KR102556846B1 - Device that induces destroying cells on abnormally dividing cells and the driving method thereof - Google Patents

Abstract

The present invention is characterized by controlling the concentration or directing of an electric field to a specific target region where cancer cells or tumor cells exist, so that cancer cells, etc., do not completely divide and naturally die.

Description

Death induction device for abnormally dividing cells and its driving method {Device that induces destroying cells on abnormally dividing cells and the driving method thereof}

The present invention is characterized by intensively irradiating abnormally dividing cells with an electric field so as not to complete cell division, thereby inducing abnormally dividing cells to naturally die.

Cancer cells refer to cells that continuously and rapidly divide without stopping normal cells for any reason, and are also called malignant neoplasms or malignant tumors. In addition, these cancer cells damage the body and organs to prevent the human body from maintaining normal functions, and as a result, it is a scary disease that causes cancer patients to die. Existing methods for treating cancer cells or cancer include various treatment methods such as surgery, radiation therapy, and chemotherapy, and recently, immunotherapy and gene therapy have also been used. However, existing treatments such as radiation therapy and chemotherapy have a problem that destroys not only cancer cells but also surrounding normal cells, which can deteriorate the patient's health. there was.

Therefore, in the field of cancer treatment, new treatment or alleviation methods are continuously being researched and developed, and recently, a new cancer treatment method using an electric field has emerged. However, even in the case of using an electric field to kill cancer cells, which are abnormal cells that divide rapidly, there is a concern that the area to which the electric field is applied is quite wide, which can negatively affect even normal cells.

For reference, the above-mentioned background art is technical information that the inventor possessed for derivation of the present invention or acquired in the process of derivation of the present invention, and is not necessarily a known art disclosed to the general public prior to filing the present invention. It should be noted that there is no

The present invention has been made to solve the above problems, and an apparatus for inducing death of abnormally dividing cells in which an electric field can be focused or steered to a target region where rapidly dividing abnormally dividing cells, cancer cells exist, and its We want to provide a driving method.

In order to achieve the above object, in the present invention a first electrode array (array); a second electrode array; It provides a death induction device for abnormally dividing cells, characterized in that it includes; a power source for supplying power necessary for driving the first electrode array and the second electrode array.

In addition, the present invention is a first electrode array; a second electrode array; a power source supplying power to any one of the first electrode array and the second electrode array; A ground electrode connected to the electrode array to which the power source is not connected; provides an apoptosis induction device for abnormally dividing cells comprising a.

In addition, the power source provides an apoptosis inducing device for abnormally dividing cells, characterized in that for supplying alternating current power.

In addition, the abnormal division further comprises; a power regulator for adjusting the power supplied from the power source to be applied to the individual electrodes of the first electrode array and the individual electrodes of the second electrode array with phase differences. A death induction device for cells is provided.

In addition, the abnormal division further comprises; a power regulator for adjusting the power supplied from the power source to be applied to the individual electrodes of the first electrode array or the individual electrodes of the second electrode array with a phase difference. A death induction device for cells is provided.

In addition, the individual electrodes of the first electrode array are arranged in an i x j matrix, the individual electrodes of the second electrode array are arranged in an i x j matrix, and i and j are natural numbers. provides

In addition, by using the power supplied from the power source, an output signal obtained by synthesizing a modulation signal and a carrier signal is controlled to be applied to individual electrodes of the first electrode array and individual electrodes of the second electrode array. It provides a death inducing device for abnormal dividing cells, characterized in that it further comprises a; power regulator.

In addition, the output signal applied to the first electrode array and the output signal applied to the second electrode array provide a death induction device for abnormally dividing cells, characterized in that they have a phase difference of 180 degrees.

In addition, when a target area is located within a predetermined distance from the individual electrodes of the first electrode array and/or the second electrode array, the power regulator is an individual electrode closest to the target area. Applying the output signal to adjacent individual electrodes, and alternately applying the output signal to individual electrodes included in odd-numbered columns and individual electrodes included in even-numbered columns of the electrode array not including the nearest individual electrode Provided is a device for inducing apoptosis of abnormally dividing cells.

In addition, an apparatus for inducing death of abnormally dividing cells is provided, wherein the output signal is applied to individual electrodes adjacent to the closest individual electrode in the electrode array where the closest individual electrode is located.

In addition, when the target area is located outside a predetermined distance from the individual electrodes of the first electrode array and the second electrode array, the power regulator may set the individual electrodes of the first electrode array and the second electrode array in the same row and column position. A virtual line connecting the individual electrodes passing through the target area is selected as the X group and the Y group in the first electrode array and the second electrode array, respectively, and in the first electrode array in a clockwise direction from the X group The same number of individual electrodes as the number of individual electrodes of the X group are sequentially selected from the X+1 group to the X+n group, and in the second electrode array, the individual electrodes of the Y group in a counterclockwise direction from the Y group Individual electrodes of the same number as the number are sequentially selected from the Y + 1 group to the Y + n group, and the output signal is applied for a predetermined t time for each group from the X group to the X + n group to complete one cycle and completing one cycle by applying the output signal for the time t for each group from the Y group to the Y+n group.

In addition, all individual electrodes constituting the first electrode array receive the output signal more than once through one cycle, and all individual electrodes constituting the second electrode array receive the output signal more than once. Provided is a device for inducing apoptosis of abnormally dividing cells.

In addition, some of the individual electrodes overlap each other between adjacent groups in the X group to the X+n group, and some of the individual electrodes overlap each other between the adjacent groups in the Y group to the Y+n group. It provides a death induction device for abnormal dividing cells, characterized in that.

In addition, when the target area is located outside a predetermined distance from the individual electrodes of the first electrode array and the second electrode array, the power regulator connects each individual electrode of the second electrode array from the first electrode array. It provides an apoptosis inducing device for abnormally dividing cells, characterized in that for applying the output signal to individual electrodes through which the lines of the target area pass.

(

)이며, 상기 변조 신호는 온오프(on-off) 신호(

) 이며, 여기서

은

보다 작은 것을 특징으로 하는 비정상 분열 세포에 대한 사멸 유도 장치를 제공한다.In addition, the carrier signal is

(

), and the modulation signal is an on-off signal (

), where

silver

A death induction device for abnormally dividing cells characterized by a smaller size is provided.

In addition, the power regulator provides a death inducing device for abnormally dividing cells, characterized in that 0 volt is applied to individual electrodes to which the output signal is not applied.

In addition, the abnormal division further comprises; a power regulator for adjusting the power supplied from the power source to be applied to the individual electrodes of the first electrode array or the individual electrodes of the second electrode array with a phase difference. A death induction device for cells is provided.

In addition, the ground electrode is sequentially or non-sequentially connected to each of the individual electrodes of the electrode array to which the power source is not connected.

In addition, the power controller provides a death inducing device for abnormally dividing cells, characterized in that the phase difference is adjusted so that the electric field is concentrated or steered in a target region.

In addition, a death inducing device for abnormally dividing cells, characterized in that it further comprises; a target identifier for receiving information on the target region or identifying the target region.

In addition, the target area provides a death inducing device for abnormally dividing cells, characterized in that the area to be intensively irradiated with an electric field.

In addition, the target area provides a death inducing device for abnormally dividing cells, characterized in that the area to be intensively irradiated with an electric field.

In addition, the AC power source provides a death induction device for abnormally dividing cells, characterized in that it has a kilohertz (KHz) band frequency.

In addition, the AC power source provides a death induction device for abnormally dividing cells, characterized in that it has a frequency of 10 to 600 kilohertz.

In addition, the frequency of the AC power source provides a death induction device for abnormally dividing cells, characterized in that it can be set to a plurality of different frequencies.

In addition, the AC power source provides a death induction device for abnormally dividing cells, characterized in that switching (switching) the output state having a different frequency.

In addition, the output state provides a death inducing device for abnormally dividing cells, characterized in that lasting for 10 to 1000 milliseconds (ms).

In addition, the electric field strength of the electric field generated by the power source is 0.1 to 15 V / cm, characterized in that it provides a death induction device for abnormally dividing cells.

In addition, the present invention is applied to abnormally dividing cells characterized by including; applying power to individual electrodes of the first electrode array and individual electrodes of the second electrode array with a phase difference so that the electric field is concentrated or steered in the target region. It provides a method for driving a death induction device for

In addition, the present invention relates to an abnormally dividing cell comprising a step of applying an output signal obtained by synthesizing a modulation signal and a carrier signal to individual electrodes of the first electrode array and individual electrodes of the second electrode array. A method for driving a death induction device is provided.

In addition, the present invention includes the steps of confirming whether the target area is located at a predetermined distance from individual electrodes of the first electrode array and/or the second electrode array; applying an output signal obtained by synthesizing a modulation signal and a carrier signal to an individual electrode closest to the target region when the target region is located within a predetermined distance; applying the output signal to individual electrodes included in odd-numbered columns of the electrode array not including the nearest individual electrode, and not applying the output signal to individual electrodes included in even-numbered columns; and applying the output signal to individual electrodes included in even-numbered columns of the electrode array not including the nearest individual electrode, and not applying the output signal to individual electrodes included in odd-numbered columns. It provides a method for driving a death induction device for abnormally dividing cells.

In addition, the output signal applied to the first electrode array and the output signal applied to the second electrode array have a phase difference of 180 degrees.

In addition, after the step of checking whether the target area is located at a predetermined distance from the individual electrodes of the first electrode array and/or the second electrode array, if the target area is located outside the predetermined distance, the first electrode array and selecting individual electrodes in which an imaginary line connecting individual electrodes of the same row and column of the second electrode array passing through the target area are selected as X group and Y group respectively from the first electrode array and the second electrode array; sequentially selecting the same number of individual electrodes as the number of individual electrodes of the X group in a clockwise direction from the X group in the first electrode array from the X+1 group to the X+n group; sequentially selecting the same number of individual electrodes as the number of individual electrodes of the Y group from the Y group in the second electrode array in a counterclockwise direction from the Y+1 group to the Y+n group; applying the output signal for a predetermined time t for each group from the X group to the X+n group; It provides a method of driving a death induction device for abnormally dividing cells, comprising the step of applying the output signal for the time t to each group from the Y group to the Y+n group.

In addition, after the step of checking whether the target area is located at a predetermined distance from the individual electrodes of the first electrode array and/or the second electrode array, if the target area is located outside the predetermined distance, from the first electrode array Applying the output signal to individual electrodes through which an imaginary line connecting each individual electrode of the second electrode array passes through the target region; provides

(

)이며, 상기 변조 신호는 온오프(on-off) 신호(

) 이며, 여기서

은

보다 작은 것을 특징으로 하는 비정상 분열 세포에 대한 사멸 유도 장치의 구동 방법을 제공한다.In addition, the carrier signal is

(

), and the modulation signal is an on-off signal (

), where

silver

It provides a method for driving a death induction device for abnormally dividing cells, characterized in that they are smaller.

In addition, a method of driving a death induction device for abnormally dividing cells is provided, wherein 0 volt is applied to individual electrodes to which the output signal is not applied.

In addition, some of the individual electrodes overlap each other between adjacent groups in the X group to the X+n group, and some of the individual electrodes overlap each other between the adjacent groups in the Y group to the Y+n group. It provides a method of driving a death induction device for abnormal dividing cells, characterized in that.

In addition, the present invention includes the steps of applying power with a phase difference to either individual electrode of the first electrode array or the second electrode array so that the electric field is concentrated or steered in the target region; Connecting ground electrodes sequentially or non-sequentially to individual electrodes of an electrode array to which power is not applied; provides a method for driving a death induction device for abnormally dividing cells, characterized in that it is included.

In addition, before the step of applying power to the individual electrodes of the first electrode array and the individual electrodes of the second electrode array with a phase difference, receiving information on the target area or identifying the target area; further included It provides a method for driving a death induction device for abnormal dividing cells, characterized in that.

In addition, before the step of applying power to any one individual electrode of the first electrode array and the second electrode array with a phase difference, a step of receiving information on the target region or identifying the target region; further included It provides a method for driving a death induction device for abnormal dividing cells, characterized in that.

In addition, the power source provides a method of driving a death inducing device for abnormally dividing cells, characterized in that the AC power source.

In addition, the step of receiving information on the target region or identifying the target region provides a method of driving a death induction device for abnormally dividing cells, characterized in that the step is performed based on impedance information.

In addition, the AC power source provides a method for driving a death induction device for abnormally dividing cells, characterized in that it has a kilohertz frequency.

In addition, the AC power source provides a method of driving a death induction device for abnormally dividing cells, characterized in that it has a frequency of 10 to 600 kilohertz.

In addition, the frequency of the AC power source provides a method of driving a death inducing device for abnormally dividing cells, characterized in that it can be set to a plurality of different frequencies.

In addition, the AC power source provides a method of driving a death induction device for abnormally dividing cells, characterized in that for switching output states having different frequencies.

In addition, the output state provides a method of driving a death induction device for abnormally dividing cells, characterized in that lasting for 10 to 1000 milliseconds.

In addition, it provides a method of driving a death induction device for abnormally dividing cells, characterized in that the field strength of the electric field generated by the power source is 0.1 to 15 V / cm.

In addition, the present invention is a first electrode array (array); a second electrode array; a power source supplying power necessary for driving the first electrode array and the second electrode array; It provides a death inducing device for abnormally dividing cells comprising a; temperature measuring device.

In addition, the present invention is a first electrode array; a second electrode array; a power source supplying power to any one of the first electrode array and the second electrode array; a ground electrode connected to the electrode array to which the power source is not connected; It provides a death inducing device for abnormally dividing cells comprising a; temperature measuring device.

In addition, the power source provides an apoptosis inducing device for abnormally dividing cells, characterized in that for supplying alternating current power.

In addition, the abnormal division further comprises; a power regulator for adjusting the power supplied from the power source to be applied to the individual electrodes of the first electrode array and the individual electrodes of the second electrode array with phase differences. A death induction device for cells is provided.

In addition, the abnormal division further comprises; a power regulator for adjusting the power supplied from the power source to be applied to the individual electrodes of the first electrode array or the individual electrodes of the second electrode array with a phase difference. A death induction device for cells is provided.

In addition, the power controller provides a death inducing device for abnormally dividing cells, characterized in that the phase difference is adjusted so that the electric field is concentrated or steered in a target region.

In addition, a death inducing device for abnormally dividing cells, characterized in that it further comprises; a target identifier for receiving information on the target region or identifying the target region.

In addition, the target identifier provides an apparatus for inducing apoptosis of abnormally dividing cells, characterized in that the target region is identified based on impedance information.

In addition, the first electrode array is formed of a flexible material to have a shape corresponding to the contact surface, and the second electrode array is formed of a flexible material to have a shape corresponding to the contact surface. A death induction device for dividing cells is provided.

In addition, the AC power source provides a death induction device for abnormally dividing cells, characterized in that it has a megahertz (MHz) band frequency.

In addition, the AC power source provides a death inducing device for abnormally dividing cells, characterized in that it has a frequency of 1 to 25 megahertz.

Alternatively, when the temperature measured by the temperature measuring unit exceeds a predetermined temperature, the power supply of the power source is cut off to provide an apoptosis induction device for abnormally dividing cells.

In addition, the first electrode array is a capacitive coupling electrode, and the second electrode array is a capacitive coupling electrode to provide a death induction device for abnormally dividing cells, characterized in that.

In addition, the first electrode array is provided with an open space, and the second electrode array is provided with an apoptosis induction device for abnormally dividing cells, characterized in that the open space is provided.

In addition, the present invention includes the steps of applying power supplied from a power source to individual electrodes of the first electrode array and the second electrode array with a phase difference so that the electric field is concentrated or steered in the target region; It provides a method of driving a death inducing device for abnormally dividing cells, comprising the step of measuring the temperature around the first electrode array and/or the second electrode array.

In addition, the present invention includes the steps of applying the power supplied from the power source to any one individual electrode of the first electrode array and the second electrode array with a phase difference so that the electric field is concentrated or steered in the target region; sequentially or non-sequentially connecting ground electrodes to individual electrodes of the electrode array to which power is not applied; It provides a method for driving a death induction device for abnormally dividing cells, characterized in that it includes; measuring the temperature around the first electrode array and/or the second electrode array.

In addition, before the step of applying the power supplied from the power source to the individual electrodes of the first electrode array and the second electrode array with a phase difference by the power regulator so that the electric field is concentrated or steered in the target area, the target identifier is applied to the target area. It provides a method for driving a death induction device for abnormally dividing cells, further comprising: receiving information about or identifying the target region.

In addition, before the step of applying the power supplied from the power source to any one of the individual electrodes of the first electrode array and the second electrode array with a phase difference between the power controller so that the electric field is concentrated or steered in the target region, the target identifier A method for driving an apoptosis induction device for abnormally dividing cells, further comprising receiving information on a target region or identifying the target region.

In addition, the power source provides a method of driving a death inducing device for abnormally dividing cells, characterized in that the AC power source.

In addition, the step of receiving information on the target region by the target identifier or identifying the target region provides a method of driving an apoptosis induction device for abnormally dividing cells, characterized in that the step of identifying the target region is performed based on impedance information.

In addition, the first electrode array is formed of a flexible material to have a shape corresponding to the contact surface, and the second electrode array is formed of a flexible material to have a shape corresponding to the contact surface. A method for driving a death induction device for dividing cells is provided.

In addition, the AC power source provides a method of driving a death induction device for abnormally dividing cells, characterized in that it has a megahertz band frequency.

In addition, the AC power source provides a method of driving a death induction device for abnormally dividing cells, characterized in that it has a frequency of 1 to 25 megahertz.

In addition, after the step of measuring the temperature around the first electrode array and/or the second electrode array, when the measured temperature exceeds a predetermined temperature, the temperature is supplied to the first electrode array and/or the second electrode array. It provides a method for driving a death induction device for abnormally dividing cells, characterized in that it further comprises.

In addition, the first electrode array is a capacitive coupling electrode, and the second electrode array is a capacitive coupling electrode.

In addition, the first electrode array is provided with an open space, and the second electrode array is provided with a method of driving a death inducing device for abnormally dividing cells, characterized in that the open space is provided.

According to the device for inducing death of abnormally dividing cells and the method for driving the same according to the present invention, the following effects are obtained.

First, since cancer cells and tumor cells that divide abnormally quickly are intensively irradiated with an electric field to induce death, negative effects on normal cells can be minimized.

Second, since the electric field can be intensively irradiated to a region where cancer cells or tumor cells exist, the time for applying the electric field to the human body can be improved for a longer period of time.

Third, since the electric field can be steered or concentrated in the target area, there is an effect of reducing the amount of electric energy used as a whole.

Fourth, through an embodiment in which AC power of various frequency bands is applied, an effect capable of responding to abnormally dividing cells in various ways in various ways can be expected.

Fifth, by adjusting the selection pattern of the individual electrodes to which the output signal is to be applied in the first electrode array and/or the second electrode array, the direction and concentration of the electric field from near the skin to the depth of the body can be freely adjusted. .

1 is a diagram showing an example of a conventional cancer treatment device using an electric field.
Figure 2 is a view showing the inside of a cell during cell division.
Figure 3 is an enlarged view showing the attachment of spindle fibers to centromeres of chromosomes.
4 is an enlarged view of cells in the late stage of cell division.
FIG. 5 is a schematic diagram showing the area affected by an electric field in a conventional apparatus for treating cancer cells by applying an electric field.
6 is a diagram schematically showing how an electric field is concentrated in an electrode array of an apoptosis induction device for abnormally dividing cells according to the present invention.
Figure 7 is a view schematically showing the appearance of a modified electrode array of the death induction device for abnormal dividing cells according to the present invention.
Figure 8 is a view showing how the present invention having a modified electrode array is applied to the human body.
FIG. 9 is a view showing a process in which an electric field is steered in an electrode array of an apoptosis induction device for abnormally dividing cells according to the present invention.
FIG. 10 is a view showing the process of concentrating an electric field through an electrode array of the death induction device for abnormally dividing cells according to the present invention.
Figure 11 is a diagram schematically showing a death induction device for abnormal dividing cells according to the present invention.
FIG. 12 is a view schematically summarizing the configuration of a modified embodiment of an apoptosis induction device for abnormal dividing cells according to the present invention.
FIG. 13 is a view showing how the directionality of an electric field concentrated in a target area is changed in the present invention according to a modified embodiment.
FIG. 14 is a diagram briefly showing the principle of changing the directionality of an electric field concentrated in a target region in the present invention according to a modified embodiment.
15 is a flowchart showing a method of driving a killing device for abnormally dividing cells according to the present invention.
16 is a flowchart illustrating a method of driving a killing device for abnormally dividing cells according to a modified embodiment.
FIG. 17 is a more enlarged view of the electrode array portion in FIG. 11. Referring to FIG.
FIG. 18 is a diagram showing a case where a target area exists close to the first electrode array or the second electrode array.
FIG. 19 is a diagram schematically showing the operation of the first electrode array and the second electrode array for applying an electric field to a target region near the body surface.
Figure 20 is a diagram schematically showing the operation of the first electrode array and the second electrode array for applying an electric field to a target area near the body surface.
Figure 21 is a view showing a state when a target area exists deep in the body.
FIG. 22 is a diagram showing how individual electrodes to be activated are selected in correspondence to a target region existing inside the body.
FIG. 23 is an enlarged view of individual electrode regions activated in the first electrode array of FIG. 22 .
FIG. 24 is a view showing how individual electrodes activated in the first electrode array and the second electrode array change in order to change the direction of an electric field applied to a target region existing inside the body.
Figure 25 is a flow chart showing another driving method of the death induction device for abnormally dividing cells according to the present invention.
Figure 26 is a flow chart showing another driving method of the death induction device for abnormally dividing cells according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. Since the present invention can have various changes and various forms, specific embodiments are illustrated in the drawings and described in detail in the text. However, it should be understood that this is not intended to limit the present invention to the specific disclosed form, and includes all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

In addition, terms such as “first” and “second” in the description of the present invention are used only for the purpose of distinguishing one component from another, and are not used to limit any meaning. In addition, singular expressions include plural expressions unless the context clearly indicates otherwise, and terms such as “include” or “have” refer to features, numbers, steps, operations, components, parts, or the like described in the specification. It is intended to specify that a combination thereof exists, but it should be understood that it does not preclude the possibility of existence or addition of one or more other features, numbers, steps, operations, components, parts, or combinations thereof.

1 is a diagram showing an example of a conventional cancer treatment device using an electric field.

In a conventional cancer treatment device using an electric field, an electrode plate 20 capable of applying an electric field is attached to a part of the human body 10 where cancer cells exist, and an electric field is applied to the cancer cells through the electrode plate 20. Thus, the cancer cells that are constantly dividing are unable to complete division and self-destruct. Typically, a pair of electrode plates 20 are attached to the front and back of the area to be irradiated, and AC power is applied through these electrode plates 20 to generate an electric field, and the alternating electric field causes abnormally fast division. Cancer cells, which are abnormal cells, do not complete division and die. The principle of death of abnormally dividing cells according to the application of an electric field will be examined in more detail through the following drawings.

2 to 4 are views explaining the principle of inducing the death of abnormally dividing cells using an electric field. First, FIG. 2 is a view showing the inside of a cell during cell division.

When the division of the cell 50 begins, the nuclear membrane and phosphorus disappear, and the chromosomes 30 in a state in which two chromatids are linked to the centromere 31 are arranged in the center of the cell. Then, the spindle thread 40 comes out from the centriole and is attached to the centromere 31. In the case of mitosis, the copied chromatids are separated from each other and move away from each other in opposite directions from the equatorial plane, the cytoplasm is divided and the cell membrane is closed, thereby completing cell division. For reference, FIG. 3 is an enlarged view showing how the spindle thread 40 is attached to the centromere 31 of the chromosome 30 in this way.

However, compared to normal cells, cancer cells and tumor cells do not stop dividing, but also divide abnormally quickly. A cancer treatment device using an electric field makes use of such a rapid division characteristic of cancer cells so that the division process of cancer cells is not completed, so that they naturally die. Specifically, the spindle thread 40 grows by a polymerization reaction in which GTP (Guanosine Triphosphate) dimers having high affinity for microtubule ends are converted into GDP (Guasnosine diphosphate) dimers. The growing part is not only very unstable, but also has a polarity, so that microtubules cannot continuously grow and disintegrate and disappear in the presence of a continuously changing electric field. As a result, since the chromatids cannot move in opposite directions, cell division is not completed and death occurs. And, this effect by the alternating electric field has a greater effect on cancer cells and tumor cells, which divide faster than normal cells.

4 is an enlarged view of cells in the late stage of cell division.

After the movement of the chromatids in opposite directions by the spindle 40 is completed, the cell membrane of the cell 50 begins to invade. Invasion of the cell membrane is achieved by constriction rings of actin, myosin, central spindle, etc. formed under the cell membrane.

However, when an electric field is introduced into the dividing cell 50, more lines of electric force pass through the invaginated part of the cell membrane than other parts of the cell, forming a non-homogeneous electric field region within the cell 50. Due to this, the portion where the cell membrane is indented becomes polarized, and many bipolar materials such as nuclei present in the cell 50 gather in the cell membrane indented. In more detail, in the region of an electric field applied parallel to the long axis of the dividing cell, electric force lines are concentrated at the part where the cell membrane is invaginated, and as a result, electric polarity is generated, and bipolar materials are gathered in the part of the cell membrane that is invaginated or indented. It will be. Therefore, the cell membrane of the dividing cell does not close, and as a result, the cell 50 dies. That is, the method of killing cancer cells using an electric field prevents the formation of the spindle thread 40 in the cell through the application of an alternating electric field, and at the same time causes the dipole material to gather around the indented cell membrane to close the cell membrane. It causes cells to die through interfering effects.

FIG. 5 is a schematic diagram showing the area affected by an electric field in a conventional apparatus for treating cancer cells by applying an electric field.

A treatment method for cancer cells that divide abnormally quickly compared to normal cells using an electric field is known as a treatment method that is more stable than existing cancer treatment methods and can guarantee a normal life of a patient. FIG. Shows the patient being treated.

In order to treat cancer cells present in the portion marked 'C' in the drawing, a conventional apparatus for treating cancer cells by applying an electric field places electrode plates 20 in pairs at the portion where cancer cells exist, and then applies an electric field will authorize For example, as shown in FIG. 5 , an electric field may be applied by attaching electrode plates 20 to both sides of the chest in order to treat cancer cell tissue existing in the lung. However, as can be seen from the drawing, it can be confirmed that the area where the cancer cell tissue is present is very small, whereas the area of the electric field induced through the pair of electrode plates 20 is very wide. Although the alternating electric field has a greater effect on the death of rapidly dividing abnormal cells than normal cells, when the electric field is irradiated in such a wide range, it also has a negative effect on normal cells. Therefore, it is necessary to keep the area affected by the applied electric field narrow only to the target area where cancer cells exist. And, the present invention aims to achieve this by adjusting the phase difference of the power applied to the individual electrodes of the first electrode array and the second electrode array.

FIG. 6 is a diagram schematically showing how an electric field is concentrated in the electrode array of the death induction device for abnormal dividing cells according to the present invention, and FIG. 7 is a modified electrode of the death inducing device for abnormal dividing cells according to the present invention. It is a view schematically showing the appearance of the array, and FIG. 8 is a view showing the state in which the present invention having a modified electrode array is applied to the human body.

When the power supplied from the power source 200 is applied to the individual electrodes P of the first electrode array 110 and the second electrode array 120 with a phase difference, the electric field is directed in a certain direction. In the case of the drawing, the electric field is concentrated in the target region (T). Directing the electric field in a certain direction or concentrating on a certain area in this way is called beam forming or beam focusing. The electric field is focused on the targeted target area. While beamforming or beam focusing is usually performed in case of mobile communication to efficiently use limited frequency resources, an apparatus for inducing apoptosis of abnormally dividing cells and a method for driving the same according to the present invention are in the target region where cancer cells exist. Beam forming and beam focusing are performed so that the electric field is concentrated on .

In the present invention, the electrode array can be deformed to have a corresponding shape so as to adhere to a specific part of the body. FIG. 7 shows the second electrode array 120 deformed to have a hemispherical shape. As shown in FIG. 8, the electrode array having a hemispherical shape can be usefully used to treat cancer cell tissue ('C' in the drawing) formed in a woman's breast. For reference, by using the electrode array deformed into a hemispherical shape, since the focus of the electrode is concentrated in a certain area, the electric field can be more efficiently concentrated on the target area T.

Figure 9 is a view showing the process of steering the electric field in the electrode array of the death induction device for abnormal dividing cells according to the present invention, Figure 10 shows the process in which the electric field is steered through the electrode array of the death induction device for abnormal dividing cells according to the present invention It is a diagram showing the process of concentrating.

The apparatus for inducing death of abnormally dividing cells according to the present invention includes an electrode array composed of a plurality of individual electrodes, and by controlling the phase difference of signals or power applied to individual electrodes of the electrode array, the electric field becomes specific as shown in FIG. It is directed in the direction or focused as shown in Figure 10.

Therefore, the apparatus for inducing death of abnormally dividing cells according to the present invention and the method for driving the same can only kill rapidly dividing cancer cells by the effect of an electric field, while minimizing the effect of the electric field on surrounding normal cells.

Figure 11 is a diagram schematically showing a death induction device for abnormal dividing cells according to the present invention.

The death induction device for abnormal dividing cells according to the present invention may include a first electrode array 110, a second electrode array 120, a power source 200, and a power source 200, and furthermore, a power regulator 300 , a temperature measuring device 500, a target identifier 400, and the like may be further provided. More specifically, the first electrode array 110 and the second electrode array 120 are electrodes formed by gathering a plurality of individual electrodes P, and play a role in irradiating an electric field to a subject, more specifically, the human body 10. carry out To this end, the first electrode array 110 and the second electrode array 120 may be formed of capacitive coupling electrodes. In addition, the power source 200 serves to provide power necessary for driving the first electrode array 110 and the second electrode array 120, and the power regulator 300 transmits power to the target area of the electric field described above. For concentration, the phase difference of the power supplied from the power source 200 may be adjusted and supplied to individual electrodes of the first electrode array 110 and individual electrodes of the second electrode array 120 . In addition, the temperature measuring device 500 measures the temperature around the first electrode array 110 and the second electrode array 120 so that the first electrode array 110 and/or the second electrode array ( 120), and the target identifier 400 selects a target area where the electric field should be concentrated based on the impedance of the area to which the electric field is irradiated or received from the outside. can play a role in identification.

In the death inducing device for abnormally dividing cells according to the present invention, the power source 200 supplies AC power in the kilohertz (kHz) band, which is the most effective medium frequency band for killing dividing cells, specifically, 10 to 600 kilohertz. It supplies AC power with a frequency of Hertz. However, it is not limited thereto, and AC power having a frequency of 1 to 25 megahertz may be supplied. In addition to this, the power source 200 may supply power of any one fixed frequency, but may also supply AC power of a plurality of different frequencies, switching output states having these different frequencies and controlling Power may be supplied to the first electrode array 110 and the second electrode array 120 . Alternatively, the power source 200 may supply DC power. For reference, the switched output state can last for 10 to 1000 milliseconds (ms), and effects that can respond to abnormally dividing cells in various ways can be expected through the application of AC power in various frequency bands. In addition, an electric field having an electric field strength of 0.1 to 15 V/cm may be generated in a subject between the first electrode array 110 and the second electrode array 120 due to the application of the AC power.

Through this configuration, the device for inducing death of abnormally dividing cells according to the present invention induces death by intensively irradiating abnormally rapidly dividing cancer cells and tumor cells with an electric field, and can minimize negative effects on normal cells. it works

FIG. 12 is a view schematically summarizing the configuration of a modified embodiment of a death induction device for abnormal dividing cells according to the present invention, and FIG. It is a drawing showing the

The death induction device for abnormal dividing cells according to the modified embodiment has a difference in that it additionally has a ground electrode 700 compared to the previous embodiment and in its detailed connection method, which is different from the previous embodiment. In comparison, the driving method is as follows.

First, in the embodiment of FIG. 11 , AC power supplied from the power source 200 is applied to the first electrode array 110 and the second electrode array 120 . That is, in order to concentrate or direct the electric field to the target area, it is applied to the individual electrodes of the electrode array with a phase difference through the power regulator 300, but when the first electrode array 110 becomes (+), the second electrode When the array 120 becomes (-) and the first electrode array 110 becomes (-), AC power is directly applied in such a way that the second electrode array 120 becomes (+). In contrast, in the device for inducing death of abnormally dividing cells according to a modified embodiment, AC power is applied to either one of the first electrode array 110 and the second electrode array 120, and the electrode array not selected here is grounded. Electrodes 700 are connected. In addition, the directivity of the electric field applied to the target region is adjusted by adjusting the individual electrodes P of the electrode array to which the ground electrode 700 is connected. In summary, in the embodiment of FIG. 11, since the polarity of the power supplied to the first electrode array 110 and the second electrode array 120 changes, the directionality of the electric field naturally changes, but the modified embodiment of FIG. 12 shows a communication antenna. There is a difference in that the beam is formed or focused on the target area as described above, and the direction of the concentrated electric or magnetic field is changed by adjusting the connection between the individual electrodes P of the electrode array and the ground electrode 700. For reference, the first electrode array 110 and/or the second electrode array 120 capacitively coupled to the human body 10 may be formed of a flexible material to have a shape corresponding to the contact surface, and At the same time, an open space may be provided so that moisture emitted from the human body 10 can escape.

FIG. 14 is a diagram briefly showing the principle of changing the directionality of an electric field concentrated in a target region in the present invention according to a modified embodiment.

Referring to the drawing, AC power is applied to the individual electrodes P of the first electrode array 110 with phase differences, so that an electric field is formed in a target region, which is an area to be intensively irradiated. While the electric field is concentrated in the target area, the ground electrode 700 is sequentially or non-sequentially changed and connected to the individual electrodes P of the second electrode array 120. As a result, the electric field or magnetic field concentrated in the target area is connected. direction will change. As a result, rapidly and abnormally dividing cells in the target region die without completing division due to interference with the formation of spindle threads 40 or invagination of the cell membrane. For reference, the figure shows that the connection of the ground is changed sequentially from the individual electrode at the top right of the second electrode array 120 down thereto. And, in a modified embodiment of the present invention, the ground electrode 700 may refer to a reference electrode in a power system different from the power supplied from the power source 200 .

15 is a flowchart showing a method of driving a killing device for abnormally dividing cells according to the present invention.

First, in the death induction device for abnormal dividing cells according to the present invention, the target identifier 400 detects the target region based on impedance change information in a subject or receives information about a target region where an electric or magnetic field should be concentrated from the outside. An identification process may be performed (S15-1). Next, in order to concentrate the electric field on this target area, AC power from the power source 200 passes through the power regulator 300 to the individual electrodes P of the first electrode array 110 and the second electrode array 120. A process of applying a phase difference to the fields may be performed (S15-2). While performing this process, the temperature measuring device 500 measures the temperature around the first electrode array 110 or the second electrode array 120 (S15-3), when the measured temperature exceeds a preset temperature. (S15-4), the power supplied from the power source 200 to the first electrode array 110 and/or the second electrode array 120 is cut off to prevent high heat from being generated in the human body 10 as a subject. It can be done (S15-5).

The driving method of the death induction device for abnormally dividing cells according to the present invention can achieve an effect of increasing the time for applying an electric field or a magnetic field to the human body 10 for a longer time through this driving method. .

16 is a flowchart illustrating a method of driving a killing device for abnormally dividing cells according to a modified embodiment.

In a method of driving a death inducing device for abnormal dividing cells according to a modified embodiment, after receiving or identifying location information on a target region through the target identifier 400 (S16-1), an electric field or AC power supplied from the power source 200 may be applied to either individual electrode of the first electrode array 110 or the second electrode array 120 with a delay so that the magnetic field is concentrated on the target area (S16 -2). Next, a process of changing the directionality of the electric field or magnetic field concentrated in the target area by sequentially or non-sequentially connecting the ground electrode 700 to the individual electrodes P of the electrode array to which AC power is not supplied may be performed. Yes (S16-3). While the process of irradiating the electric field to the subject is performed, the process of measuring the temperature around the first electrode array 110 and/or the second electrode array 120 may be performed through the temperature measuring device 500 ( S16-4), when the measured temperature exceeds the predetermined temperature (S16-5), a process of cutting off the power supplied to the electrode array may be performed (S16-6). For reference, the step of measuring the temperature through the temperature measuring device 500 may be performed simultaneously or first with other processes in which an electric field is applied to the subject through the first electrode array 110 and/or the second electrode array 120. It should be noted that there is no need to necessarily perform any step first.

FIG. 17 is a more enlarged view of the electrode array portion in FIG. 11. Referring to FIG.

, (

)이고, 변조 신호는 온오프(on-off) 신호(

)로서

은

보다 작을 수 있다. (A는 신호의 크기, t는 시간, f는 주파수,

는 위상을 의미) 참고로, i는 행을 가르키는 자연수, j는 열을 가르키는 자연수일 수 있으며, 도면에서 'M'은 제1 전극 어레이(110)와 제2 전극 어레이(120) 사이에 배치되는 신체 또는 세포 조직을 모식적으로 표현하여 나타낸 것일 수 있다.In the death induction device for abnormal dividing cells according to the present invention, the first electrode array 110 and the second electrode array 120 in the form of patches attached to both ends of the body are individually arranged in an ixj matrix as shown in the drawing. It may be composed of electrodes P, and an output signal generated by the power regulator 300 using power supplied from the power source 200 may be applied to these individual electrodes. Also, there may be a phase difference of 180 degrees between the output signal applied to the individual electrodes P of the first electrode array 110 and the output signal applied to the individual electrodes P of the second electrode array 120. . Here, the output signal may be a combination of a carrier signal and a modulated signal, and the carrier signal is

, (

), and the modulation signal is an on-off signal (

)as

silver

may be smaller than (A is the magnitude of the signal, t is time, f is frequency,

means a phase) For reference, i may be a natural number indicating a row, j may be a natural number indicating a column, and 'M' in the drawing is between the first electrode array 110 and the second electrode array 120. It may be shown by schematically expressing the body or cell tissue to be placed.

The apparatus for inducing death of abnormally dividing cells according to the present invention applies an alternating output signal to the first electrode array 110 and the second electrode array 120 to apply an electric field into the body or tissue to abnormally divide. cause cells to die naturally.

FIG. 18 is a diagram showing a case where a target area exists close to the first electrode array or the second electrode array.

In the first electrode array 110 and the second electrode array 120 of FIG. 17 described above, the individual electrodes P to which the output signal is applied and the individual electrodes P to which the ground or 0 volt (V) is applied are connected. By selecting, the present invention can adjust the directionality of the electric field applied from the first electrode array 110 and/or the second electrode array 120 to the body, tissue, and the like. In addition, the concentration of the electric field applied to the cancer cell tissue (C) can also be adjusted.

The part where the cancer cell tissue C can be located in the body can be divided into a case where it is located outside the body, that is, close to the skin, and a case where it is located deep inside the body. And, from the point of view of the first electrode array 110 and the second electrode array 120 attached to the body, the presence of cancer cell tissue C on the body surface means that the cancer cell tissue C or the target area ( T) means that it is within a predetermined distance (D) from the first electrode array 110 or the second electrode array 120, and being located inside the body means that the cancer cell tissue (C) or the target area (T) It may mean that it is outside a predetermined distance (D) from the first electrode array 110 or the second electrode array 120 . Here, the predetermined distance may be 1 to 3 centimeters (cm).

Hereinafter, when a target region (T) specific to cancer cell tissue (C) is present within a predetermined distance (D) from the first electrode array 110 or the second electrode array 120 through the drawings, each individual electrode Let's take a look at how the output signal is applied to (P).

19 and 20 are diagrams schematically showing the operation of the first electrode array and the second electrode array for applying an electric field to a target area near the body surface.

In the death induction device for abnormal dividing cells according to the present invention, the individual electrode P of the first electrode array 110 closest to the target region T is selected as the closest individual electrode SP, An output signal may be applied to the nearest individual electrode SP of the one-electrode array 110 . And, to the second electrode array 120, as shown in FIG. 19, output signals may be applied to individual electrodes P included in odd-numbered columns. Therefore, an electric field is applied between the closest individual electrode SP of the first electrode array 110 and the individual electrode P activated in the second electrode array 120, and as a result, the electric field in the target region T It can be seen that is concentrated, and the electric field of the remaining part is widely spread.

Thereafter, the death induction device for abnormally dividing cells according to the present invention can change the activated individual electrodes of the second electrode array 120 from odd-numbered rows to even-numbered rows as shown in FIG. 20, through which the electric field in the target region T remains concentrated, but the electric field in the remaining part maintains a wide spread state as it moves from the previously irradiated area to other areas. In addition, the individual electrodes P activated in the second electrode array 120 may periodically change from odd-numbered columns to even-numbered columns and from even-numbered columns to odd-numbered columns at regular intervals.

Through this driving method, the death induction device for abnormally dividing cells according to the present invention concentrates an electric field on the cells in the target region (T), where tumors, cancer cells, etc. exist, and naturally rapidly dies by the alternating electric field. It is possible to achieve an effect capable of inducing , and at the same time, an effect capable of minimizing the effect of the electric field on cells other than the target region T.

18 to 20 show a driving method when a target area T exists adjacent to the first electrode array 110, on the contrary, within a predetermined distance D from the second electrode array 120. In this case, the opposite operation can be performed similarly. That is, an individual electrode having the closest distance from the second electrode array 120 to the target area is selected as the nearest individual electrode SP, and odd columns and even columns of the first electrode array 110 are alternately activated. can also be driven. Also, in the electrode array including the nearest individual electrode SP, the output signal may also be applied to individual electrodes adjacent to the nearest individual electrode SP.

For reference, in the figure, the electric field applied between the first electrode array 110 and the second electrode array 120 is briefly indicated by 'EL', and the individual electrodes activated by the application of the output signal are different from other individual electrodes. Otherwise, the inside is marked black.

FIG. 21 is a diagram showing a state when a target region exists deep in the body, and FIG. 22 is a diagram showing a state in which individual electrodes to be activated are selected in response to a target region existing inside the body.

When the target area T on which the electric field should be concentrated exists deep in the body, the target area T is positioned outside a predetermined distance D from both the first electrode array 110 and the second electrode array 120 do.

In this case, the death induction device for abnormally dividing cells according to the present invention does not select the closest individual electrode from the first electrode array 110 or the second electrode array 120 to the target region T, An imaginary line connecting individual electrodes in the same row and column position of the first electrode array 110 and the second electrode array 120 groups the individual electrodes passing through the target area T to form an X group, You can select the method of applying the output signal by selecting the Y group. Referring to the drawing, in FIG. 22, individual electrodes P included in the first electrode array 110 form an X group in a rectangle indicated by a dotted line, and individual electrodes P included in the second electrode array 120 are They can be grouped into Y groups.

FIG. 23 is an enlarged view of individual electrode regions activated in the first electrode array of FIG. 22 .

In the drawing, an imaginary line connecting individual electrodes of the same row and column position of the first electrode array 110 and the second electrode array 120 is located in the first electrode array 110 among the individual electrodes passing through the target area T. It shows that 9 individual electrodes are selected as the X group and the output signal is applied. The reason why a plurality of individual electrodes are selected and grouped in this way is that the electric field reaching the target region (T), where the cancer cell tissue (C) is designated, is deeper, the weaker the electric field. It is also to apply an electric field as much as the intensity to the target region (T).

When the individual electrodes grouped in the X group are selected in the first electrode array 110 in this way, the same number of individual electrodes clockwise from the X group in the first electrode array 110 sequentially from the X+1 group to the X+n group. The process of grouping into . And, in the second electrode array 120, a process of sequentially grouping the same number of individual electrodes from the Y group in a counterclockwise direction from Y+1 to Y+n groups is performed. In this process, some of the individual electrodes P may overlap and be grouped between adjacent groups. In addition, all individual electrodes P constituting the first electrode array 110 and the second electrode array 120 may belong to one or more groups without exception.

FIG. 24 is a view showing how individual electrodes activated in the first electrode array and the second electrode array change in order to change the direction of an electric field applied to a target region existing inside the body.

22 and 23, after the X group is selected in the first electrode array 110 and the Y group is selected in the second electrode array 120, in the first electrode array 110, based on the X group In the clockwise direction, the same number of individual electrodes are sequentially selected from the X+1 group to the X+n group, and in the second electrode array 120, the same number of individual electrodes in the counterclockwise direction based on the Y group is Y+1 After being sequentially selected from the group to the Y+n group, a process of applying an output signal for each group for a predetermined time period t may be performed. Here, activation from the start group to the last group can be expressed as one cycle being completed.

Looking through the figure, after output signals are input to the X group and the Y group and an electric field is applied to the target region T for time t, in the first electrode array 110, the X+1 group in the clockwise direction is selected, In the second electrode array 120, the Y+1 group in the counterclockwise direction may be selected and an output signal may be input. For reference, the output signal applied to the first electrode array 110 and the second electrode array 120 is a combination of a modulation signal and a carrier signal, and may have a phase difference of 180 degrees.

In this way, after the output signal is applied to the X + 1 group and the Y + 1 group for a preset time t, continuously, in the first electrode array 110, the X + 2 group, the X + 3 group, and the X + 4 group An output signal may be applied while transitioning, and in the second electrode array 120, an output signal may be applied while transitioning to the Y+2 group, the Y+3 group, and the Y+4 group. When the output signal is applied according to the group of individual electrodes that change in this way, it can be seen that the electric field is continuously irradiated in a dense manner in the target target region T, but the electric field is widely dispersed in time except for the target region. That is, assuming that the magnitude of the electric field applied for a predetermined time t is A, in the case of FIG. only experience

Therefore, death can be induced by intensively irradiating the electric field only to the target region T where cancer cells and tumor cells exist, and negative effects can be minimized in the region where other normal cells exist.

Here, the individual electrodes of the first electrode array 110 and the second electrode array 120 are all grouped into five groups, but this is only an example, and the first electrode array 110 and the second electrode array 120 are The number of groups may vary according to the number of individual electrodes.

Figure 25 is a flow chart showing another driving method of the death induction device for abnormally dividing cells according to the present invention.

First, another driving method of the death induction device for abnormally dividing cells according to the present invention can be performed from the process of identifying the target region (T) to be irradiated by concentrating the electric field (S25-1). After the target region T is identified in this way, a process in which an output signal obtained by synthesizing a modulation signal and a carrier signal is applied to the first electrode array 110 and the second electrode array 120 with a phase difference of 180 degrees may be performed. Yes (S25-2). And, while the electric field is being applied to the target region T through the first electrode array 110 and the second electrode array 120, the death induction device for abnormally dividing cells according to the present invention first A process of measuring the temperature around the electrode array 110 and/or the second electrode array 120 may be performed (S25-3). Here, when the measured temperature exceeds the predetermined temperature (S25-4), by cutting off the power supplied to the first electrode array 110 and / or the second electrode array 120 (S25-5), the target Cells in the area where the electric field is irradiated, including the area T, are prevented from experiencing thermal damage.

For reference, in the description of the present invention, an activated individual electrode refers to an individual electrode to which an output signal is applied, and a deactivated individual electrode refers to an individual electrode to which an output signal is not applied or to which a ground or 0 volt is applied. may be pointing

Figure 26 is a flow chart showing another driving method of the death induction device for abnormally dividing cells according to the present invention.

According to another driving method of the death induction device for abnormal dividing cells according to the present invention, when the target region T is identified (S26-1), the target region T is connected to the first electrode array 110 and/or the second electrode array 110. It is checked whether it is located at a predetermined distance from the electrode array 120 (S26-2), and if it is located within the predetermined distance, a process of applying an output signal to the nearest individual electrode may be performed (S26-3). ). Then, a process of applying an output signal to individual electrodes included in even columns of the electrode array not including the nearest individual electrode SP (S26-4), and applying an output signal to individual electrodes included in odd columns The process (S26-5) may be performed alternately. Here, even-numbered columns need not necessarily be activated first and odd-numbered columns activated next, and the order may be reversed.

If the target area T is outside the predetermined distance, the death induction device for abnormally dividing cells according to the present invention uses individual electrodes in the same row position of the first electrode array 110 and the second electrode array 120. An imaginary line connecting individual electrodes passing through the target area T is selected as an X group and a Y group, respectively (S26-6), and based on this, in the first electrode array 110, individual electrodes P are rotated in a clockwise direction. Groups X+1,..., X+n are selected to be included without omission, and groups Y+1,...,Y+n can be selected in a counterclockwise direction in the second electrode array 120.

After the grouping of the individual electrodes of the first electrode array 110 and the second electrode array 120 is completed, an output signal obtained by synthesizing the modulation signal and the carrier signal for a predetermined time t from the X group to the X + n group is applied (S26-9), and an output signal having a phase difference of 180 degrees is applied from the Y group to the Y+n group during the same time period to complete one cycle (S26-10). Here, the process of applying the output signal to the X groups and the process of applying the output signal to the Y groups are described as different steps in the flowchart for convenience of notation, but are performed simultaneously.

Next, the death induction device for abnormally dividing cells according to the present invention performs a process of checking whether the temperature around the first electrode array 110 or the second electrode array 120 exceeds a preset temperature ( S26-11), when the temperature exceeds the predetermined temperature, the power applied to the first electrode array 110 or the second electrode array 120 is cut off so that the area including the target area T is irradiated with an electric field. Cells can be prevented from thermal damage.

Through this process, the death induction device for abnormally dividing cells according to the present invention can intensively irradiate the electric field to the region where cancer cells or tumor cells exist, and can minimize the effect of the electric field on the remaining regions.

As described above, although it has been described with reference to the preferred embodiments of the present invention, those skilled in the art will variously modify the present invention within the scope not departing from the spirit and scope of the present invention described in the claims below. And it will be understood that it can be changed.

10: human body
20: electrode plate
30: chromosome
31: centromere
40: spindle
50: cell
110: first electrode array
120: second electrode array
200: power source
300: power regulator
400: target identifier
500: temperature meter
700: ground electrode

Claims (48)

a first electrode array;
a second electrode array;
a power source supplying power necessary for driving the first electrode array and the second electrode array;
A power source that adjusts an output signal obtained by synthesizing a modulation signal and a carrier signal to be applied to individual electrodes of the first electrode array and the individual electrodes of the second electrode array by using the power supplied from the power source. Including a controller;
The individual electrodes of the first electrode array are arranged in an ixj matrix,
The individual electrodes of the second electrode array are arranged in an ixj matrix,
i, j are natural numbers,
The power regulator
When a target area is located within a predetermined distance from individual electrodes of the first electrode array or the second electrode array,
Applying the output signal to an individual electrode closest to the target area, which is the closest individual electrode;
The death induction device for abnormal dividing cells, characterized in that the output signal is alternately applied to individual electrodes included in odd columns and individual electrodes included in even columns of the electrode array not including the closest individual electrode.
a first electrode array;
a second electrode array;
a power source supplying power to any one of the first electrode array and the second electrode array;
a ground electrode connected to the electrode array to which the power source is not connected;
A power source that adjusts an output signal obtained by synthesizing a modulation signal and a carrier signal to be applied to individual electrodes of the first electrode array and the individual electrodes of the second electrode array by using the power supplied from the power source. Including a controller;
The individual electrodes of the first electrode array are arranged in an ixj matrix,
The individual electrodes of the second electrode array are arranged in an ixj matrix,
i, j are natural numbers,
The power regulator
When a target area is located within a predetermined distance from individual electrodes of the first electrode array or the second electrode array,
Applying the output signal to an individual electrode closest to the target area, which is the closest individual electrode;
The death induction device for abnormal dividing cells, characterized in that the output signal is alternately applied to individual electrodes included in odd columns and individual electrodes included in even columns of the electrode array not including the closest individual electrode.
According to claim 1 or 2,
The power source is a death induction device for abnormal dividing cells, characterized in that for supplying alternating current power.
According to claim 1 or 2,
The death induction device for abnormally dividing cells, characterized in that the power regulator adjusts the output signal to be applied to individual electrodes of the first electrode array and individual electrodes of the second electrode array with a phase difference.
According to claim 1 or 2,
The power regulator controls the output signal to be applied to the individual electrodes of the first electrode array and the individual electrodes of the second electrode array with a phase difference of 180 degrees.
According to claim 1 or 2,
Wherein the power regulator controls the output signal to be applied to individual electrodes adjacent to the closest individual electrode in the electrode array where the closest individual electrode is located.
According to claim 1,
The power regulator
When the target area is located outside a predetermined distance from the individual electrodes of the first electrode array and the second electrode array,
An imaginary line connecting individual electrodes of the same row and column position of the first electrode array and the second electrode array passes through the target area, and the individual electrodes are grouped in X group and Y group in the first electrode array and the second electrode array, respectively. to select,
In the first electrode array, the same number of individual electrodes as the number of individual electrodes in the X group is sequentially selected from the X + 1 group to the X + n group in a clockwise direction from the X group,
In the second electrode array, in a counterclockwise direction from the Y group, the same number of individual electrodes as the number of individual electrodes in the Y group is sequentially selected from the Y+1 group to the Y+n group,
Applying the output signal for a predetermined time t for each group from the X group to the X+n group to complete one cycle;
Apparatus for inducing death of abnormally dividing cells, characterized in that one cycle is completed by applying the output signal for the time t for each group from the Y group to the Y + n group.
According to claim 7,
Through one cycle, all individual electrodes constituting the first electrode array are applied with the output signal one or more times,
Death inducing device for abnormal dividing cells, characterized in that all individual electrodes constituting the second electrode array receive the output signal at least once.
According to claim 7,
Some of the individual electrodes overlap each other between adjacent groups in the X group to the X + n group,
A death induction device for abnormal dividing cells, characterized in that some of the individual electrodes overlap each other between the groups adjacent to the Y group to the Y + n group.
According to claim 1,
The power regulator
When the target area is located outside a predetermined distance from the individual electrodes of the first electrode array and the second electrode array,
A death induction device for abnormally dividing cells, characterized in that the imaginary line connecting each individual electrode of the second electrode array from the first electrode array applies the output signal to individual electrodes passing through the target area.
According to claim 1,
The carrier signal is , ( ), and
The modulation signal is an on-off signal ( ), and
here silver A death inducing device for abnormally dividing cells, characterized in that they are smaller.
According to claim 1,
The power regulator
Death induction device for abnormal dividing cells, characterized in that 0 volt (volt) is applied to individual electrodes to which the output signal is not applied.
According to claim 2,
The ground electrode is
Death inducing device for abnormal dividing cells, characterized in that sequentially or non-sequentially connected to each of the individual electrodes of the electrode array to which the power source is not connected.
According to claim 1 or 2,
The power regulator is a death induction device for abnormal dividing cells, characterized in that for adjusting the phase difference so that the electric field is concentrated or steered in a target region.
According to claim 1,
The apparatus for inducing apoptosis for abnormally dividing cells, further comprising: a target identifier for receiving information on the target region or identifying the target region.
According to claim 15,
The target area is a death induction device for abnormally dividing cells, characterized in that the area to be intensively irradiated with an electric field.
According to claim 1,
The target area is a death induction device for abnormally dividing cells, characterized in that the area to be intensively irradiated with an electric field.
According to claim 10,
The target area is a death induction device for abnormally dividing cells, characterized in that the area to be intensively irradiated with an electric field.
According to claim 3,
The AC power source is a death inducing device for abnormally dividing cells, characterized in that it has a kilohertz (KHz) band frequency.
According to claim 3,
The AC power supply has a frequency of 10 to 600 kilohertz, characterized in that the death induction device for abnormal dividing cells.
According to claim 3,
The frequency of the AC power supply is a death induction device for abnormal dividing cells, characterized in that can be set to a plurality of different frequencies.
According to claim 21,
The AC power supply is a death induction device for abnormal dividing cells, characterized in that for switching (switching) the output state having a different frequency.
The method of claim 22,
The death induction device for abnormally dividing cells, characterized in that the output state lasts for 10 to 1000 milliseconds (ms).
According to claim 1 or 2,
The electric field intensity of the electric field generated by the power source is 0.1 to 15 V / cm, characterized in that the death induction device for abnormally dividing cells.
checking whether the target area is located at a predetermined distance from individual electrodes of the first electrode array or the second electrode array;
applying an output signal obtained by synthesizing a modulation signal and a carrier signal to an individual electrode closest to the target region using power supplied from a power source when the target region is located within a preset distance;
applying the output signal to individual electrodes included in odd-numbered columns of the electrode array not including the nearest individual electrode, and not applying the output signal to individual electrodes included in even-numbered columns;
Applying the output signal to individual electrodes included in even-numbered columns of the electrode array not including the nearest individual electrode, and not applying the output signal to individual electrodes included in odd-numbered columns; characterized in that it includes A method for driving a death inducing device for abnormally dividing cells.
According to claim 25,
The method of driving a death induction device for abnormally dividing cells, characterized in that the output signal applied to the first electrode array and the output signal applied to the second electrode array have a phase difference of 180 degrees.
According to claim 25,
The method of driving a death induction device for abnormally dividing cells, characterized in that the output signal applied to the first electrode array and the output signal applied to the second electrode array have a phase difference.
According to claim 25,
After the step of confirming whether the target area is located at a predetermined distance from the individual electrodes of the first electrode array or the second electrode array,
When the target area is located outside the predetermined distance, a virtual line connecting individual electrodes in the same row and column position of the first electrode array and the second electrode array passes through the target area, and the individual electrodes pass through the first electrode array, the selecting the X group and the Y group from the second electrode array;
sequentially selecting the same number of individual electrodes as the number of individual electrodes of the X group in a clockwise direction from the X group in the first electrode array from the X+1 group to the X+n group;
sequentially selecting the same number of individual electrodes as the number of individual electrodes of the Y group from the Y group in the second electrode array in a counterclockwise direction from the Y+1 group to the Y+n group;
applying the output signal for a predetermined time t for each group from the X group to the X+n group;
and applying the output signal for the time t to each group from the Y group to the Y+n group.
According to claim 25,
After the step of confirming whether the target area is located at a predetermined distance from the individual electrodes of the first electrode array or the second electrode array,
Applying the output signal to individual electrodes through which a virtual line connecting each individual electrode of the second electrode array from the first electrode array passes through the target area when the target area is located outside a predetermined distance; A method of driving a death inducing device for abnormal dividing cells, characterized in that it is included.
According to claim 25,
The carrier signal is , ( ), and
The modulation signal is an on-off signal ( ), and
here silver A method of driving a death induction device for abnormal dividing cells, characterized in that they are smaller.
According to claim 25,
A method of driving a death induction device for abnormally dividing cells, characterized in that 0 volt is applied to individual electrodes to which the output signal is not applied.
According to claim 28,
Some of the individual electrodes overlap each other between adjacent groups in the X group to the X + n group,
A method of driving a death induction device for abnormally dividing cells, characterized in that some of the individual electrodes overlap each other between adjacent groups in the Y group to the Y + n group.
According to claim 25,
A method of driving a death induction device for abnormally dividing cells, characterized in that ground electrodes are sequentially or non-sequentially connected to individual electrodes to which the output signal is not applied.
According to claim 25,
Prior to the step of confirming whether the target area is located at a predetermined distance from the individual electrodes of the first electrode array or the second electrode array,
Receiving information on the target region or identifying the target region; The driving method of the apoptosis induction device for abnormally dividing cells, characterized in that it further comprises.
According to claim 25,
The method of driving a death induction device for abnormal dividing cells, characterized in that the power source is an alternating current power source.
35. The method of claim 34,
The step of receiving information about the target area or identifying the target area
A method of driving a death induction device for abnormally dividing cells, characterized in that made on the basis of impedance information.
The method of claim 35,
The AC power source is a method of driving a death induction device for abnormal dividing cells, characterized in that having a kilohertz frequency.
The method of claim 35,
The method of driving the death induction device for abnormal dividing cells, characterized in that the AC power source has a frequency of 10 to 600 kilohertz.
The method of claim 35,
A method of driving a death induction device for abnormally dividing cells, characterized in that the frequency of the AC power source can be set to a plurality of different frequencies.
The method of claim 39,
The AC power source is a method of driving a death induction device for abnormally dividing cells, characterized in that for switching output states having different frequencies.
41. The method of claim 40,
The method of driving a death induction device for abnormally dividing cells, characterized in that the output state lasts for 10 to 1000 milliseconds.
According to claim 25,
The electric field strength of the electric field generated by the power source is 0.1 to 15 V / cm.
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