KR102412516B1 - Microcurrent stimulation device and method considering impedance measured from skin according to lesion - Google Patents

Abstract

an input unit for receiving a control mode; an electrode unit including a counter electrode set to an arbitrary polarity and a working electrode set to a polarity opposite to the counter electrode; and a control unit for outputting a current to the electrode unit so that the voltage appearing in the electrode unit appears in a preset waveform with respect to the direction of the current and the magnitude range of the current according to the control mode; to provide.

Description

Microcurrent stimulation device and method using biomimetic current

The present invention relates to a microcurrent stimulation device and method that takes into account the on-resistance measured from the skin according to the lesion, and more particularly, to the on-resistance or phase angle calculated according to the voltage measured at the wound site and the output current. It relates to an apparatus and method for outputting a microcurrent according to the present invention.

Diseases such as chronic scars and wounds need to be resolved for a normal life. On the other hand, research results have been reported that the treatment period can be shortened when a physical stimulus is applied to such a disease.

A treatment method using a microcurrent is a treatment method in which an electric current of less than 1 mA is applied to a damaged tissue, and this treatment method has the advantage of being able to perform long-term treatment without side effects. Accordingly, a treatment method using a microcurrent has no side effects in treating a disease and has an excellent effect, so it is used in various treatment institutions.

On the other hand, in the treatment method using a microcurrent, electrical stimulation of different sizes is applied depending on the wound healing process. At this time, the wound healing process can be largely classified into an inflammatory phase, a proliferative phase, and a maturation phase, and it is known that the types of cells involved in wound healing are different in each phase. In addition, since cells involved in wound healing in each step have different electrotaxis, electrical stimulation should be applied in consideration of this. Here, it is known that electrostaticity refers to a phenomenon in which an arbitrary object existing in an electric field is attracted to a specific polarity. For example, macrophages active in the inflammatory phase are known to migrate along the positive electrode, and fibroblasts active in the proliferative phase are known to migrate along the negative electrode.

Accordingly, there is a need for a method capable of applying electrical stimulation of an appropriate size to the wound area according to the progress of the wound.

Domestic Registered Patent No. 10-1033287 (2011.04.28.)

The technical problem to be solved by the present invention is to provide an apparatus and method for outputting a microcurrent according to an on-resistance or a phase angle calculated according to a voltage and an output current measured at a wound site.

One aspect of the present invention, the input unit for receiving a control mode set according to at least one element of the direction of the current and the magnitude range of the current; an electrode unit including a counter electrode set to an arbitrary polarity and a working electrode set to a polarity opposite to a polarity appearing in the counter electrode; and a control unit configured to output a current to the electrode unit so that the voltage appearing in the electrode unit appears in a preset waveform with respect to at least one element among the direction of the current and the magnitude range of the current according to the control mode can

In addition, the control mode may include at least one control mode among an inflammatory phase mode, a proliferative phase mode, and a maturation phase mode for determining at least one element of a direction of a current output from the controller and a magnitude range of the current.

In addition, the control unit outputs a current to the electrode unit so that the current moves from the working electrode to the counter electrode in the inflammatory phase mode, and a voltage difference value measured between the counter electrode and the working electrode is preset The current may be controlled to be maintained at a set inflammatory phase set voltage.

In addition, in the multiplication mode, the control unit outputs a current to the electrode unit so that the current moves from the counter electrode to the working electrode, and a voltage difference value measured between the counter electrode and the working electrode is preset The current may be controlled so as to be maintained at a set multiplier set voltage.

In addition, in the mature mode, the controller outputs a current to the electrode unit so that the current moves from the counter electrode to the working electrode, and a voltage difference value measured between the counter electrode and the working electrode is preset in advance. The current may be controlled so as to be maintained at a set maturity stage voltage.

In addition, the control unit calculates at least one of an on-resistance value and a phase angle value between the counter electrode and the working electrode according to a voltage difference value between the counter electrode and the working electrode and a current value output from the control unit, , a current value output to the electrode unit may be controlled according to at least one of the on-resistance value and the phase angle value.

In addition, the control unit may output the current so that the first to fifth steps representing the form of outputting the current according to the frequency of the current output to the electrode unit are sequentially repeated.

In addition, in the first step, the magnitude of the current output from the control unit may be output according to a constant frequency from the initial value to the magnitude of the current set in advance.

Also, in the second step, the magnitude of the current output from the controller may decrease from the magnitude of the current output in the first step to a preset magnitude in the form of an exponential function for a predetermined time interval.

In addition, in the third step, the magnitude of the current reduced according to the second step may maintain a constant magnitude.

Also, in the fourth step, the magnitude of the current output from the control unit may decrease from the magnitude of the current output in the third step to an initial value.

In addition, in the fifth step, the magnitude of the current reduced to the initial value by the fourth step may be maintained.

In another aspect of the present invention, in the microcurrent stimulation method for outputting a microcurrent in consideration of the on-resistance measured in the skin according to the lesion, a control mode indicating at least one element of the direction of the current and the range of the magnitude of the current receiving input; At least one element of the direction of the current and the range of the magnitude of the current according to the control mode, in the electrode part having a counter electrode set to an arbitrary polarity and a working electrode set to a polarity opposite to the polarity shown in the counter electrode outputting a current so that the voltage appearing in the electrode part appears in a preset waveform; calculating an on-resistance value between the counter electrode and the working electrode according to a voltage difference value between the counter electrode and the working electrode and a current value output from the step of outputting the current; and controlling a current value output to the electrode unit according to the on-resistance value.

In addition, the control mode may include at least one control mode of an inflammatory phase mode, a proliferative phase mode, and a maturation phase mode that determines at least one element of a direction of the current and a magnitude range of the current.

In addition, the outputting of the current may include outputting a current to the electrode unit so that the current moves from the working electrode to the counter electrode in the inflammatory phase mode.

In addition, the outputting of the current may include outputting a current to the electrode unit so that the current moves from the counter electrode to the working electrode in the multiplication mode.

In addition, the outputting of the current may include outputting a current to the electrode unit so that the current moves from the counter electrode to the working electrode in the maturation mode.

In addition, the controlling of the current value may include controlling the current so that a voltage difference value measured between the counter electrode and the working electrode is maintained at a voltage preset according to the control mode.

In addition, the outputting of the current may output the current so that the first to fifth steps representing the form of outputting the current according to the frequency of the current output to the electrode unit are sequentially repeated.

Also, in the first step, the magnitude of the current output in the step of outputting the current may be output according to a constant frequency from the initial value to the magnitude of the current set in advance.

In addition, in the second step, the magnitude of the current output from the step of outputting the current may decrease from the magnitude of the current output in the first step to a preset magnitude in the form of an exponential function for a predetermined time interval. .

In addition, in the third step, the magnitude of the current reduced according to the second step may maintain a constant magnitude.

Also, in the fourth step, the magnitude of the current output in the step of outputting the current may decrease from the magnitude of the current output in the third step to an initial value.

In addition, in the fifth step, the magnitude of the current reduced to the initial value by the fourth step may be maintained.

According to one aspect of the present invention described above, by providing a microcurrent stimulation device and method that considers the on-resistance measured from the skin according to the lesion, the on-resistance or phase calculated according to the voltage measured at the wound site and the output current It is possible to output a micro current according to each angle.

1 is a schematic diagram of a microcurrent stimulation apparatus according to an embodiment of the present invention.
2 is a control block diagram of a microcurrent stimulation apparatus according to an embodiment of the present invention.
FIG. 3 is a schematic diagram showing the electrode part of FIG. 2 .
4A and 4B are schematic diagrams illustrating the polarity of a current output from the electrode unit of FIG. 2 .
5A to 5C are graphs illustrating the flow of current output from the electrode unit of FIG. 2 .
6A and 6B are graphs illustrating a change in voltage output to an electrode unit according to the control unit of FIG. 2 .
7 is a flowchart of a microcurrent stimulation method according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0012] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0010] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0010] Reference is made to the accompanying drawings, which show by way of illustration specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different but need not be mutually exclusive. For example, certain shapes, structures, and characteristics described herein with respect to one embodiment may be implemented in other embodiments without departing from the spirit and scope of the invention. In addition, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the present invention. Accordingly, the detailed description set forth below is not intended to be taken in a limiting sense, and the scope of the present invention, if properly described, is limited only by the appended claims, along with all scope equivalents as those claimed. Like reference numerals in the drawings refer to the same or similar functions throughout the various aspects.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the drawings.

1 is a schematic diagram of a microcurrent stimulation apparatus according to an embodiment of the present invention.

The microcurrent stimulation device 100 may be formed such that the portion where the input unit 110 is positioned is gripped, and the electrode unit 120 is in contact with the wound site.

The input unit 110 may receive a control mode input from the outside, where the control mode selects at least one control mode according to at least one element of the direction of the current applied to the wound site according to the lesion and the range of the magnitude of the current. may include

In this case, the control mode may include at least one of an inflammatory phase mode, a proliferative phase mode, and a maturation phase mode depending on the lesion.

The inflammatory phase mode may be set when the user's lesion is in the inflammatory phase, in which the inflammatory phase occurs when a wound occurs, platelets stick to the wound site, inflammatory cells gather in the wound area, and bacteria or wounds invading from the outside It can be understood as the process of removing dead tissue.

The proliferative mode can be set when the user's lesion is in the proliferative stage, in which epithelial cells migrate or proliferate in the wound site to cover the wound site, and the fibrous cells present in the dermal layer produce fibers to form new flesh It can be understood as a process

The mature mode may be set when the user's lesion is in the mature stage, in which the inflammatory cells gathered in the inflammatory stage disappear and the new flesh generated in the proliferative stage matures similarly to the skin tissue of the undamaged body part. can be understood as

The control mode according to the lesion stage may be modified or changed to another stage according to different classification conditions for the lesion, and the present invention is not limited by this embodiment, and may be replaced without departing from the spirit and scope of the present invention. It should be understood that there can be

The input unit 110 is provided with one button, so that different control modes can be sequentially changed, and the input unit 110 is provided with two buttons formed of an up button and a down button, which are sequentially arranged. It may be formed to change to an adjacent control mode according to the input of a button among different control modes, and the input unit 110 includes the same number of buttons as the number of different control modes according to an arbitrary button input from the outside. It may be formed to change to a control mode set in a corresponding button.

In this case, the button provided in the input unit 110 may be formed in various ways, such as a touch method and a press method.

On the other hand, the electrode unit 120 may mean a conductor provided to flow a current, the electrode unit 120 may be applied with a preset current according to the control mode received from the input unit 110, the electrode When the unit 120 is in contact with the wound, the current applied to the electrode unit 120 may be applied to the skin.

To this end, the electrode unit 120 may include a plurality of electrodes set to have different polarities. Accordingly, the electrode unit 120 in contact with the skin proceeds from an electrode set as an anode among the plurality of electrodes to the skin. current may flow to the electrode set as the cathode among the plurality of electrodes.

In this case, the flow of current may be generally understood in a direction opposite to the movement of electrons, and the movement of electrons may be understood as movement of electrons present in a body or object from the cathode toward the anode.

On the other hand, each element of the microcurrent stimulation device 100 will be described in detail below.

2 is a control block diagram of a microcurrent stimulation apparatus according to an embodiment of the present invention.

The microcurrent stimulation apparatus 100 may include an input unit 110 , an electrode unit 120 , and a control unit 130 .

The input unit 110 may receive a control mode set according to at least one of the direction of the current and the range of the magnitude of the current.

Here, the control mode may include at least one control mode of an inflammatory phase mode, a proliferative phase mode, and a maturation phase mode for determining at least one element among the direction of the current output from the controller 130 and the magnitude range of the current.

The electrode unit 120 may include a counter electrode set to an arbitrary polarity according to a control mode input from the input unit 110 , and a working electrode set to a polarity opposite to the polarity appearing in the counter electrode.

In this case, the working electrode may be located at the center of the electrode unit 120 , and the counter electrode may be provided in a shape surrounding the working electrode located at the center of the electrode unit 120 .

Accordingly, when the electrode unit 120 is in contact with a wound site, the current output from one of the working electrode or the counter electrode may proceed to one of the counter electrode or the working electrode through the skin of the wound site. .

To this end, the working electrode and the counter electrode of the electrode part 120 may be formed to be electrically insulated.

At this time, the electrode part 120 may be provided in various shapes such as a circle, a triangle, a square, and a hexagon, and the electrode part 120 has a single axis that cuts the center of the electrode part 120 so as to be able to contact the curved wound site. may be formed in a concave shape.

In addition, the electrode part 120 may be formed in a shape that is concave as it progresses from the outside to the center side of the electrode part 120 , and the electrode part 120 is formed of a material having elasticity and in contact with the wounded part. , can be formed to adapt to the shape of the wound site.

The controller 130 may output a current to the electrode unit 120 according to at least one of a direction of a current and a range of a magnitude of the current according to the control mode.

At this time, the current output from the control unit 130 may appear as an alternating current, and the current output from the control unit 130 is a waveform in which an action potential waveform appearing in the muscle cell membrane in the body and a DC current waveform of a preset size are mixed. It may be a current represented by .

In this case, the action potential may be preset to indicate a constant frequency, and the input unit 110 may receive one frequency from a plurality of preset frequencies from the outside. In this case, the control unit 130 may mix the AC current representing the frequency input from the input unit 110 with the DC current and output it to the electrode unit 120 .

On the other hand, the input unit 110 may receive an arbitrary frequency from the outside, the present invention is not limited by this embodiment, and it goes without saying that it can be changed without departing from the spirit and scope of the present invention.

Here, when the control unit 130 determines the direction of the current according to the control mode, the direction of the current is directed from the counter electrode to the working electrode by setting the working electrode as the negative electrode and the counter electrode as the positive electrode according to the control mode. Alternatively, it may be understood that the direction of current is determined from the working electrode toward the counter electrode by setting the working electrode as the positive electrode and the counter electrode as the negative electrode.

In addition, when the control unit 130 determines the magnitude range of the current according to the control mode, the control unit 130 controls the magnitude difference between the working electrode and the counter electrode according to the control mode to maintain a preset range. It can be understood that the magnitude range of the current output to the electrode part 120 is determined.

As such, the direction of the current output from the controller 130 and the magnitude range of the current may vary according to a control mode including at least one of an inflammatory mode, a proliferative mode, and a maturation mode.

The control unit 130 may output a current to the electrode unit 120 so that the current moves from the working electrode to the counter electrode in the inflammatory phase mode, which means that the control unit 130 sets the working electrode as the positive electrode and the counter electrode It can be understood as setting the negative electrode.

In this case, the controller 130 may control the current so that the voltage difference value measured between the counter electrode and the working electrode is maintained at a preset inflammatory stage voltage.

The control unit 130 may output a current to the electrode unit 120 so that the current moves from the counter electrode to the working electrode in the multiplier mode, which means that the control unit 130 sets the working electrode as the negative electrode and the counter electrode It can be understood as setting the positive pole.

In this case, the controller 130 may control the current such that the voltage difference value measured between the counter electrode and the working electrode is maintained at a preset voltage for the growth phase.

The control unit 130 may output a current to the electrode unit 120 so that the current moves from the counter electrode to the working electrode in the maturation mode, in which case the control unit 130 sets the working electrode as the negative electrode and the counter electrode It can be understood as setting the positive pole.

In this case, the controller 130 may control the current so that a voltage difference value measured between the counter electrode and the working electrode is maintained at a preset voltage for maturity.

To this end, the controller 130 may calculate at least one of an on-resistance value or a phase angle value between the counter electrode and the working electrode according to a voltage difference value between the counter electrode and the working electrode and a current value output from the controller 130 . have.

Here, the on-resistance value may be understood as an impedance value expressed as a ratio of current and voltage according to Ohm's law, and the on-resistance value may include a resistance value that is a real value and a reactance value that is an imaginary value.

Also, the phase angle value may mean a difference between a phase appearing in an AC form in voltage and a phase appearing in an alternating current form in a voltage.

The controller 130 may control the current value output to the electrode unit 120 according to at least one of an on-resistance value and a phase angle value.

In this case, when the on-resistance value is greater than a preset threshold on-resistance value, the controller 130 may output a preset threshold current to the electrode unit 120 .

Also, when the phase angle value is greater than a preset critical phase angle value, the controller 130 may output a preset threshold current to the electrode unit 120 .

FIG. 3 is a schematic diagram showing the electrode part of FIG. 2 .

The electrode unit 120 includes a counter electrode 121 set to an arbitrary polarity according to a control mode input from the input unit 110 and a working electrode 122 set to a polarity opposite to the polarity appearing in the counter electrode 121 . may include

In this case, the working electrode 122 may be located at the center of the electrode unit 120 , and the counter electrode 121 may be provided in a shape surrounding the working electrode 122 located at the center of the electrode unit 120 . have.

Accordingly, when the electrode part 120 is in contact with the wound site, the current output from one of the working electrode 122 or the counter electrode 121 passes through the skin of the wound site to the counter electrode 121 or the actuating electrode 121 . It may proceed to one electrode among the electrodes 122 .

To this end, the working electrode 122 and the counter electrode 121 of the electrode part 120 may be formed to be electrically insulated.

At this time, the electrode part 120 may be provided in various shapes such as a circle, a triangle, a square, and a hexagon, and the electrode part 120 has a single axis that cuts the center of the electrode part 120 so as to be able to contact the curved wound site. may be formed in a concave shape.

In addition, the electrode part 120 may be formed in a shape that is concave as it progresses from the outside to the center side of the electrode part 120 , and the electrode part 120 is formed of a material having elasticity and in contact with the wounded part. , can be formed to adapt to the shape of the wound site.

4A and 4B are schematic diagrams illustrating the polarity of a current output from the electrode unit of FIG. 2 .

Referring to FIG. 4A , it can be understood that the working electrode 122 is set as an anode and the counter electrode 121 is set as a cathode. In this case, the direction of current is from the working electrode 122 to the counter electrode 121 . You can move in the direction of the arrow pointing towards

The control unit 130 may output a current to the electrode unit 120 so that the current moves from the working electrode 122 to the counter electrode 121 in the inflammatory phase mode. Thus, a current may be output to the electrode unit 120 .

Referring to FIG. 4B , it can be understood that the counter electrode 121 is set as an anode and the working electrode 122 is set as a cathode. In this case, the direction of current is from the counter electrode 121 to the working electrode 122 . You can move in the direction of the arrow pointing towards

The controller 130 may output a current to the electrode part 120 so that the current moves from the working electrode 122 to the counter electrode 121 in the proliferative mode or the maturation mode, and in this case, the controller 130 is shown in FIG. 4B . A current may be output to the electrode unit 120 in the same manner as shown in FIG.

5A to 5C are graphs illustrating the flow of current output from the electrode unit of FIG. 2 .

Referring to FIG. 5A , it is possible to check the current waveform of one cycle appearing from the electrode unit 120 . In this regard, the control unit 130 outputs a current according to the frequency of the current output to the electrode unit 120 . A current may be output so that a plurality of steps representing

At this time, the current appearing in the electrode part 120 may be understood as a waveform of the current output from the controller 130 , and the current output from the controller 130 is a voltage measured from the working electrode 122 and the counter electrode 121 . It can be understood that the waveform of the current appearing from the electrode part 120 is proportional to the waveform of the voltage.

Meanwhile, the waveform of the current may include a first phase 131 , a second phase 132 , a third phase 133 , a fourth phase 134 , and a fifth phase 135 within one cycle. .

Here, one cycle including different steps may mean one cycle in a cycle that is repeated in the same form according to the frequency of the AC current output from the controller 130 .

The first step 131 may be understood as a step in which a preset current is output according to a constant frequency, and in this case, the current level before the first step 131 is executed may be understood as an initial value. .

In this case, the constant frequency may mean the frequency of the current output from the controller 130 .

In addition, the magnitude of the preset current may be determined by the action potential waveform appearing in the muscle cell membrane within the body, and the magnitude of this current may vary depending on the control mode, and even in each control mode, different magnitudes depending on the human body environment may appear as

In this regard, the magnitude of the current output in the first step 131 may be generally set according to the action potential waveform appearing in the muscle cell membrane in the human body, and may vary within the range of a constant current according to an external input. In order to output a current of a different magnitude, different magnitudes of current may be provided in advance.

On the other hand, in an arbitrary control mode, the magnitude of the current appearing in the first step 131 can be understood as the maximum value of the magnitude of the current output from the controller 130 , and the initial value of the magnitude of the current is output from the controller 130 . It can be understood as the minimum value of the current magnitude.

The second step 132 is a step in which the magnitude of the current output from the control unit 130 for a predetermined time interval from the magnitude of the current output in the first step 131 is reduced to a preset magnitude in the form of an exponential function. can

At this time, the magnitude of the current finally reduced in the second step 132 may be the same as the magnitude of the current shown in the third step 133 , and the form in which the magnitude of the current is decreased in the second step 132 is exponential Depending on the function, the magnitude of the current shown in the first step 131 may be decreased from the magnitude of the current shown in the third step 133 .

In this case, the exponential function may mean a form in which a variable appears as a negative number.

The third step 133 may be a step in which the magnitude of the current reduced according to the second step 132 is maintained at a constant level, and in this case, the time interval during which the magnitude of the current is maintained in the third step 133 is the first In step 2 132 , the magnitude of the current may be set longer than the time interval during which it decreases.

In this case, it goes without saying that the magnitude of the current maintained in the third step 133 may be changed within a certain error range.

The fourth step 134 may be a step in which the magnitude of the current output from the controller 130 is reduced from the magnitude of the current output in the third step 133 to an initial value.

The form in which the magnitude of the current is decreased in the fourth step 134 is reduced from the magnitude of the current shown in the third step 133 to the magnitude of the current shown at the initial value according to a preset higher-order function. may be in the form of

In this regard, referring to FIG. 5A , the difference between the decrease in the current magnitude in the fourth step 134 and the decrease in the current magnitude in the first step 131 can be confirmed, but FIG. 5A is a diagram of the present invention. For understanding, it should be understood that some representations may appear in an ideal form, and such shapes, structures, and characteristics may be implemented in other embodiments without departing from the spirit and scope of the present invention.

On the other hand, in the fifth step 135, the magnitude of the current reduced to the initial value by the fourth step 134 is maintained, and when a new cycle is repeated, the first step 131 after a predetermined time interval can be performed again.

Referring to FIG. 5B , when the current moves from the working electrode 122 to the counter electrode 121 , the waveform of the current appearing in the electrode unit 120 can be confirmed.

Such a waveform may appear when the controller 130 outputs a current to the electrode unit 120 so that the current moves from the working electrode 122 to the counter electrode 121 in the inflammatory mode.

Meanwhile, referring to FIG. 5C , when the current moves from the counter electrode 121 to the working electrode 122 , the waveform of the current appearing in the electrode unit 120 can be checked.

Such a waveform may appear when the controller 130 outputs a current to the electrode unit 120 so that the current moves from the counter electrode 121 to the working electrode 122 in the proliferative mode or the mature mode.

It can be understood that the current waveform of the same frequency is inverted in FIGS. 5B and 5C, and this current is a current obtained by mixing an alternating current according to an action potential appearing in the muscle cell membrane in the body and a direct current of a preset size. I can understand.

Accordingly, it can be understood that the average value of the current shown in the graph by the direct current is not 0, and the current increases and decreases according to a constant frequency by the alternating current.

At this time, the frequency of the current may be the same as the frequency for the action potential appearing in the muscle cell membrane, and this frequency may be set in advance, and may be set to receive a frequency from the outside and output an AC component according to the frequency have.

For example, when the frequency of the action potential is 2 Hz, the frequency of the current measured by the electrode unit 120 may also appear as 2 Hz.

6A and 6B are graphs illustrating a change in voltage output to an electrode unit according to the control unit of FIG. 2 .

The control unit 130 controls the current so that the voltage difference value measured between the counter electrode 121 and the working electrode 122 is maintained at at least one of a preset inflammatory phase set voltage, a proliferative phase set voltage, and a mature stage set voltage. can do.

Referring to FIG. 6A , it can be confirmed that the magnitude of the voltage measured by the electrode unit 120 is measured in a low state compared with the voltage preset according to the control mode. It can be understood as increasing the magnitude of the current so that the magnitude is maintained at a voltage preset according to the control mode.

In addition, referring to FIG. 6B , it can be confirmed that the magnitude of the voltage measured by the electrode unit 120 is measured in a low state compared with the voltage preset according to the control mode, and accordingly, the control unit 130 It can be understood that the magnitude of the current is increased so that the magnitude of the voltage is maintained at a voltage preset according to the control mode.

On the other hand, it can be understood that the polarity of the electrode part 120 is opposite to that of FIG. 6B as compared to that of FIG. 6A , and accordingly, the voltage is measured as a negative value.

On the other hand, the magnitude of the voltage preset according to the control mode shown in FIGS. 6A and 6B is one of an impedance value or a phase angle value expressed as a ratio of the current output from the controller 130 and the voltage measured by the electrode part 120 . It may be set differently according to at least one value.

In this case, the controller 130 may set the preset voltage in the same control mode to include a plurality of different voltage values according to at least one of an impedance value and a phase angle value.

In other words, the control unit 130 controls the current so that the voltages measured by the electrode unit 120 are maintained at different levels according to at least one of impedance values and phase angle values of different magnitudes calculated in the same control mode. can do.

7 is a flowchart of a microcurrent stimulation method according to an embodiment of the present invention.

Since the microcurrent stimulation method according to an embodiment of the present invention proceeds in substantially the same configuration as the microcurrent stimulation apparatus 100 shown in FIG. 1, for the same components as the microcurrent stimulation apparatus 100 of FIG. The same reference numerals are given, and repeated descriptions will be omitted.

The microcurrent stimulation method may include receiving a control mode input (600), outputting a current (610), calculating an on-resistance value (620), and controlling the current value (630).

In step 600 of receiving the control mode input, the control mode indicating at least one element among the direction of the current and the range of the magnitude of the current may be received.

Here, the control mode may include at least one of an inflammatory phase mode, a proliferative phase mode, and a maturation phase mode that determines at least one of the direction of the output current and the magnitude range of the current.

The step of outputting current 610 is to the electrode unit 120 having a counter electrode 121 set to an arbitrary polarity and a working electrode 122 set to a polarity opposite to the polarity appearing in the counter electrode 121. According to the control mode, a current according to at least one of a direction of a current and a range of a magnitude of the current may be output.

The step of outputting the current 610 may output a current to the electrode unit 120 so that the current moves from the working electrode 122 to the counter electrode 121 in the inflammatory mode, which is the step of outputting the current ( In 610 , it can be understood that the working electrode 122 is set as an anode and the counter electrode 121 is set as a cathode.

In this case, the step of outputting the current 610 may control the current so that a voltage difference value measured between the counter electrode 121 and the working electrode 122 is maintained at a preset inflammatory stage voltage.

The step of outputting a current 610 may output a current to the electrode unit 120 so that the current moves from the counter electrode 121 to the working electrode 122 in the growth mode, which is the step of outputting the current ( It can be understood that in 610 , the working electrode 122 is set as a cathode and the counter electrode 121 is set as an anode.

In this case, in the step of outputting the current 610 , the current may be controlled so that a voltage difference value measured between the counter electrode 121 and the working electrode 122 is maintained at a preset multiplier set voltage.

The step of outputting a current 610 may output a current to the electrode unit 120 so that the current moves from the counter electrode 121 to the working electrode 122 in the mature mode, which is the step of outputting the current ( It can be understood that in 610 , the working electrode 122 is set as a cathode and the counter electrode 121 is set as an anode.

In this case, in the step of outputting the current 610 , the current may be controlled so that a voltage difference value measured between the counter electrode 121 and the working electrode 122 is maintained at a preset voltage for maturity.

In step 620 of calculating the on-resistance value, the counter electrode 121 and the working electrode 121 according to the voltage difference value between the counter electrode 121 and the working electrode 122 and the current value output in the step 610 of outputting the current At least one of an on-resistance value and a phase angle value between (122) may be calculated.

In operation 630 of controlling the current value, the current value output to the electrode unit 120 may be controlled according to at least one of an on-resistance value and a phase angle value.

In this case, in the step 630 of controlling the current value, when the on-resistance value is greater than a preset threshold on-resistance value, a preset threshold current may be output to the electrode unit 120 .

In addition, in the step 630 of controlling the current value, when the phase angle value is greater than a preset critical phase angle value, a preset threshold current may be output to the electrode unit 120 .

Although the above has been described with reference to the embodiments, those skilled in the art will understand that various modifications and changes can be made to the present invention without departing from the spirit and scope of the present invention as set forth in the following claims. will be able

100: microcurrent stimulation device
110: input unit
120: electrode part
121: counter electrode
122: working electrode

Claims (24)

an input unit receiving a control mode set according to at least one of a direction of a current and a range of a magnitude of the current;
an electrode unit including a counter electrode set to an arbitrary polarity and a working electrode set to a polarity opposite to a polarity appearing in the counter electrode; and
A control unit for outputting a current to the electrode unit such that the voltage appearing in the electrode unit appears in a preset waveform with respect to at least one element of the direction of the current and the magnitude range of the current according to the control mode;
The control mode is
Including an inflammatory phase mode, a proliferative phase mode, and a maturation phase mode for determining at least one element of a direction of a current output from the control unit and a magnitude range of the current,
The inflammatory mode is,
It is set to induce platelets and inflammatory cells in the wound site, the current is output to the electrode unit so that the current moves from the working electrode to the counter electrode, and the voltage difference value measured between the counter electrode and the working electrode is The current is controlled to be maintained at a preset inflammatory phase set voltage,
The proliferative mode is,
It is set to induce movement or proliferation of epithelial cells in the wound site and to induce fibrous production of fibroblasts present in the dermal layer, wherein a current is output to the electrode unit so that the current moves from the counter electrode to the working electrode, , the current is controlled so that a voltage difference value measured between the counter electrode and the working electrode is maintained at a preset multiplier set voltage,
The mature mode is,
It is set to induce extinction of the inflammatory cells and maturation of the flesh by the fibers, wherein a current is output to the electrode unit so that the current moves from the counter electrode to the working electrode, and between the counter electrode and the working electrode The microcurrent stimulation device, wherein the current is controlled so that the voltage difference value measured is maintained at a preset maturity set voltage.
delete delete delete delete According to claim 1, wherein the control unit,
calculating at least one of an on-resistance value and a phase angle value between the counter electrode and the working electrode according to a voltage difference value between the counter electrode and the working electrode and a current value output from the control unit,
A microcurrent stimulation device for controlling a current value output to the electrode unit according to at least one of the on-resistance value and the phase angle value.
According to claim 1, wherein the control unit,
A microcurrent stimulator for outputting a current so that the first to fifth steps representing the form of outputting the current according to the frequency of the current output to the electrode unit are sequentially repeated.
The method of claim 7, wherein the first step comprises:
The magnitude of the current output from the control unit is output according to a constant frequency to the magnitude of the current set in advance from the initial value, microcurrent stimulation device.
The method of claim 8, wherein the second step comprises:
The magnitude of the current output from the control unit decreases from the magnitude of the current output in the first step to a magnitude preset in the form of an exponential function for a predetermined time interval, the microcurrent stimulation device.
The method of claim 9, wherein the third step is
The amount of the reduced current according to the second step maintains a constant size, microcurrent stimulation device.
The method of claim 10, wherein the fourth step comprises:
The magnitude of the current output from the control unit is reduced to the initial value from the magnitude of the current output in the third step, microcurrent stimulation device.
The method of claim 11, wherein the fifth step
The magnitude of the current reduced to the initial value by the fourth step is maintained, the microcurrent stimulation device.
In the microcurrent stimulation method performed in a microcurrent stimulation device that outputs a microcurrent in consideration of on-resistance,
receiving a control mode indicating at least one of a direction of a current and a range of a magnitude of the current;
At least one element of the direction of the current and the range of the magnitude of the current according to the control mode, in an electrode part having a counter electrode set to an arbitrary polarity and a working electrode set to a polarity opposite to the polarity shown in the counter electrode outputting a current so that the voltage appearing in the electrode part appears in a preset waveform;
calculating an on-resistance value between the counter electrode and the working electrode according to a voltage difference value between the counter electrode and the working electrode and a current value output in the step of outputting the current; and
Controlling a current value output to the electrode unit according to the on-resistance value,
The control mode is
an inflammatory mode, a proliferative mode, and a maturation mode that determine at least one of a direction of the current and a range of magnitudes of the current;
The inflammatory mode is,
It is set to induce platelets and inflammatory cells in the wound site, the current is output to the electrode unit so that the current moves from the working electrode to the counter electrode, and the voltage difference value measured between the counter electrode and the working electrode is The current is controlled to be maintained at a preset inflammatory phase set voltage,
The proliferative mode is,
It is set to induce movement or proliferation of epithelial cells in the wound site and to induce fibrous production of fibroblasts present in the dermal layer, wherein a current is output to the electrode unit so that the current moves from the counter electrode to the working electrode, , the current is controlled so that a voltage difference value measured between the counter electrode and the working electrode is maintained at a preset multiplier set voltage,
The maturity mode is
It is set to induce extinction of the inflammatory cells and maturation of the flesh by the fibers, wherein a current is output to the electrode unit so that the current moves from the counter electrode to the working electrode, and between the counter electrode and the working electrode The method of claim 1, wherein the current is controlled so that the measured voltage difference value is maintained at a preset maturity setting voltage.
delete delete delete delete delete The method of claim 13, wherein the outputting of the current comprises:
A microcurrent stimulation method for outputting a current so that the first to fifth steps indicating a form of outputting a current according to the frequency of the current output to the electrode unit are sequentially repeated.
The method of claim 19, wherein the first step comprises:
The magnitude of the current output in the step of outputting the current is output according to a constant frequency from the initial value to the magnitude of the current set in advance, the microcurrent stimulation method.
The method of claim 20, wherein the second step comprises:
The magnitude of the current output from the step of outputting the current decreases from the magnitude of the current output in the first step to a magnitude preset in the form of an exponential function for a predetermined time interval, the microcurrent stimulation method.
The method of claim 21, wherein the third step comprises:
A microcurrent stimulation method in which the magnitude of the reduced current according to the second step maintains a constant magnitude.
23. The method of claim 22, wherein the fourth step comprises:
The amount of the current output in the step of outputting the current is reduced from the magnitude of the current output in the third step to an initial value, the microcurrent stimulation method.
The method of claim 23, wherein the fifth step
The magnitude of the current reduced to the initial value by the fourth step is maintained, the microcurrent stimulation method.

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