JP2003062034A - Therapeutic unit having an impedance measuring function - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a therapeutic unit, capable of being easily used at home or the like and directly detecting a diseased part to be treated through measuring the living body impedance of the body of a patient by applying an electric current thereto, and capable of efficiently treating the diseased part through checking the effect of the treatment. SOLUTION: The therapeutic unit is provided with a measuring part for measuring the living body impedance of the sites of the body through applying an electric current to the body of the patient, and a therapeutic means for treating the diseased part of the patient. The therapeutic unit detects and treats the diseased part based on the measured impedance, and judges and displays the effectiveness of the treatment based on the varied amount between a first impedance before the treatment of the diseased part and a second impedance after the treatment thereof. Further, the therapeutic unit is provided with an operating means for determining several settings for therapeutic means, such as treatment intensity and treatment time, for a next treatment, based on the effectiveness of the treatment. The therapeutic unit controls the therapeutic means so as to carry out the next treatment based on the several settings for therapeutic means, such as treatment intensity and treatment time.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a therapeutic instrument with an impedance measurement function, which measures the impedance of the body and can effectively treat the affected area of a patient based on the measured value. Regarding

[0002]

2. Description of the Related Art Conventionally known medical treatment devices include a low-frequency treatment device and a hot moxibustion treatment device as an electric treatment device, and some low-frequency treatment devices also have another function. For example, in the electrotherapy device disclosed in Japanese Patent Application Laid-Open No. 50-128386, a low-frequency therapy device also has a pot exploration function, and in the electrotherapy device disclosed in Japanese Patent Application Laid-Open No. 7-313570, It is disclosed that the frequency treatment device is provided with the acupoint exploration function and the heat or moxibustion treatment function. The conventional electrotherapeutic devices disclosed in these publications have a plurality of therapeutic functions, can be used together, and can improve the therapeutic effect by performing acupoint exploration prior to the treatment. .

[0003]

However, the conventional electrotherapy device as described above is provided with a plurality of treatment functions in the low-frequency treatment device, and these are used together, and all of them have the acupoint exploration function. However, the purpose of the present invention is not to directly treat the affected area but to stimulate the acupuncture points based on so-called Oriental medicine to bring about the effect of healing the affected area. Further, for the treatment method using such acupoints, it requires specialized knowledge about the relationship between the symptoms and acupuncture points of the affected part and the position of the acupuncture points, even with a conventional treatment device having an acupoint exploration function, Searching for the exact position of the acupuncture point is not easy, and it may be difficult to perform accurate search. Therefore, it was not always easy to use and effective treatment at home.

In view of the above problems of the prior art, an object of the present invention is a therapeutic device that can be easily used at home and the like, and by applying an electric current to the body of a patient, a bioimpedance of a part of the body is provided. The object of the present invention is to provide a device which can measure a dance and directly search for an affected part to be treated, and at the same time, can effectively treat the affected part while confirming a therapeutic effect.

[0005]

In order to solve the above problems, a therapeutic device with an impedance measurement function according to the present invention measures the biological impedance of a body part by applying an electric current to the body of a patient. It is characterized in that it is provided with a living body impedance measuring means and a treatment means for treating the affected area of the patient, and the affected area is treated based on the measured impedance (claim 1).

[0006] In the body, an affected area such as a stiff shoulder appears due to poor blood circulation due to fatigue, and it is said that the impedance increases in such affected area. And, in the treatment device with the impedance measurement function of the present invention, by measuring the biological impedance of the body part, the state of the body part can be known, and the treatment of the affected area can be effectively performed. You can do it. Therefore, according to the treatment device with the impedance measurement function of the present invention, it can be easily used at home and the like, and it is possible to effectively treat an affected area such as stiff shoulder.

Further, the therapeutic device with the impedance measurement function of the present invention is provided with a search function for searching the affected part to be treated based on the measured impedance (claim 2). By measuring the impedance of the body part, a part having a relatively high impedance compared to the peripheral part thereof, for example, a stiff shoulder or the like having a poor blood circulation state can be searched as an affected part.

With respect to such a therapeutic device with an impedance measuring function, a storage means for storing a first impedance measured before treating the affected part and a second impedance measured after the treatment. And a change amount between the first impedance and the second impedance can be obtained and displayed (claim 3). As a result, since the impedance before and after the treatment in the affected area is measured and displayed, it is possible to know the presence or absence and the degree of the treatment effect.

Further, in such a therapeutic device with an impedance measurement function, the change amount between the first impedance measured before the affected part is treated and the second impedance measured after the treated part is measured. Based on this, the degree of effectiveness of the treatment is obtained and displayed (claim 4). Thereby, the impedance before and after the treatment in the affected area
Since the amount of change in dance is displayed as the degree of treatment effect, it is possible to know the effect of treatment more clearly.

Further, the treatment device with the impedance measurement function of the present invention further comprises a calculation means for obtaining various settings of the treatment means such as intensity and time of the next treatment based on the degree of the treatment effect, And the treatment is controlled so that the next treatment is performed based on the setting of the time and the like (claim 5). As in the present invention, the means for treating the affected area can be controlled based on the setting of the intensity and time of the treatment, and based on the degree of therapeutic effect, the intensity and time of the next treatment More effective treatment is possible by requesting various settings.

Further, with respect to such a therapeutic device with an impedance measurement function, the therapeutic means includes at least a low frequency therapeutic function (claim 6). In this way, as a treatment means, at least a low-frequency treatment function, which is one of the means of electrodynamic treatment, can be provided, thereby promoting blood circulation in the affected area, effectively loosening stiffness, fatigue recovery, and muscle recovery. Relieves fatigue, neuralgia and muscle pain.

[0012]

BEST MODE FOR CARRYING OUT THE INVENTION The present invention will now be described in more detail with reference to the accompanying drawings.

FIG. 1 is a diagram schematically showing the external appearance of a therapeutic device with an impedance measurement function according to a first embodiment of the present invention. 2 is a plan view of the lower surface 3 of the treatment head 1 of FIG. 1, where the temporary surface 3 is applied directly to the affected area for treatment. As shown in FIG. 1, the electrotherapy device of this embodiment includes a treatment head 1 for exploring an affected area and performing low frequency treatment of the affected area. Further, as shown in FIG. 2, on the lower surface 3 of the treatment head 1, electrode groups 2a and 2b for contacting a body part to exert a diseased part search function, a diseased part treatment effect confirmation function, and a low frequency treatment function. Two
c and 2d are provided, the electrodes 2a and 2d are used as electrodes for applying a current when the search for the affected area and the confirmation of the therapeutic effect are performed.
b and 2c act as electrodes for impedance measurement,
Further, at the time of low frequency treatment of the affected area, the electrodes 2a and 2d act as electrodes for low frequency treatment. As described above, the electrodes for impedance measurement have an electrode configuration based on the so-called four-terminal measurement method, and are not affected by contact impedance between the electrodes and the skin of the body, so that the impedance of the body part is not affected. Dance can be measured stably and accurately. The treatment head 1 is connected to the operating portion 6 through the support arm 4 as shown in FIG. 1, and the operating portion 5 is provided with a gripping portion 11 at its lower portion. Operation switch groups 7 to 10 are provided. Here, the switch 7 is a power switch, the switch 8 is a start switch in various operation modes, the switch 9 is a mode change switch, and the switch 10 is a setting data selection switch. Indicates. Inside the operation unit 5, a power supply unit 23 shown in the block diagram of FIG. 3, an impedance measurement circuit unit 22 for exploring the affected part and confirming the effect of treating the affected part, and an electric circuit part 24 of the low frequency treatment device, Further, the electric circuit section 24
And a central processing unit 2 for controlling the operation of this electric circuit
6 etc. are built-in. Although not shown, the impedance measurement electrode and the low-frequency treatment electrode are a power supply unit 23 incorporated in the operation unit 5 via a conductive wire that passes through the inside of the support arm 4. It is connected to the impedance measurement circuit section 22 for searching the affected area and confirming the therapeutic effect, and the electric circuit section 24 of the low frequency treatment device. The power supply unit 2
3. The impedance measurement circuit unit 22 for exploring the affected part and confirming the therapeutic effect and the electric circuit unit 24 of the low frequency treatment device are
Instead of being provided inside the operation portion 5, it may be provided inside the treatment head 1.

FIG. 3 is a block diagram of a therapeutic device with an impedance measurement function according to the first embodiment of the present invention. In this therapy device with an impedance measurement function, the above-mentioned electrode groups 2a to 2d, and a display unit 5 for displaying various operation modes such as diseased part search, affected part treatment effect confirmation and low frequency treatment, and the degree of therapeutic effect. , Power switch 7, star in various modes
Switch group 7, a mode switch 9 and a set data selection switch 10, and an impedance measurement circuit section 22 for searching the affected area and confirming the therapeutic effect, and a low frequency therapeutic device. An electric circuit section 24, a contact switching circuit section 21 for switching connection of the electrodes 2a, 2d to either the impedance measurement circuit section 22 or the electric circuit section 24 of the low frequency treatment device, and a power supply section 23.
And an I / O unit 25, a central processing unit 26, and a storage unit 27. The impedance measurement circuit unit 22
Is connected to the electrode 2 via the contact switching circuit unit 21.
By applying a current to a and 2d and measuring the impedance between the electrodes 2b and 2c, it is possible to measure the biological impedance of the body part of the patient, and
The electric circuit section 24 of the low-frequency treatment device can apply a low-frequency pulse to the electrodes 2a, 2d via the contact switching circuit section 21 to treat the affected area. Further, the power supply unit 23 is connected to the impedance measurement circuit unit 22 and the electric circuit unit 24 of the low frequency treatment device, and supplies a power supply voltage to these circuit units. Further, the display unit 6, the switch groups 7 to 10, the impedance measurement circuit unit 22, the power supply unit 23, and the electric circuit unit 24 of the low-frequency treatment device are each connected via an I / O unit 25. It is connected to a central processing unit 26 and a storage unit 27 that perform all input / output processing and control of all circuit units of the therapeutic device with an impedance measurement function according to the first embodiment of the present invention. The storage unit 27 can store the operation program of the medical treatment device of the present embodiment, each measurement data, each input data, each calculation data and the like.

Next, regarding the operation of the therapeutic device with the impedance measurement function of the present embodiment, the flowchart of FIG. 4, which is the main routine, and each of the subroutines thereof, that is, FIG. 5 to FIG. The flow chart will be described.
First, the flow chart of the main routine of FIG. 4 will be described. In step 1, the power is turned on by turning on the power switch 7 of FIG. The display unit 6 in FIG. 1 is a display showing the initial state. Then, in step 2, by pressing the mode changeover switch 8 of FIG. 1, the display section of FIG. 1 is switched to the display of the setting mode. In this state, in step 3, the operator judges the selection of the setting mode, and the setting mode is selected.
In order to select various modes and make various settings for this treatment device, in step 4, the start switch 9 shown in FIG. 1 is pressed and the setting mode subroutine in step 5 is selected.
Enter Chin When the subroutine of the setting mode is completed, the process returns to step 2 of the main routine.
Further, in step 3, if the operator judges the selection of the setting mode and does not select the setting mode, the process proceeds to the next step 6. Then, in step 6, by pressing the mode changeover switch 8 of FIG. 1, the display section of FIG. 1 is switched to the display of the diseased part search mode. In this state,
In step 7, the operator judges the selection of the setting mode, selects the affected part search mode, and measures the impedance of the body part to measure the affected part prior to the treatment by the present treatment device. 1 is pressed, the start switch 9 of FIG. 1 is pushed to enter the subroutine of the diseased part search mode of step 9. Further, when the subroutine of the affected area search mode is completed, the process returns to step 10 of the main routine. In step 7, if the operator judges the selection of the diseased part search mode and does not select the diseased part search mode, the process proceeds to the next step 10. Then, in step 10, by pressing the mode changeover switch 8 of FIG. 1, the display section of FIG. 1 is switched to the display of the affected area treatment mode. In this state, in step 11, the operator judges the selection of the treatment mode for the affected area, selects the treatment mode for the affected area, and selects the affected area searched in the affected area search mode in step 9 above. 1 to be treated, the start switch 9 shown in FIG. 1 is pushed in step 12 to enter the subroutine of the affected area treatment mode in step 13. Further, when the subroutine of the affected area treatment mode is completed, the process returns to step 14 of the main routine. In step 11, if the operator judges whether or not to select the affected part treatment mode and does not select the affected part treatment mode, the process proceeds to the next step 14. Then, in step 14, the mode switching switch 8 of FIG. 1 is pressed to switch the display of FIG. 1 to the display of the affected part treatment mode. In this state, in step 15, the operator judges the selection of the therapeutic effect confirmation mode, selects the therapeutic effect confirmation mode, and selects the affected area treated in the affected area treatment mode of step 13 above. On the other hand, when it is desired to confirm the therapeutic effect, in step 16, the start switch 9 of FIG. 1 is pressed to enter the subroutine of the therapeutic effect confirmation mode in step 17. Further, when the subroutine of the therapeutic effect confirmation mode is completed, the process returns to step 2 of the main routine. Further, in step 15, the operator makes a judgment of selecting a treatment effect confirmation mode,
Even if you do not select the treatment effect confirmation mode,
Return to Chin Step 2.

Next, the routine relating to the setting mode will be explained based on the flow chart of FIG. Step 1
At this time, by turning on the setting data selection switch 10, the setting data of the low frequency treatment pulse number is switched and displayed on the display section 6 in three steps such as 5 Hz, 10 Hz and 20 Hz. It has become so. And
In step 2, in the state in which the data to be selected by the operator is displayed, the setting data selection switch 10 is turned on, for example, twice in succession, so that the low frequency treatment pulse number The display data is selected and stored in the storage unit 27. Further, in step 3, the setting data selection switch 10 is turned on, so that the setting data of the low frequency treatment output intensity is displayed on the display unit 6 by, for example, 50.
V, 100V, and 150V are switched and displayed in three stages. Then, in step 4, in the state in which the data to be selected by the operator is displayed, the setting data selection switch 10 is turned on, for example, twice in succession to thereby output the low frequency treatment output. Display data relating to intensity is selected and stored in the storage unit 27. Further, in step 5, by turning on the setting data selection switch 10, the setting data of the low frequency treatment time is displayed on the display unit 6, for example, 5 minutes, 10 minutes and 15 minutes.
It is designed to be switched and displayed in three steps like a minute. Then, in step 6, in the state where the data to be selected by the operator is displayed, the setting data selection switch 10 is turned on, for example, twice in succession, so that the low frequency treatment time is increased. The display data related to is selected and stored in the storage unit 27. In this way,
In Chin, the treatment device according to the present embodiment is set.

Next, the routine relating to the affected part search mode will be explained based on the flowchart of FIG. First,
In step 1, the contact switching circuit 21 is impeded.
Switch to the dance measurement mode. Next, in step 2, the impedance of the body part to which the electrode groups 2a to 2d arranged on the lower surface 3 of the treatment head 1 of FIG. Further, in step 3, the measured impedance and the maximum stored impedance Zmax are compared in the central processing unit 26, and if the measured impedance is small, step Proceed to and change the exploration position. Further, when the measured impedance is large,
In step 4, this measured value is updated as Zmax and displayed on the display unit 6 in FIG. In addition, at the time of the first measurement, Zmax is set to zero as an initial value. Next, in step 5, the operator determines whether or not the updated measurement value Zmax is an affected area,
If it is determined that the affected area, the exploration is completed, otherwise,
Proceed to step 6. And in step 6 above,
After changing the search position, the process returns to step 2 to measure the impedance of the new body part. In this way, in this routine, while changing the position of the body part, the impedance is measured each time, and the exploration is finished at the position finally recognized as the affected part. Then, the treatment described later is performed. Further, in this routine, the operator determines whether the updated measured value Zmax is the affected area, but the central processing unit 26 automatically determines the reference value stored in advance in the storage unit 26. You may make it compare with a value.

Next, the routine relating to the affected part treatment mode will be explained based on the flowchart of FIG. First,
In step 1, the contact switching circuit 21 is switched to the low frequency treatment mode. Next, in step 2, for the affected area searched by the routine of the affected area search mode described above,
Start low frequency treatment. Further, at this time, the low frequency treatment circuit section 24 of FIG. 3 which outputs the low frequency pulse is controlled based on the low frequency treatment pulse number and the low frequency treatment output intensity set by the above-mentioned setting module. To do. Next, in step 3, the treatment is performed until the low frequency treatment time timer similarly set in the setting model is turned off, and in step 4, the treatment of the affected area is completed. Further, in this routine, the operator can confirm the status of the treatment and the completion of the treatment by displaying it on the display unit 6.

Next, the routine relating to the mode for confirming the therapeutic effect will be explained based on the flowchart of FIG. First, in step 1, the contact switching circuit 21 is switched again to the impedance measurement mode. Next, in step 2, the impedance is measured for the affected area treated with the routine in the affected area treatment mode described above. Subsequently, in step 3, the measured post-treatment impedance is stored as Z2, and in step 4, the pre-treatment impedance measurement value Zmax is read out from the storage unit 27, and then, In Step 5 of (Z
max-Z2) × 100 / Zmax is calculated.
Further, the calculation result is stored in the storage unit 27 as the therapeutic effect level and displayed on the display unit 6. The calculation is performed in the central processing unit 26. As described above, in the present routine, the impedance of the affected area after low-frequency treatment is measured, and the reduction rate with respect to the impedance before treatment is calculated and displayed. You can check.

Next, the impedance of another embodiment of the present invention will be described.
Optimal control of the operation of the therapy device with dance measurement function Flow chart of the main routine of low frequency therapy mode
The chart will be described with reference to FIG. In step 1, the affected area search module is the same as the flowchart of FIG. 6 described in the first embodiment of the present invention, and therefore its details are omitted. . Then, in step 2, the affected area treatment modul routine is executed. In this routine, first, the contact switching circuit 21 shown in FIG. 3 is switched to the low frequency treatment mode. Then, the low-frequency treatment is applied to the affected part based on the control data of the low-frequency treatment circuit stored in the production storage unit 27 as an initial value in advance. Next, in step 3, as the impedance measurement mode for the affected area after the treatment, first, the contact switching circuit 21 is switched to the impedance measurement mode, and then the impedance of the affected area. The dance is measured, and this is stored in the storage unit 27 of FIG. 3 as the post-treatment impedance Z2. Further, in step 4, the degree of therapeutic effect is calculated. That is, the impedance Zmax before the treatment and the impedance Z after the treatment this time measured by the affected area exploration model.
2 based on (Zmax−Z2) × 100 / Zmax
Is calculated and stored in the storage unit 27 as the degree of therapeutic effect.

Then, in step 5, step 4
In the central processing unit 26, it is judged whether or not the therapeutic effect degree calculated in the above exceeds the reference value stored in advance in the storage unit 27, and the therapeutic effect degree exceeds the reference value. If this routine is completed and does not exceed the reference value, proceed to the next step 6. And step 6
In the same way, in the central processing unit 26, the control data of the low-frequency treatment circuit, that is, the number of low-frequency treatment pulses, is calculated based on the degree of treatment effect obtained by the calculation in step 4. Setting data, low frequency treatment output intensity setting data
Optimal data for the setting data of the data and the treatment time are selected and set. In this case, as shown in each control data table of the low frequency treatment circuit of FIG. 10, the pulse number data of the low frequency treatment output is three types of 5 Hz, 10 Hz and 20 Hz,
There are three types of output intensity data of 50V, 100V and 150V and three types of treatment time of 2 minutes, 3 minutes and 5 minutes, and a total of 9 pieces of data are stored in the storage unit 27 in advance. Remembered in Bull. Therefore, one optimal combination is selected from the 27 combinations of the number of pulses, the output intensity, and the treatment time based on the above-mentioned degree of treatment effect. Then, the affected part treatment mode of step 2 is performed.
Treatment is given again with Dol-Chin. As shown in FIG.
In the routine, the treatment is repeatedly performed until the degree of therapeutic effect reaches a preset reference value. Also,
At the time of the first treatment, each control data of the low frequency treatment circuit is
It is set to the initial data stored in advance, and after the second time, the optimum control data is set based on the degree of effectiveness of the previous treatment. By doing so, it is possible to efficiently and automatically perform appropriate treatment without burdening the operator with setting and determination work.

In the above embodiment, the items of control data for the low-frequency treatment device are the low-frequency pulse number, the low-frequency output intensity, and the treatment time, but the phase of the low-frequency pulse is controlled. It can also be data. By doing so, more diverse control is possible. Further, in the above-mentioned embodiment, the treatment means is provided with a low-frequency pulse function, but vibrations such as electric heaters that overheat the affected area or vibrations that can obtain the effect of massaging and the like. A device may be provided, and a plurality of functions may be combined to perform treatment. in this way,
By providing a plurality of treatment means, it is possible to carry out effective treatment more suited to the symptoms of the affected area.

[0023]

As described above, according to the present invention, by measuring the impedance of the body part, the affected area can be directly searched and the treatment can be performed while confirming the therapeutic effect of the affected area. . Therefore, even at home, etc., it can be used easily and effective treatment can be performed.

[Brief description of drawings]

FIG. 1 is an appearance of a therapeutic device with an impedance measurement function of the present invention.

FIG. 2 is a plan view of an electrode group of a therapeutic device with an impedance measurement function of the present invention.

FIG. 3 is a block diagram showing the configuration of a therapeutic device with an impedance measurement function of the present invention.

FIG. 4 is a flowchart of the main routine of the therapeutic device with the impedance measurement function of the present invention.

FIG. 5 is a flowchart of a setting mode routine of the therapeutic device with the impedance measurement function of the present invention.

FIG. 6 is a flow chart of a diseased part exploration model of the therapeutic device with an impedance measurement function of the present invention.

FIG. 7 is a flowchart of a diseased part treatment mode of the treatment device with the impedance measurement function of the present invention.

FIG. 8 is a flow chart of a therapeutic effect confirmation mode routine of the therapeutic device with the impedance measurement function of the present invention.

FIG. 9 is a flow chart of an automatic control treatment mode routine of the treatment device with the impedance measurement function of the present invention.

FIG. 10 is a control data table of the low frequency treatment circuit of the treatment device with the impedance measurement function of the present invention.

[Explanation of supplements]

1 treatment head 2a to 2d electrode group 3 Treatment head bottom surface 4 Support arm 5 Operation part 6 Display 7 power switch 8 Start switch 9 mode selector switch 10 Setting data selection switch 11 grip 21 contact switching circuit 22 Impedance measurement circuit 23 Power Supply 24 Low frequency therapy circuit 25 I / O 26 Central Processing Department 27 Memory

Claims (6)

[Claims] 1. A bioimpedance measuring means for measuring a bioimpedance of a body part by applying an electric current to the body of the patient, and a treatment means for treating an affected part of the patient, wherein the measurement is performed. A therapeutic device with an impedance measurement function, characterized in that an affected part is treated based on impedance. 2. The therapeutic device with an impedance measurement function according to claim 1, further comprising a search function for searching a diseased part to be treated based on the measured impedance. 3. A storage means for respectively storing a first impedance measured before treating the affected area and a second impedance measured after treating the affected area, and the first impedance and the second impedance. 3. The therapeutic device with an impedance measurement function according to claim 1 or 2, wherein the amount of change during the impedance is calculated and displayed. 4. A first impedance measured before treating the affected area and a second impedance measured after treating the affected area.
The therapeutic device with an impedance measurement function according to claim 3, wherein the degree of effectiveness of the treatment is obtained and displayed based on the amount of change between dances. 5. The apparatus further comprises calculation means for determining the setting of the treatment device such as intensity and time of the next treatment based on the degree of the treatment effect, and the next treatment is performed based on the setting of the intensity and time. The treatment device with an impedance measurement function according to claim 4, wherein the treatment means is controlled. 6. The therapeutic device with an impedance measurement function according to claim 1, wherein the therapeutic means includes at least a low frequency therapeutic function.