JP7006283B2 - Electrical stimulator - Google Patents

Description

The present invention relates to an electrical stimulator.

Conventionally, functional electrical stimulation (FES: Functional Electrical Stimulation) for the purpose of improving the function of paralyzed limbs, therapeutic electrical stimulation (TES: Thermal Electrical Stimulation) for the purpose of pain relief, etc., and prevention of muscle weakness, etc. Neuromuscular Electrical Stimulation (NMES) and Transcranial DC Electrical Stimulation (tDCS) for the purpose of improving aftereffects of stroke are known in Patent Document 1. An electrical stimulation system that combines electrical stimulation and transcranial DC electrical stimulation as one intervention system is described. FIG. 5A of Patent Document 1 exemplifies a timing diagram of transcranial direct current stimulation, and paragraph [096] describes that steady DC is usually applied for a time of 1 to 60 minutes, but a current. Details at the time of suspension are not described.

Special Table 2010-591003

In the technique of Patent Document 1, it is necessary to stop the electrical stimulation when the stop switch is pressed or when an abnormality occurs (when the current / voltage exceeds the reference value) while the transcranial direct current electrical stimulation is performed. At one point, there was the problem that when the current was sharply reduced, the subject felt an intraocular flash and the discomfort increased.
The present invention has been made to solve such a problem, and an object of the present invention is to provide an electric stimulator capable of preventing a subject from feeling an intraocular flash and increasing discomfort.

The electrical stimulator according to claim 1 includes an electrode attached to the head of the subject and a stimulus output means for outputting the electrical stimulus to the electrode, and when the electrical stimulus is stopped in the middle, the subject has an eye. When the output of the stimulus output means is reduced over a predetermined time in which the internal flash is hard to be felt and the output of the stimulus output means is reduced, the amount of change in the output per unit time is constant, and the stimulus output means. If the amount of change in the output per unit time when the steady value of the output of is set to zero in the predetermined time is equal to the amount of change in the output per unit time when the electrical stimulation is normally stopped, the change thereof. The amount is defined as the stop change amount, and if different, the larger change amount is defined as the stop change amount, and when the electrical stimulation is stopped in the middle, the change amount per unit time is set as the stop change amount of the stimulus output means. It is characterized by reducing the output . With this configuration, when it is necessary to stop the electrical stimulation in the middle, such as when the stop switch is pressed during electrical stimulation, or when an abnormality occurs, the subject can take a predetermined time to make it difficult for the subject to feel the intraocular flash. By continuously reducing the output, the electrical stimulus can be gradually reduced, and the subject can be prevented from feeling an intraocular flash. In addition, it is possible to prevent the electrical stimulation from being stopped for an extra long time, and the subject can quickly stop the electrical stimulation without feeling an intraocular flash.

The electrical stimulator according to claim 2 includes an electrode attached to the head of the subject and a stimulus output means for outputting the electrical stimulus to the electrode, and when the electrical stimulus is stopped in the middle, the subject has an eye. It is characterized in that the output of the stimulus output means is reduced over a predetermined time in which the internal flash is hard to be felt, and the amount of change in the output per unit time when the output of the stimulus output means is reduced is changed . .. With this configuration , when it is necessary to stop the electrical stimulation in the middle, such as when the stop switch is pressed during electrical stimulation, or when an abnormality occurs, the subject can take a predetermined time to make it difficult for the subject to feel the intraocular flash. By continuously reducing the output, the electrical stimulus can be gradually reduced, and the subject can be prevented from feeling an intraocular flash. In addition, the amount of change in output per unit time can be set so that the subject can quickly stop the electrical stimulation without feeling an intraocular flash.

The electrical stimulator according to claim 3 is characterized in that the amount of change in the output per unit time is larger when the output is smaller than when the output of the stimulus output means is large . With this configuration , the subject can quickly stop the electrical stimulation without feeling an intraocular flash.

The electrical stimulator according to claim 4 is characterized in that the amount of change in the output of the stimulus output means per unit time is changed according to the time. With this configuration, the subject can quickly stop the electrical stimulation without feeling an intraocular flash.

The electrical stimulator according to claim 5 takes a period of time during which the output of the stimulus output means in the normal operation of the electrical stimulus increases and / or decreases, so that the subject does not easily feel the phosphene. It is characterized in that the output of the stimulus output means is changed . With this configuration , the electrical stimulus can be gradually increased or decreased at the start or end of the normal operation of the electrical stimulus, and the subject can be prevented from feeling the intraocular flash.

The electrical stimulator according to claim 6 changes the amount of change in the output of the stimulus output means per unit time during the period, and the output is smaller when the output is smaller than when the output is larger. It is characterized by a large amount of change per unit time . With this configuration, the subject can quickly start or stop the electrical stimulation without feeling the phosphene.

The electrical stimulator according to claim 7 includes an electrode attached to the head of the subject and a stimulus output means for outputting the electrical stimulus to the electrode, and when the electrical stimulus is stopped in the middle, the subject has an eye. The subject reduces the output of the stimulus output means over a predetermined time during which the internal flash is hard to feel , and the subject increases and / or decreases the output of the stimulus output means in the normal operation of the electric stimulus. The output of the stimulus output means is changed over a period of time during which the phosphene is hard to be felt, and the amount of change in the output of the stimulus output means per unit time is changed during the period. The smaller the output, the larger the amount of change in the output per unit time . With this configuration , when it is necessary to stop the electrical stimulation in the middle, such as when the stop switch is pressed during electrical stimulation, or when an abnormality occurs, the subject can take a predetermined time to make it difficult for the subject to feel the intraocular flash. By continuously reducing the output, the electrical stimulus can be gradually reduced, and the subject can be prevented from feeling an intraocular flash. In addition, the electrical stimulus can be gradually increased or decreased at the start or end of the normal operation of the electrical stimulus, and the subject can be prevented from feeling the intraocular flash. In addition, the subject can quickly start or end the electrical stimulation without feeling the phosphene.

The electrical stimulator according to claim 8 is characterized in that the amount of change in the output of the stimulus output means per unit time is changed according to the time during the period . With this configuration, the subject can quickly start or stop the electrical stimulation without feeling the phosphene.

The electrical stimulator according to claim 9 is characterized by comprising an input means for setting the predetermined time . With this configuration, it is possible to set a predetermined time for each subject in consideration of the difference in the time during which the intraocular flash is felt depending on the subject.

The electrical stimulator according to claim 10 includes an electrode attached to the head of the subject and a stimulus output means for outputting the electrical stimulus to the electrode, and when the electrical stimulus is stopped in the middle, the subject has an eye. It is characterized by having an input means for reducing the output of the stimulus output means over a predetermined time in which the internal flash is hard to be felt and setting the predetermined time. According to this configuration, when it is necessary to stop the electrical stimulation in the middle, such as when the stop switch is pressed or when an abnormality occurs during the electrical stimulation, the stimulation output is performed over a predetermined time so that the subject does not easily feel the intraocular flash. By continuously reducing the output of the means, the electrical stimulus can be gradually reduced and the subject can be prevented from feeling an intraocular flash. In addition, a predetermined time can be set for each subject in consideration of the difference in the time during which the intraocular flash is felt depending on the subject.

According to the present invention, it is possible to prevent the subject from feeling an intraocular flash and increasing discomfort when the electrical stimulation is stopped halfway.

It is a top view of the electric stimulator which concerns on embodiment of this invention. It is a block diagram which shows the electric structure of the electric stimulator. It is a waveform diagram which shows an example of the current waveform which is output to an electrode from the constant current circuit in Embodiment 1. FIG. It is a waveform diagram which shows the other example of the current waveform output to the electrode from the constant current circuit in Embodiment 1. FIG. It is a waveform diagram which shows an example of the current waveform output from the constant current circuit in Embodiment 2 to an electrode. It is a waveform diagram which shows the other example of the current waveform output to the electrode from the constant current circuit in Embodiment 2. FIG.

Hereinafter, the electrical stimulator according to the embodiment of the present invention will be described with reference to the drawings.

(Embodiment 1)
As shown in FIG. 1, the electrical stimulator 1 according to the first embodiment of the present invention is electrically mounted on the main body 2 of the device, which is provided with an electric circuit for outputting electrical stimuli, and on the head of a subject. The main configuration is an electrode 3 to which a stimulus is applied and an electrode cable 4 for connecting the electrode 3 to the apparatus main body 2.

The electrode cable 4 is composed of a two-pole conductor cord, the base end side of the electrode cable 4 is detachably connected to the device main body 2, and the electrode 3 is detachably attached to the tip end side of the electrode cable 4. The electrode 3 is composed of two square electrodes 3a and 3b, and the square electrodes 3a and 3b are made of conductive silicon rubber. The shape of the electrode 3 may be any shape such as a quadrangle or a circle as long as it can be attached to the head and an electrical stimulus can be applied. Further, when the electrode 3 is attached to the head, a sponge (not shown) is attached to the electrode 3, the sponge is impregnated with physiological saline, and the head is electrically stimulated from the electrode 3 via the sponge. May be good. For example, a bag-shaped quadrangular sponge to which a quadrangular electrode can be inserted / removed, a circular sponge having a slit for inserting / removing a circular electrode into one of the two circular sponges whose peripheral edges are sewn together, etc. are used. can do. When the electrodes 3 are attached to the head of the subject, for example, the square electrodes 3a and 3b are attached to the frontal region and the occipital region, or the left and right portions of the frontal region, respectively.

On the surface of the device main body 2, an operation switch unit 5 for setting or changing stimulus conditions, a liquid crystal display unit 6 for displaying information such as the set stimulus conditions, and an electrode 3 blink when a current is output. An LED display unit 7 is provided, and a power switch 8 for turning on / off the power is provided on the upper surface of the apparatus main body 2. The operation switch unit 5 includes a start switch 5a for starting the application of electrical stimulation, a stop switch 5b for stopping the application of electrical stimulation, and an upper switch 5c for moving the cursor of the liquid crystal display unit 6 upward and increasing the set value of the stimulation condition. , The lower switch 5d that moves the cursor down of the liquid crystal display unit 6 and reduces the set value of the stimulus condition, the left switch 5e and the right switch 5f that move the cursor left and right of the liquid crystal display unit 6, respectively, of the stimulus condition. It is composed of various switch groups of 5 g of decision switches for setting and changing.

FIG. 2 is a block diagram showing an electrical configuration of the electrical stimulator 1. The electrical stimulator 1 has a control unit 9, a battery 10, a DC-DC converter 11, a constant current circuit 12, a DA converter 13, and a measurement circuit 14, which are provided inside the device main body 2. .. The control unit 9 controls the liquid crystal display unit 6, the LED display unit 7, and the DA converter 13, and is composed of a microcomputer. Data such as the set stimulus conditions are stored in the internal memory of the control unit 9.

The battery 10 can be charged by a charger 16 connected to a commercial power source via the AC adapter 15, and is a rechargeable battery such as a lithium ion secondary battery, but an alkaline dry battery or the like may be used. When the power switch 8 is turned on, the voltage of the battery 10 is supplied to the DC-DC converter 11. The DC-DC converter 11 boosts the voltage supplied from the battery 10 and supplies it to the control unit 9 and the constant current circuit 12. Further, the measurement circuit 14 is a circuit for measuring the current and the voltage between the square electrodes 3a and 3b. The current value and voltage value measured by the measurement circuit 14 are input to the control unit 9. For example, when the measured current value or voltage value exceeds the reference value, the control unit 9 controls the DA converter 13. The output of the constant current circuit 12 is reduced to stop the electrical stimulation. The voltage value of the battery 10 is input to the control unit 9, and the control unit 9 monitors the remaining amount of the battery 10. The DC-DC converter 11, the constant current circuit 12, and the DA converter 13 constitute a stimulus output means 17 for outputting a current to the electrode 3 and applying an electrical stimulus to the head.

Next, the current waveform output from the constant current circuit 12 to the electrode 3 will be described. FIG. 3 is an example of a current waveform, and the current waveforms output when normal electrical stimulation is performed (during normal operation) are shown by waveforms d1 to d3 (broken line). The waveform d1 represents a waveform in which the current increases from 0 to I1 during the time 0 to t1, the waveform d2 represents the waveform in which the current I1 is maintained during the time t1 to t2, and the waveform d3 represents the waveform in which the current I1 is maintained during the time t2 to t3. It represents a waveform in which the current decreases from I1 to 0. Between the times t1 and t2, the current output of the stimulus output means 17 is a steady value (current I1), and the time from time t1 to time t2 is referred to as operating time T1. During the current increase period (time 0 to t1 period) and current decrease period (time t2 to t3 period), the amount of change in current per unit time (hereinafter referred to as "unit change amount") is constant. These unit change amounts can be set by the user of the electrical stimulator 1 operating the operation switch unit 5. The unit change amount of the current during the increase and decrease periods of the current is a value at which the subject does not easily feel the phenophene when the current increases or decreases, and when the user sets the unit change amount, the subject sees the eye. It is possible to select from values that make it difficult to feel the internal flash. For example, the settable range of the unit change amount is 0.03 to 0.15 mA / sec, and a plurality of numerical values that can be set within this range may be prepared and can be selected and set from among them. In FIG. 3, the unit change amount of the current in the rising period and the unit change amount of the current in the falling period are the same, but they may be different. Further, the current I1 and the operating time T1 can be set by the user operating the operation switch unit 5. The settable range of the current I1 is, for example, 0.1 to 2.0 mA, and the settable range of the operating time T1 is, for example, 1 second to 60 minutes.

Waveforms a, b, and c shown by solid lines in FIG. 3 show current waveforms when it is necessary to stop the electrical stimulation in the middle, such as when the stop switch 5b is pressed or when an abnormality occurs during the electrical stimulation. There is. The waveform a shows the case where the electric stimulation is stopped while the current due to the normal electric stimulation is increasing, and the waveform b shows the case where the electric stimulation is stopped when the current due to the normal electric stimulation is a steady value. c shows the case where the electrical stimulation is stopped while the current due to the normal electrical stimulation is decreasing. The time T2, which is the time required for the current I1 to become 0, is called the abnormal stop time. The abnormal stop time T2 can be set by the user, for example, the settable range of the abnormal stop time T2 is 2 to 10 seconds. Further, the slopes of the waveforms a and c are the same as the slopes of the waveform b, and the waveforms a, b, and c are all reduced by the same unit change amount. That is, when the electric stimulation is stopped when the current due to the normal electric stimulation is a steady value, the current is reduced so that the current becomes 0 at the set abnormal stop time T2, and the current due to the normal electric stimulation is reduced. When the electrical stimulation is stopped in the middle of increasing or decreasing, the current is decreased by the same unit change amount as the waveform b. Note that FIG. 3 shows a case where the set abnormal stop time T2 is shorter than the time when the current decreases from I1 to 0 in the waveform d3 (length of the descending period: t3-t2).

FIG. 4 is another example of the current waveform in the first embodiment, and the waveforms d1 to d3 shown by the broken line are the same as the waveforms d1 to d3 shown in FIG. The waveform is shown. The time T3 represents an abnormal stop time (time required to set the current I1 to 0) set by the user as the time required to stop the electrical stimulation, and the abnormal stop time T3 is, for example, in the range of 2 to 10 seconds. It is configurable. FIG. 4 shows a case where the abnormal stop time T3 set by the user is longer than the time when the current decreases from I1 to 0 in the waveform d3 (length of the descending period: t3-t2).

Waveforms e and f shown by solid lines in FIG. 4 show current waveforms when it is necessary to stop the electrical stimulation in the middle, such as when the stop switch 5b is pressed or when an abnormality occurs during the electrical stimulation. The waveform e shows the case where the electric stimulation is stopped while the current due to the normal electric stimulation is increasing, and the waveform f shows the case where the electric stimulation is stopped when the current due to the normal electric stimulation is a steady value. .. Further, when the electrical stimulation is stopped while the current due to the normal electrical stimulation is decreasing, the current is reduced according to the waveform d3. The slopes of the waveforms e and f are the same as the slopes of the waveform d3, and the waveforms e and f are reduced by the same unit change amount as the current at the time of normal stop shown in the waveform d3.

Here, when the electrical stimulation is stopped in the middle, the subject may feel an intraocular flash when the current is suddenly reduced. On the other hand, in the present embodiment, the current is not rapidly reduced, but is gradually reduced over a predetermined time. For example, in FIG. 3, when the electrical stimulation is stopped within the period of time t1 to t2, the current is gradually reduced by applying the abnormal stop time T2. By setting the predetermined time to a time during which the subject is less likely to feel the intraocular flash, it is possible to prevent the subject from perceiving the intraocular flash when the electrical stimulation is stopped halfway.

Further, as described with reference to FIGS. 3 and 4, when the electrical stimulation is stopped in the middle, the unit change amount (Ra) of the current when the current I1 is set to zero (0) and the current at the time of normal stop are obtained. The current is reduced by the larger unit change amount of the unit change amount (Rb) of. When Ra and Rb are equal, the unit change amount is Ra (= Rb) and the current is reduced. That is, if the unit change amount of the output when the steady value of the output of the stimulus output means 17 is set to zero in a predetermined time and the unit change amount of the output when the normal stop of the electrical stimulation is equal, the unit change amount is the same. Is the stop change amount, and if they are not equal, the larger unit change amount is the stop change amount, and when the electrical stimulation is stopped in the middle, the unit change amount is set to the stop change amount and the output of the stimulus output means 17 is reduced. There is. As a result, it is possible to prevent the electrical stimulation from being stopped for an extra long time, and it is possible to stop the electrical stimulation quickly without the subject feeling an intraocular flash.

Here, an example of a condition for stopping the electrical stimulation in the middle due to the occurrence of an abnormality will be described. The first condition is that the current value between the electrodes (between the square electrodes 3a and 3b) exceeds the reference value. The second condition is that the voltage value between the electrodes exceeds the reference value. The third condition is that the resistance value between the electrodes exceeds the reference value. The fourth condition is that the AD converter (not shown) does not operate normally due to a CPU failure in the control unit 9, and the current and voltage between the electrodes cannot be measured. The fifth condition is that the voltage of the battery 10 drops below the reference value. The sixth condition is that the control unit 9 cannot monitor the voltage of the battery 10. When any of the first to sixth conditions is satisfied, the electrical stimulation is stopped halfway as described with reference to FIGS. 3 and 4. In addition, the cause of the increase in the voltage value and resistance value between the electrodes is that the subject moves during long-term electrical stimulation, and the saline solution contained in the sponge dries, causing the electrodes to be sent to the subject. It is conceivable that the contact area will be smaller. The reference value may be constant or variable.

Next, an example of setting the stimulus condition will be described. As an example, it is assumed that the current I1 is set to 1 mA, the unit change amount of the waveform d3 is set to 0.1 mA / sec, and the abnormal stop time is set to 5 seconds. In this case, the time from the time t2 to the time t3 is 10 seconds, which is longer than the abnormal stop time of 5 seconds. Therefore, when the electrical stimulation is stopped in the middle, the current decreases according to the current waveform shown in FIG.

As another setting example of the stimulus condition, it is assumed that the current I1 is set to 0.2 mA, the unit change amount of the waveform d3 is set to 0.05 mA / sec, and the abnormal stop time is set to 5 seconds. In this case, the time from the time t2 to the time t3 is 4 seconds, which is shorter than the abnormal stop time of 5 seconds. Therefore, when the electrical stimulation is stopped in the middle, the current decreases according to the current waveform shown in FIG.

As described above, when the electrical stimulation is stopped in the middle, the output of the stimulation output means 17 is reduced over a predetermined time during which the subject is less likely to feel the phosphene. As a result, it is possible to prevent the subject from feeling an intraocular flash even when the electrical stimulation is stopped halfway. Further, the electrical stimulator may be provided with an input means for setting a predetermined time, and the operation switch unit 5 is an example of the input means. If such an input means is provided, it is possible to set a predetermined time for each subject in consideration of the difference in the time for perceived the intraocular flash depending on the subject.

In order to make it difficult for the subject to perceive the phosphene, it is considered that a longer abnormal stop time is required when the set current I1 value is larger than when it is small. In consideration of this point, the settable range of the abnormal stop time may be changed according to the value of the current I1 set by the user. For example, the larger the value of the set current I1, the larger the lower limit of the settable range of the abnormal stop time. In addition, an example was shown in which the unit change amount of the current during the increase period and the decrease period of the current can be set by the user, but the unit change amount is determined in advance and stored in the device so that the user does not set it. You may do it. This eliminates the need for the user to be aware of the unit change amount during the increase period and the decrease period of the current, reduces the items set by the user, and makes the electric stimulator easier to handle.

(Embodiment 2)
In the first embodiment, when the electrical stimulation is normally stopped and when the electrical stimulation is stopped in the middle, the current is reduced by a constant unit change amount until the current value becomes zero, but the unit change amount is not always constant. It is not necessary to be, and the unit change amount of the current may change. For example, when the current value is small, the subject is less likely to feel the phenophene even if the unit change of the current is slightly large, and when the current value is large, the subject is more likely to feel the phenophene unless the unit change of the current is small. Conceivable. From this, it is possible to increase the unit change amount of the current when the current value is small as compared with the case where the current value is large.

Therefore, FIG. 5 shows an example of the current waveform when the unit change amount of the current is changed. In FIG. 5, the current waveforms output when normal electrical stimulation is performed are shown by waveforms d1 to d3 (broken line). The waveform d1 represents a waveform in which the current increases from 0 to I1 during the time 0 to t1, the waveform d2 represents the waveform in which the current I1 is maintained during the time t1 to t2, and the waveform d3 represents the waveform in which the current I1 is maintained during the time t2 to t3. It represents a waveform in which the current decreases from I1 to 0. During the time t1 to t2, the current output of the stimulus output means 17 is a steady value (current I1), and the time from time t1 to time t2 is referred to as operating time T1. The current I1 and the operating time T1 can be set by the user. For example, the settable range of the current I1 is, for example, 0.1 to 2.0 mA, and the settable range of the operating time T1 is, for example, 1 second to 60 minutes.

In the current rising period (time 0 to t1 period) and the current falling period (time t2 to t3 period), the currents 0 to I1 are divided into four regions to change the unit change amount of the current. That is, the currents 0 to Ia are defined as the region A, the currents Ia to Ib are defined as the region B, the currents Ib to Ic are defined as the region C, the currents Ic to I1 are defined as the region D, and the unit change amount of the current is constant in each region A to D. .. The unit change amount of the current is smaller in the region where the current value is larger than in the region where the current value is small, and the unit change amount of the current is smaller in the order of region A, region B, region C, and region D. It has become. Here, the user may be able to set the unit change amount of the current in each of the regions A to D of the current rising period and the current falling period. In addition, it is necessary for the user to be aware of the unit change amount in the rising period and the falling period of the current by predetermining the unit change amount of the current in each region A to D and not setting it by the user. It disappears and the electric stimulator can be made easier to handle. The unit change amount of the current in each of the regions A to D is set to a value at which the subject does not easily feel the phosphene.

In FIG. 5, the waveform k shown by the alternate long and short dash line indicates the current waveform when the electrical stimulation needs to be stopped in the middle, such as when the stop switch 5b is pressed or when an abnormality occurs during the electrical stimulation. The current is reduced from I1 to 0 by a constant unit change amount. The time (abnormal stop time) T4 required for the current to change from I1 to 0 in the waveform k can be set by the user. For example, the settable range of the abnormal stop time T4 is 2 to 10 seconds. By setting in such a settable range, the abnormal stop time T4 can be set to a time during which the subject is less likely to perceive the phosphene. Note that FIG. 5 shows a case where the set abnormal stop time T4 is shorter than the time when the current decreases from I1 to 0 in the waveform d3 (length of the descending period: t3-t2).

In FIG. 5, the waveforms a, b, and c show current waveforms when it is necessary to stop the electrical stimulation in the middle, and are examples in which the unit change amount of the current is changed. The waveform a shows the case where the electric stimulation is stopped while the current due to the normal electric stimulation is increasing, and the waveform b shows the case where the electric stimulation is stopped when the current due to the normal electric stimulation is a steady value. c shows the case where the electrical stimulation is stopped while the current due to the normal electrical stimulation is decreasing. In the waveforms a, b, and c, as in the waveforms d1 and d3, the unit change amount of the current is constant in each of the regions A to D, and the current in the region where the current value is large is higher than that in the region where the current value is small. The unit change amount of the current is reduced in the order of region A, region B, region C, and region D. The unit change amount in the region D of the waveform b is the same value as the unit change amount of the waveform k. Further, the unit change amount of the current in each of the regions A to D is set to the same value in the waveforms a, b, and c, and is set to a value at which the subject is less likely to perceive the intraocular flash.

The time (abnormal stop time) T5 required for the current to change from I1 to 0 in the waveform b is shorter than the time (abnormal stop time) T4 required for the current to change from I1 to 0 in the waveform k. When the electrical stimulation is stopped in the middle, the current may be reduced according to the waveform k, but when the current is smaller than when the current is large as in waveform b, the unit change amount of the current is increased to increase the current. By reducing the amount, the abnormal stop time can be shortened as compared with the case where the unit change amount of the current is constant. Therefore, in the case of the waveforms a, b, and c, the subject can quickly stop the electrical stimulation without feeling an intraocular flash.

Here, when the current is reduced by the waveforms a, b, and c shown in FIG. 5, the user sets the abnormal stop time T4, determines the unit change amount in the region D based on the setting, and the unit of the region D. The unit change amount in other regions A to C may be determined so as to be larger than the change amount. For example, a range of the unit change amount that can be taken in the areas A to C is determined, and within the range, the unit change amount gradually increases in the order of the area D, the area C, the area B, and the area A. The unit change amount of A to C may be set.

FIG. 6 is another example of the current waveform in the second embodiment, and the waveforms d1 to d3 shown by the broken line are the same as the waveforms d1 to d3 shown in FIG. The waveform is shown. The waveforms e and f shown by the solid lines show current waveforms when it is necessary to stop the electrical stimulation in the middle, such as when the stop switch 5b is pressed or when an abnormality occurs during the electrical stimulation. The waveform e shows the case where the electric stimulation is stopped while the current due to the normal electric stimulation is increasing, and the waveform f shows the case where the electric stimulation is stopped when the current due to the normal electric stimulation is a steady value. .. Further, when the electrical stimulation is stopped while the current due to the normal electrical stimulation is decreasing, the current is reduced according to the waveform d3. The waveform f is the same as the waveform d3, and the waveform e has a shape overlapping the waveform d3. That is, the unit change amount in each region A to D of the waveforms e and f is the same as the unit change amount in each region A to D of the waveform d3. As a result, the subject can stop the electrical stimulation without feeling the intraocular flash. The time T6 represents an abnormal stop time (time required to set the current I1 to 0) set by the user as the time required to stop the electrical stimulation, and the abnormal stop time T6 is, for example, 2 to 10 seconds. It can be set in a range. FIG. 6 shows a case where the abnormal stop time T6 set by the user is longer than the time when the current decreases from I1 to 0 in the waveform d3 (length of the descending period: t3-t2).

In the second embodiment, an example in which the currents 0 to I1 are divided into four regions has been described, but the number of divided regions is not limited to four and may be a plurality of regions, and the number of divided regions can be changed. You may. In the second embodiment, the unit change amount of the current is changed according to the current value. For example, the unit change amount becomes smaller as the time elapses in the current increase period, and the time in the current decrease period. The unit change amount of the current may be changed according to time so that the unit change amount increases with the lapse of time.

Further, instead of attaching both the square electrodes 3a and 3b to the head, for example, the square electrodes 3a are attached to the left frontal region and the square electrodes 3b are attached to the upper left arm, so that at least the square electrodes 3a and 3b are attached to the head. By applying the present invention to an electrical stimulator to which one electrode is attached and an electrical stimulus is applied, the subject feels an intraocular flash and the discomfort increases even when the electrical stimulus is stopped in the middle. Can be prevented.

It can be applied to an electric stimulator in which at least one electrode is attached to the head to give an electric stimulus.

1 Electrical stimulator 2 Device body 3 Electrode 3a, 3b Square electrode 4 Electrode cable 5 Operation switch 6 Liquid crystal display 7 LED display 8 Power switch 9 Control 10 Battery 11 DC-DC converter 12 Constant current circuit 13 DA converter 14 Measurement circuit 15 AC adapter 16 Charger 17 Stimulation output means

Claims (10)

It is provided with an electrode to be attached to the head of the subject and a stimulus output means for outputting an electrical stimulus to the electrode, and when the electrical stimulus is stopped in the middle, it takes a predetermined time for the subject to hardly feel an intraocular flash. By reducing the output of the stimulus output means ,
The amount of change in the output per unit time when the output of the stimulus output means is reduced is constant, and the unit time of the output when the steady value of the output of the stimulus output means is set to zero in the predetermined time. If the change amount per unit time is equal to the change amount per unit time of the output when the electrical stimulation is normally stopped, the change amount is defined as the stop change amount, and if they are different, the larger change amount is referred to as the stop change amount. age,
An electrical stimulator characterized in that when the electrical stimulus is stopped in the middle, the amount of change per unit time is set to the stop change amount to reduce the output of the stimulus output means . It is provided with an electrode to be attached to the head of the subject and a stimulus output means for outputting an electrical stimulus to the electrode, and when the electrical stimulus is stopped in the middle, it takes a predetermined time for the subject to hardly feel an intraocular flash. By reducing the output of the stimulus output means,
An electrical stimulator, characterized in that the amount of change in the output per unit time when the output of the stimulus output means is reduced is changed. The amount of change in the output per unit time is larger when the output is smaller than when the output of the stimulus output means is large.
The electrical stimulator according to claim 2 . The amount of change in the output of the stimulus output means per unit time is changed according to the time.
The electrical stimulator according to claim 2 or 3 . During the period in which the output of the stimulus output means increases and / or decreases in the normal operation of the electrical stimulus, the output of the stimulus output means is changed over a period of time during which the subject is less likely to perceive an intraocular flash.
The electrical stimulator according to any one of claims 1 to 4 . The amount of change in the output of the stimulus output means per unit time is changed during the period, and the amount of change in the output per unit time is larger when the output is smaller than when the output is large.
The electrical stimulator according to claim 5 . It is provided with an electrode to be attached to the head of the subject and a stimulus output means for outputting an electrical stimulus to the electrode, and when the electrical stimulus is stopped in the middle, it takes a predetermined time for the subject to hardly feel an intraocular flash. By reducing the output of the stimulus output means,
During the period in which the output of the stimulus output means increases and / or decreases in the normal operation of the electrical stimulus, the output of the stimulus output means is changed over a period of time during which the subject is less likely to perceive the phosphene.
The amount of change in the output of the stimulus output means per unit time is changed during the period, and the amount of change in the output per unit time is larger when the output is smaller than when the output is large. An electrical stimulator characterized by that. During the period, the amount of change in the output of the stimulus output means per unit time is changed according to the time.
The electrical stimulator according to any one of claims 5 to 7 . An input means for setting the predetermined time is provided.
The electrical stimulator according to any one of claims 1 to 8 . It is provided with an electrode to be attached to the head of the subject and a stimulus output means for outputting an electrical stimulus to the electrode, and when the electrical stimulus is stopped in the middle, it takes a predetermined time for the subject to hardly feel an intraocular flash. By reducing the output of the stimulus output means,
An electrical stimulator comprising an input means for setting the predetermined time.

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