance value for each of a body part of a subject and a body part symmetrical to the one body part;
A difference in bioimpedance values measured for one body part having the affected part of the subject and a body part symmetrical to the one body part, and the one body part in the state without the affected part and the one Functions as arithmetic means for determining the recovery state of the affected area of the subject by comparing a reference value based on a difference in bioimpedance values measured in the past for each of the body part and the symmetrical body part A program for determining the affected area recovery state. The affected part recovery state determination program according to claim 5, wherein the one body part and a body part symmetrical to the one body part are a right arm and a left arm. The affected part recovery state determination program according to claim 5, wherein the one body part and a body part symmetrical to the one body part are a right leg and a left leg. The reference value is any one of a mode value, a median value, and an average value of differences in bioimpedance values measured in the past in a state where the affected part is not present. The affected area recovery state judgment program.

Images