JP2020018882A - Current stimulation device for recovering physical exercise functional disorder - Google Patents

Abstract

To provide a current stimulation device that increases or decreases muscle output in real time and weakens and relaxes excessive muscle contraction using current stimulation.SOLUTION: A current stimulation device applies percutaneous current stimulation using an electrode 14 to supply an electric signal that is to be used for improving muscle strength and is weak so that a muscle is not caused to contract, the electric signal being constituted by an electric signal having current amplitude increasing to a predetermined set value within a predetermined time, an electric signal having current amplitude equal to or lower than 1000 μA, and an electric signal having current amplitude decreasing from a predetermined set value within a predetermined time, each predetermined time being larger than 1 second.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a current stimulating device that generates a weak current that cannot be sensed by humans, and more specifically, a current stimulating device that improves or reduces muscle output by stimulating the transcutaneous current and recovers motor dysfunction of the body. About.

  An EMS that improves muscle output by causing muscle contraction has been known as a device for restoring a body function by current stimulation.

  The EMS is an electrical muscle simulation, which is a device that stimulates motor nerves electrically from the outside to contract muscles connected to the nerves intermittently to perform efficient muscle training. This device restores the physical motor dysfunction by applying a heavy load to the muscle tissue and repairing the muscle fibers after the muscle fibers are broken, thereby increasing the muscle output and improving the muscle output. Therefore, EMS provides a strong current stimulus that causes muscle contraction. However, if a sudden current stimulus is given to the muscle suddenly, the stimulus is too strong. Therefore, various techniques have been devised for "applying a current" to gradually increase the current to a set current. (For example, cited document 1)

JP 2009-225810 A

The EMS causes the muscle to be intermittently contracted by a strong current stimulus, thereby performing efficient muscle training, and causing the muscle to enlarge. As a result, the muscle output is improved, and the muscle output cannot be improved until the muscle is enlarged.
That is, there is a problem that the muscle output cannot be immediately improved.

  On the other hand, there are various states of motor dysfunction, and there is also a disorder that causes motor dysfunction due to excessive contraction of muscle.

  For such motor dysfunction, it is necessary to relax excessive muscle contraction to relax, but it was not possible to recover such motor dysfunction with a conventional current stimulator.

  Means for alleviating such excessive muscle contraction include, for example, Botox injection for patients with cerebral palsy. In this treatment, Clostridium botulinum is injected into muscles that are contracting muscles to relax the muscle contraction. However, the effects are not permanent and require repeated injections on a regular basis. In addition, when administered periodically, there is a problem that immunity to the bacterium is attached and the effect is weakened, and there is a problem that there is a risk of causing respiratory disorders and dysphagia. In addition, there is a problem that medical treatment is required only at a medical institution.

  In order to solve the above problems, a current stimulating device according to the present invention is a current stimulating device that provides a percutaneous current stimulus by supplying an electric signal using a conductor, wherein the electric signal is: An electrical signal that is used to improve muscle strength and is a weak electrical signal that does not cause muscle contraction, and that the amplitude of the current of the electrical signal increases to a predetermined set value within a predetermined time, An electric signal having an amplitude of 1000 μA or less, and an electric signal in which the amplitude of the current of the electric signal becomes smaller than a predetermined set value within a predetermined time, wherein each of the predetermined times is an electric signal longer than 1 second. There is a feature.

  Muscle output can be immediately improved by the electric signal, so that motor dysfunction can be immediately alleviated.

  As another means for solving the above problem, in the above-described configuration, the electric signal includes an electric signal in which the amplitude of the current of the electric signal increases to a predetermined set value within a predetermined time, and an electric signal having an amplitude of 1000 μA or less. A signal and an electric signal whose current amplitude of the electric signal becomes smaller than a predetermined set value within a predetermined time, wherein each of the predetermined times is an electric signal smaller than 1 second. .

  Muscle output can be immediately reduced by the electric signal, so that motor dysfunction can be immediately alleviated. In addition, excessive muscle contraction can be easily weakened and relaxed without suffering from a medical institution.

  As another means for solving the above-mentioned problems, in the above-mentioned configuration, the current stimulator supplies the first electric signal in the first mode or the second electric signal in the second mode as the electric signal. It is possible that the first electric signal is an electric signal used to improve muscle strength and is a weak electric signal that does not cause muscle contraction, and the electric signal of the electric signal within a first time period. Of an electric signal whose amplitude increases to a predetermined set value, an electric signal whose amplitude is 1000 μA or less, and an electric signal whose current amplitude of the electric signal decreases from the predetermined set value within a second time. Wherein the second electric signal is an electric signal used to reduce muscle strength and is a weak electric signal that does not cause muscle contraction, and the electric signal of the electric signal within a third time period. amplitude An electric signal that increases to a predetermined set value, an electric signal having an amplitude of 1000 μA or less, and an electric signal whose current amplitude of the electric signal decreases from the predetermined set value within a fourth time period. I do.

  By applying percutaneous current stimulation using at least one of the first mode and the second mode, the muscle output can be immediately increased or decreased, so that the motor dysfunction is immediately reduced. Can be relaxed. In addition, excessive muscle contraction can be easily weakened and relaxed without suffering from a medical institution.

  Still preferably, in the above configuration, a mode setting means for arbitrarily selecting one of the first output mode and the second output mode is provided, and the first electric signal or the second 2 is output.

  By applying a transcutaneous current stimulation in accordance with a mode setting for arbitrarily selecting one of the first output mode and the second output mode, the efficiency of motor dysfunction and relaxation of muscle contraction is improved.

  Further, preferably, the first time and the second time are not less than 1.1 seconds and not more than 4 seconds.

  By setting the first time and the second time, a great effect is obtained on muscle output prompting.

  Further, preferably, the third time and the fourth time are not less than 0.1 second and not more than 0.9 second.

  By setting the third time and the fourth time, a great effect on muscle output suppression can be obtained.

  According to another aspect of the present invention, there is provided a current stimulator for providing a percutaneous current stimulus by supplying an electric signal using a conductor, the current stimulator comprising: Is an electric signal used to improve muscle strength and is a weak electric signal that does not cause muscle contraction, and an electric signal in which the output of the electric signal increases to a predetermined set value within a predetermined time, An electric signal of 1000 μA or less, and an electric signal whose electric signal output becomes smaller than a predetermined set value within a predetermined time, wherein each of the predetermined times is an electric signal longer than 1 second. And

  Muscle output can be immediately improved by the electric signal output, so that motor dysfunction can be immediately alleviated.

  As another means for solving the above-mentioned problems, in the above-described configuration, the electric signal is an electric signal used to reduce muscle strength and is a weak current that does not cause muscle contraction, and It is composed of an electric signal whose electric signal output increases to a predetermined set value within a time, an electric signal of 1000 μA or less, and an electric signal whose electric signal output decreases from a predetermined set value within a predetermined time. Each of the predetermined times is an electric signal smaller than 1 second.

  Muscle output can be immediately reduced by the electric signal, so that motor dysfunction can be immediately alleviated. In addition, excessive muscle contraction can be easily weakened and relaxed without suffering from a medical institution.

  As another means for solving the above-mentioned problems, in the above configuration, the current stimulating device can supply a first electric signal or a second electric signal as the electric signal, and the first electric signal is An electric signal used to improve muscle strength, a weak electric signal that does not cause muscle contraction, and an electric signal whose electric signal output increases to a predetermined set value within a predetermined time; The following electric signal and an electric signal whose electric signal output becomes smaller than a predetermined set value within a predetermined time, and the second electric signal is an electric signal used for lowering muscle strength. A weak electrical signal that does not cause muscle contraction while being a signal, an electrical signal in which the output of the electrical signal increases to a predetermined set value within a predetermined time, and an electrical signal of 1000 μA or less, It is characterized in that the output of the electric signal becomes smaller than a predetermined set value within a predetermined time.

  By providing transcutaneous current stimulation using at least one of the first electric signal and the second electric signal, the muscle output can be immediately increased or decreased, so that motor dysfunction is impaired. Can be alleviated immediately. In addition, excessive muscle contraction can be easily weakened and relaxed without suffering from a medical institution.

The present invention can immediately increase or decrease the muscle output by applying a weak current stimulus that does not cause muscle contraction from the percutaneous surface of the muscle whose function is to be restored.
In particular, for a motor dysfunction caused by too strong muscle contraction, the motor dysfunction can be recovered by reducing the muscle output.

FIG. 2 is a front view of the current stimulation device 100 according to the present invention. It is a block diagram of a current stimulating device according to the present invention. 5 is a waveform showing a first output mode according to the present invention. 9 is a waveform showing a second output mode according to the present invention.

Usually, in order for a muscle to contract, a command (electric signal) is issued from the brain to a muscle to be moved through a nerve, and the muscle contracts in response to the command.
At that time, the force (muscle strength) that the muscle can exert is basically proportional to the cross-sectional area of the muscle. However, the muscle power actually output is not determined simply by the cross-sectional area of the muscle alone, and the percentage of the total muscle mass that is used up is a major factor in exerting the muscle strength.
In other words, the greater the amount of instruction when the brain transmits an instruction to a muscle through a nerve, the more the muscle can contract more muscle fibers and exert a greater force (muscle strength).

And, in general, even if you intend to exert maximum muscle strength (maximum effort), the maximum command is not actually transmitted to the muscles, but only a few percent of the total muscles have instructions. Often things.
There is an individual difference in the ratio, which causes a difference in muscle strength even with the same amount of muscle. Further, it is generally considered that the instruction reaches only about 60% to 70% of the muscles even with the largest instruction. This is because tendon, bones, joints, and even the muscles themselves are too burdened when the muscles exert 100% of their muscle strength, so that a 100% command is controlled as a kind of defense measure.

In the present invention, it is considered that the muscle output is improved by increasing the instruction amount of about 60% to 70% transmitted to the muscle, and the muscle output is reduced by decreasing the instruction amount.

In the present invention, increasing the instruction amount of about 60% to 70% transmitted to this line is defined as prompting, and decreasing the instruction amount is defined as suppression.
That is, the muscle output is improved by selecting "prompting", and the muscle output is reduced by selecting "suppression".

The present invention can output one or both of a first output mode for improving muscle output and a second output mode for decreasing muscle output, and has a motor dysfunction in the body. Recovery of the function of the patient can be achieved.
For example, a patient who has a pain in a joint or the like and suffers from a pain has a motor dysfunction in which muscles to be used are not used well. They also use specific muscles around them to supplement this poorly used muscle.
These poorly used muscles have weak muscles, so they increase muscle output and restore muscle function, and conversely, certain muscles around them have too strong muscle output, so they decrease muscle output. To recover from motor dysfunction.
An apparatus for recovering from motor dysfunction due to such abnormal muscle contraction and a method using the apparatus are provided.

Here, features of the present invention will be described.
A feature of the present invention is that muscle output can be immediately increased and decreased.
In order to obtain this effect, the time required for the ramp-up time and the ramp-down time is important.

Ramp-up time is also called rise time control.It does not apply the set current immediately after the start, but gradually increases the current to the set current. Time to reduce current. It is provided to alleviate muscle irritation.
The inventor of the present invention has proposed that the ramp-up time and the ramp-down time should be greater than 1 second in order to improve the muscle output, and the ramp-up time and the ramp-down time should be less than 1 second in order to reduce the muscle output. Was found to be a condition.

The ramp-up time and the sleep-down time are controlled by the CPU 19 and output from the conductor 14 via the output circuit 20, as shown in FIG.

As shown in FIG. 3A, the first output mode is an output mode in which the ramp-up time and the ramp-down time are longer than 1 second, and is a mode for improving muscle output. (Hereinafter, this is referred to as a facilitation mode.) That is, this is a mode for recovering the reduced muscle output.
For example, bedridden patients at the point of care, heart disease, respiratory disease, to restore muscle output decreased by disuse muscle atrophy such as diabetic patients, prevention of disuse muscle atrophy after surgery for orthopedic diseases, Can be used for rehabilitation.

In particular, since many rehabilitation patients are elderly and often suffer from severe electric shock, it is useful to recover motor dysfunction with a weak current (not perceived) that does not cause muscle contraction It is.

In addition, pediatric rehabilitation is also effective because it does not cause fear of electrical stimulation.

It is also useful in orthopedic surgery and osteotomy for treating and improving the range of motion of diseases mainly due to muscle weakness and muscle balance due to shoulder and knee joint pain.

The second output mode is an output mode in which the ramp-up time and the ramp-down time are smaller than 1 second as shown in FIG. In other words, the mode is a mode in which the contraction of the muscle in a state where the muscle is contracted more than necessary is relaxed and suppressed. (Hereinafter referred to as the suppression mode.) For example, the present invention is effective for patients with excessive muscle tone in the affected area such as low back pain and stiff shoulders.

[Example 1]
Hereinafter, the present invention will be described with reference to the drawings.
In the present embodiment, by applying a weak current (microcurrent) that does not cause muscle contraction and applying a percutaneous stimulation, the muscle output of the muscle associated with the nerve is improved or reduced, and the reduced physical function As shown in FIG. 1, a current stimulating device 100 for recovering a fault includes a main body 10 for generating a weak current and a conductor 14 for applying the current.

Various SWs (operation switches) are provided on the front of the current stimulation device 100. Reference numeral 11 denotes a power switch. Reference numeral 12 denotes a start / stop SW. In addition, an output port for connecting the conductor 14 is provided on the lower surface of the device 100.

The output modes include a first output mode for improving muscle output and a second output mode for decreasing muscle output. This output mode may be a mode fixed for each device, or a mode selection switch may be separately provided to allow the user to select one of the modes.

FIG. 2 is a block diagram illustrating a main configuration of the current stimulation device 100.
In FIG. 2, a power supply voltage Vcc output from a power supply unit 15 is controlled to a required voltage by a control voltage circuit 17 and supplied to a CPU 19, a memory 21, a booster circuit 16, and other necessary circuits. Further, it is also supplied to an output circuit 20 controlled by the CPU 19.

First, the weak current generator will be described.
The weak current generator includes an output circuit 20, a voltage Vcc supplied from the booster circuit 16, and the CPU 19.
The output circuit 20 receives the voltage Vcc supplied from the booster circuit 16 and a signal from the CPU 19 and generates a weak current. The weak current refers to a current at a level that does not cause muscle contraction, and specifically refers to a current of 20 mA or less. The numerical value of 20 mA is described in FIG. 8-20 on page 242 of EBM Physical Therapy Original Edition, 2nd Ed. As can be seen from this figure, an output of 20 mA or more is required to cause muscle contraction.
This embodiment is characterized in that no muscle contraction occurs because a current (microcurrent) having an output of less than 1000 μA is used.

Next, the control unit will be described.
The control unit includes a CPU 19, a control voltage circuit 17, a power supply voltage monitoring circuit 18, and a memory 21. The CPU 19 is connected to a memory 21 composed of an EEPROM, the above-described switches, and a source oscillator for generating a clock. Further, the CPU 19 monitors the power supply voltage Vcc by the power supply voltage monitoring circuit 18. The CPU 19 also performs time control on a ramp-up time, a hold time, a ramp-down time, and an off-time.
The memory 21 such as a control program ROM and a work RAM is configured as a single chip with the CPU 19.
The control voltage circuit 17 converts the power supplied from the power supply unit 15 into a voltage necessary for controlling the CPU 19 and the like, and supplies the voltage.

Next, the output unit will be described.
The output unit includes an output circuit 20 and a polarity switching circuit 22.
The polarity of the weak current and voltage generated by the output circuit 20 is switched by the polarity switching circuit 22 to be a pulse signal, which is output from the output terminal to the conductor 14.

The operation unit includes SWs (switches) 11 and SW12. The operation is started by turning on the power (SW11) and pressing the start / stop SW12.

Next, the operation will be described.
After attaching the lead 14 to the affected part, the power is turned on by the power supply SW11 to start the apparatus body. Press START / STOP SW12 to start treatment.
When the treatment is completed, the user presses the start / stop SW 12 again to end the procedure.
It should be noted that a mode selection SW may be provided so that a mode can be selected for each output unit.

First, the first output mode will be described.
The first output mode is a mode for improving muscle output, and is an output mode in which the ramp-up time and the ramp-down time are longer than 1 second.
In other words, the control is such that the current is gradually increased to the set current over a time longer than 1 second, the voltage is output at the set current for several seconds, and then the voltage is gradually reduced over a time longer than 1 second.
Such control is performed by the CPU 19 and the output circuit 20.

The second output mode is a mode in which muscle output is suppressed, and is an output mode in which the ramp-up time and the ramp-down time are smaller than 1 second.
That is, the control is such that the current is increased to the set current in less than one second, the current is output for several seconds, and then the current is decreased in less than one second. Such control is performed by the CPU 19 and the output circuit 20.

When the ramp-up time and the ramp-down time are set to 1 second, neither prompting nor suppression of muscle output occurs.

However, when the ramp-up time and the ramp-down time are set to be longer than 1 second, the effect of improving muscle output is recognized. Preferably, the prompting effect is in the range of 1.1 to 4.0 seconds, and the prompting effect is particularly in the range of 1.1 to 3.0 seconds.

On the other hand, when the ramp-up time and the ramp-down time are set smaller than 1 second, the effect of suppressing muscle output is recognized. Preferably, the effect of suppression is in the range of 0.1 to 0.9 seconds.
An experiment for deriving such a numerical range will be described later in detail as Test Example 2.

The conductor 14 may be a known conductor 14. The guide 14 may be placed anywhere on the muscle whose function is to be restored.

Hereinafter, test examples will be described.
[Test Example 1]
This test is a test for proving that the current stimulator 100 was able to increase or decrease muscle output. In addition, since the muscle output is changed immediately, the test proves that the improvement in muscle output is not due to muscle hypertrophy.

Using males of each age in their 20s to 40s as subjects, a conductor 14 connected to the current stimulator 100 is attached to the middle gluteal muscle of the right leg, and a muscle output facilitation mode as a first output mode and a second output mode The restraint mode, which is the output mode, was performed, and the force of right leg abduction before and after the treatment was measured.

A muscular strength meter μTas F-1 manufactured by Anima Co., Ltd. was used for the measurement. This was placed on the right ankle of the outer leg.
In addition, the left foot was tightly attached to the wall to prevent trick motion (exercise by a substitute muscle) from occurring.

As group A, the force of each subject before the treatment was measured, and then the facilitation mode was performed and measured, then the suppression mode was performed and measured, and then the facilitation mode was performed and measured again.
The interval until the next treatment was 20 minutes.

As group B, the force of each subject before the treatment was measured, and then the suppression mode was applied and measured, then the prompting mode was applied and measured, and then the inhibition mode was applied again and measured.
The interval until the next treatment was 20 minutes.

The parameters of the prompting mode are as follows.
Frequency 50 Hz, pulse width 200 μs, output 450 μA, output time 5 minutes, ramp up time 1.5 seconds, hold 2.0 seconds, ramp down time 1.5 seconds, off time 3.0 seconds

The parameters of the suppression mode are as follows.
Frequency 50 Hz, pulse width 200 μs, output 450 μA, output time 5 minutes, ramp up time 0.5 seconds, hold 4.0 seconds, ramp down time 0.5 seconds, off time 3.0 seconds

The results for Group A are presented in Table 1 below. The unit N is Newton.

The results for Group B are presented in Table 2 below. The unit N is Newton.

As can be seen from the results, it has been proved that in both the groups A and B, the facilitation leads to an increase in muscle output, and the suppression leads to a decrease in muscle output.
In addition, it was proved that the muscle output could be immediately increased (promoted) and decreased (suppressed).

From the test results described above, the use of the current stimulating device 100 can immediately increase and decrease the muscle output.
In addition, since the effect appeared immediately after the treatment, it was proved that the muscle was not enlarged by the muscle contraction, and as a result, the muscle output was not enhanced.
On the other hand, when a stimulus is given in the suppression mode, a decrease in muscle output is observed. Such an effect cannot be achieved by the conventional EMS. In addition, the effect of improving and decreasing muscle output also showed sustainability.

[Test Example 2]
Next, the range of the ramp-up time and the ramp-down time was tested.

In the test, the number of seconds for the ramp-up time and the ramp-down time was changed, and the other conditions were the same as in Test Example 1. Each time after the test for each second, the suppression was performed and it was confirmed that the muscle output had returned to that before the operation, and then the next second test was performed.

The ramp-up time and the ramp-down time for the prompting mode were set as shown in Table 3 below. The unit is (N: Newton).

As a result, an improvement in muscle output was observed in the range of 1.1 seconds to 3.5 seconds. Among them, the output was improved most in 3.0 seconds. In addition, although it was higher than before the treatment, a slight decrease was observed at 4.0 seconds.

Similarly, in the suppression mode, the ramp-up time and the ramp-down time are set as shown in Table 4 below. Each time after the test for each second, after confirming that the muscle output had returned to that before the operation, the test for the next second was performed.
The unit is (N: Newton).

As a result, a decrease in muscle output was observed in the range of 0.9 to 0.1. Above all, the output decreased for 0.5 seconds.

According to the above test, the muscle output can be improved by setting the ramp-up time and the ramp-down time from 1.1 seconds to 4.0 seconds, preferably from 1.1 seconds to 3.0 seconds.
On the other hand, by setting the ramp-up time and the ramp-down time from 0.9 seconds to 0.1 seconds, the muscle output can be reduced.

From the above test results, it was demonstrated that the muscle output was improved and decreased by the set time of the ramp-up time and the ramp-down time.
To increase muscle output, the ramp-up time and ramp-down time must be greater than 1 second; conversely, to decrease muscle output, the ramp-up and ramp-down times must be less than 1 second. Become.
In addition, since the effect appeared immediately after the treatment, it was proved that the muscle was enlarged by the muscle contraction, and as a result, the muscle output was not enhanced.
In addition, there is an immediate decrease in muscle output. Such results are not possible with conventional EMS. In addition, the effect of improving and decreasing muscle output also showed sustainability.

When the current value was set in the range of 1 μA to 999 μA and a similar test was performed, similar results were obtained.

In addition, the apparatus main body may be provided with a display unit for displaying the current treatment mode, parameters, elapsed time, and the like. In addition, although the number of output channels to the conductor 14 is illustrated as one, the number is not limited to this, and a plurality of channels may be used. The number of channels does not matter.
The output of the prompting mode and the suppression mode may be arbitrarily changed by the user. For example, a five-stage output level adjustment switch may be provided to provide a user's favorite output.

It should be noted that the parameters described above are merely examples, and the present invention is not limited to these parameters but covers an equivalent range.

In addition to the above, the current stimulating device according to the present invention can be configured as follows. Another current stimulating device according to the present invention, a weak current generator that generates a weak current stimulus that does not cause muscle contraction to the affected area, a controller that controls the current generated by the weak current generator, An output unit that outputs the current controlled by the control unit, and a conductor that applies the current output by the output unit to the skin surface of the affected part, wherein the control unit improves or suppresses the output of the muscle. Controlling a ramp-up time for gradually increasing the current to a set current and a ramp-down time for gradually decreasing the current from the set current, wherein the output unit controls the ramp-up time and the ramp controlled by the control unit. A first output mode in which the downtime is increased by more than 1 second to improve the muscle output; and the muscle output is reduced by making the ramp-up time and the ramp-down time less than 1 second. And outputting at least one mode of the second output mode in which made. As described above, by performing an operation on the affected part using at least one of the first output mode and the second output mode, the muscle output can be immediately increased or decreased, so that the motor dysfunction can be immediately reduced. Can be eased. In addition, excessive muscle contraction can be easily weakened and relaxed without suffering from a medical institution.

Another current stimulating device according to the present invention is a current stimulating device that supplies an electric signal to an affected part using a conductor arranged at the affected part of a patient, wherein the electric signal is used to improve muscle strength. An electrical signal that is a weak electrical signal that does not cause muscle contraction and that has a current amplitude that gradually increases during the ramp-up time; an electrical signal that is less than 20 mA; The ramp-up time and the ramp-down time are each an electric signal that is longer than 1 second. Further, the current stimulating device according to the present invention is a current stimulating device for supplying an electric signal to an affected part using a conductor arranged at the affected part, wherein the electric signal is an electric stimulus used for reducing muscle strength. An electrical signal that is a signal and is a weak current that does not cause muscle contraction, and the amplitude of the current gradually increases during the ramp-up time; an electrical signal of 20 mA or less; , Wherein the ramp-up time and the ramp-down time are each a current smaller than 1 second.

10 Main body 11 Power switch SW11
12 Start / Stop SW12
14 Conductor 15 Power supply unit 16 Boost circuit 17 Control voltage circuit 18 Power supply voltage monitoring circuit 19 CPU
Reference Signs List 20 output circuit 21 memory 22 polarity switching circuit 100 current stimulator

Claims (9)

A current stimulator for providing a transcutaneous current stimulus by supplying an electrical signal using a conductor,
The electrical signal is
It is an electrical signal used to improve muscle strength and a weak electrical signal that does not cause muscle contraction,
An electric signal whose current amplitude of the electric signal increases to a predetermined set value within a predetermined time, an electric signal having an amplitude of 1000 μA or less,
It is composed of an electric signal whose current amplitude of the electric signal becomes smaller than a predetermined set value within a predetermined time,
The current stimulating device, wherein each of the predetermined times is an electric signal longer than 1 second. A current stimulator for providing a transcutaneous current stimulus by supplying an electrical signal using a conductor,
The electrical signal is
It is an electrical signal used to reduce muscle strength and a weak electrical signal that does not cause muscle contraction,
An electric signal whose current amplitude of the electric signal increases to a predetermined set value within a predetermined time, an electric signal having an amplitude of 1000 μA or less,
It is composed of an electric signal whose current amplitude of the electric signal becomes smaller than a predetermined set value within a predetermined time,
The current stimulating device, wherein each of the predetermined times is an electric signal smaller than 1 second. A current stimulator for providing a transcutaneous current stimulus by supplying an electrical signal using a conductor,
The current stimulator can supply, as the electric signal, a first electric signal in a first mode or a second electric signal in a second mode,
The first electric signal is
It is an electrical signal used to improve muscle strength and a weak electrical signal that does not cause muscle contraction,
An electrical signal in which the amplitude of the current of the electrical signal increases to a predetermined value within a first time;
An electric signal having an amplitude of 1000 μA or less;
The current amplitude of the electric signal is reduced from a predetermined set value within the second time, and
The second electrical signal is
It is an electrical signal used to reduce muscle strength and a weak electrical signal that does not cause muscle contraction,
An electrical signal in which the amplitude of the current of the electrical signal increases to a predetermined set value within a third time; an electrical signal having an amplitude of 1000 μA or less;
A current stimulating device comprising an electric signal in which a current amplitude of the electric signal becomes smaller than a predetermined set value within a fourth time. A mode setting unit for arbitrarily selecting one of the first output mode and the second output mode, and outputting the first electric signal or the second electric signal according to the selected mode. The current stimulation device according to claim 3, characterized in that:   The current stimulation device according to claim 3, wherein the first time and the second time are not less than 1.1 seconds and not more than 4 seconds.   The current stimulation device according to claim 3, wherein the third time and the fourth time are not less than 0.1 seconds and not more than 0.9 seconds. A current stimulator for providing a transcutaneous current stimulus by supplying an electrical signal using a conductor,
The electrical signal is
It is an electrical signal used to improve muscle strength and a weak electrical signal that does not cause muscle contraction,
An electric signal in which the output of the electric signal increases to a predetermined set value within a predetermined time;
An electric signal of 1000 μA or less;
It is configured from an electric signal whose output of the electric signal becomes smaller than a predetermined set value within a predetermined time,
The current stimulating device, wherein each of the predetermined times is an electric signal longer than 1 second. A current stimulator for providing a transcutaneous current stimulus by supplying an electrical signal using a conductor,
The electrical signal is
An electrical signal used to reduce muscle strength and a weak current that does not cause muscle contraction,
An electric signal in which the output of the electric signal increases to a predetermined set value within a predetermined time;
An electric signal of 1000 μA or less;
It is configured from an electric signal whose output of the electric signal becomes smaller than a predetermined set value within a predetermined time,
The current stimulating device, wherein each of the predetermined times is an electric signal smaller than 1 second. A current stimulator for providing a transcutaneous current stimulus by supplying an electrical signal using a conductor,
The current stimulator can supply a first electric signal or a second electric signal as the electric signal,
The first electric signal is
It is an electrical signal used to improve muscle strength and a weak electrical signal that does not cause muscle contraction,
An electric signal in which the output of the electric signal increases to a predetermined set value within a predetermined time;
An electric signal of 1000 μA or less;
It is configured from an electric signal whose output of the electric signal becomes smaller than a predetermined set value within a predetermined time,
The second electrical signal is
It is an electrical signal used to reduce muscle strength and a weak electrical signal that does not cause muscle contraction,
An electric signal in which the output of the electric signal increases to a predetermined set value within a predetermined time;
An electric signal of 1000 μA or less;
A current stimulating device comprising an electric signal whose output becomes smaller than a predetermined set value within a predetermined time.