KR102312773B1 - High frequency treatment device based on power value difference based control - Google Patents

Abstract

The present invention measures the difference value (P1-P2) of the active electrode power value (P1) and the current value (P2) of the return electrode when the current value varies, and the difference power value (P1-P2) It relates to a high-frequency electrotherapy device and a treatment method capable of inducing effective treatment and treatment by controlling the frequency output appropriate to the affected part of a patient by calculating an impedance value, comprising: a high-frequency energy generator for generating high-frequency energy; An electrode unit including an active electrode and a return electrode for receiving the high frequency energy of which the output is controlled from the high frequency energy control unit and the high frequency energy control unit for controlling the output of the generated high frequency energy, and injecting the high frequency energy into the affected area when in contact with the affected area , an active electrode voltage current detector for measuring the voltage value (V1) and the current value (I1) of the active electrode, and a voltage value (V2) for the return electrode and a return electrode voltage current detector for measuring the current value (I2). .

Description

High frequency treatment device by power value difference-based control {HIGH FREQUENCY TREATMENT DEVICE BASED ON POWER VALUE DIFFERENCE BASED CONTROL}

The present invention relates to a high frequency treatment device by controlling the difference in power value, and more particularly, the difference value (P1-) between the power value of the active electrode (P1) and the power value (P2) of the return electrode when the current value is variable. By measuring P2) and calculating the impedance value of the affected area according to the difference power value (P1-P2), the frequency output appropriate to the affected area of the patient is controlled to induce effective treatment and treatment. It is about a treatment device.

The basis of the electrosurgical principle lies in the basic electrical concepts, namely current, voltage, electric circuit, and impedance (resistance). Electrical flow, or current, is the flow of a negative charge along an electrical circuit formed by a path (path) with minimal resistance from one atom to another, going to a neutral ground state. Impedance (ohms) is a measure of resistance to current. The product of current (I) and voltage (V) is power (p) in watts. Only when the voltage, which is the driving force of the current, is up to 200 (peak voltage, Vp), that is, when the voltage spike exceeds 200, the density of current sufficient for electrical cutting in living tissue can be produced. Some electrosurgical devices ensure that the voltage is always kept below 200 Vp, regardless of the power level, in which case only tissue coagulation occurs and tissue cutting cannot be performed regardless of the power level. do. This is often denoted as 'soft coaguation' in unipolar circuits and is also characteristic of bipolar circuit devices. Voltages above 200 Vp can produce sufficient current density for electrical tissue cleavage and overcome tissue impedance to achieve tissue coagulation to deeper regions.

Ultimately, the effect or change of tissue to be treated with an electrosurgical device is determined by the current density. The density of these currents is affected by several variables. Some of these parameters may be adjusted by the user of the electrosurgical instrument and some may not be adjusted by the user's intention. One of the latter is tissue impedance, which greatly depends on the composition of the tissue in a specific area (the area to be treated), that is, the water content. For example, in the case of a tissue containing a lot of water, such as blood or the intestinal wall, the impedance is low and the resistance to the flow of electric current is less than that of fat or bone. Increasing the fibrosis and reactive impedance at the base of the peptic ulcer, eventually requiring higher power to achieve the desired tissue effect.

In addition to the composition of the tissue, the amount of tissue to be treated is also important. If the tissue to be treated is energized at once, if the amount of tissue is large, the current density will be lowered, and consequently the heating rate will be slow. In addition, it may vary depending on the shape and size of the appendage that conducts electricity. In the case of an appendage with a broad end of a ball type or a flat-shaped forceps jaw, the density of current will be low because current flows into the tissue through a wide electrode, Conversely, in the case of a relatively sharp and narrow tip such as a snare or a sphincter incision, the current density will be high because the current flows to the tissue through the narrow electrode area. Thus, the former promotes coagulation and the latter promotes cleavage.

Some recent devices (eg ErbeEndocut, Erbe, Marietta, GA and ValleyLab Instant Response, Valleylab, Boulder, CO) allow for highly selective, specialized microprocessor-controlled electrical supply.

Among them, the ‘Endocut’ method has the function of quickly adjusting the voltage in response to the changing impedance of the tissue, and controlling the speed of tissue cutting based on the intermittent or wave output. The ‘Instant Response’ method in the cutting method has the function of supplying the selected power very quickly when the tissue impedance is low at the time of cutting, and then maintaining the power constant regardless of the change in impedance. In order to make the best use of these functions, it is important to understand the intention of the mode well and apply it to the appropriate procedure.

An object of the present invention is to measure the power value (active power value and return power value) of the affected part when the current value varies in the patient procedure using high frequency, and the impedance value of the affected part using the difference value of the measured power value To provide a high-frequency electrotherapy device that can be operated by controlling a high-frequency value suitable for the condition of the affected part by calculating .

The present invention for achieving the above object relates to a high frequency electric therapy device for treating an affected part by applying a high frequency to a patient's body when the current value is variable,

High-frequency energy generating unit for generating high-frequency energy, a high-frequency energy control unit for controlling the output of high-frequency energy generated by the high-frequency energy generating unit, and receiving the high-frequency energy with the output adjusted from the high-frequency energy control unit, when in contact with the affected area, the affected area An electrode part including an active electrode and a return electrode to which high-frequency energy is applied, an active electrode voltage current detector measuring the voltage value (V1) and current value (I1) of the active electrode, and a voltage value (V2) of the return electrode It may include a return electrode voltage and current detector for measuring I2).

In addition, the high frequency energy control unit, based on the voltage value (V1) and the current value (I1) of the active electrode measured by the active electrode voltage and current detection unit, the power value (P1) of the active electrode, and the active power value (P1) And measuring the power (P2) of the return electrode based on the current value (I2), the impedance value of the affected part calculated using the difference value (P1-P2) between the active power value and the return power value (Z = (P1) -P2) The output of high frequency energy can be controlled according to X (V1-V2)²).

In addition, the high frequency energy control unit, when the difference value (P1-P2) or the calculated impedance value of the affected part is the same as a predetermined reference value, or is greater than the reference value, it can control the high frequency energy input by controlling the high frequency energy generation unit have.

In addition, the preferred frequency value of the reference value or the calculated impedance value may be any one or more high frequency values of 100 kHz, 250 kHz, 400 kHz, 500 kHz, 1 MHz, and 5 MHz.

On the other hand, in the present invention, when the current value varies, the voltage/current value of the active electrode and the voltage/current value of the return electrode are detected in the affected part of the patient, and the difference value of the power value is used by the detected voltage/current value to calculate the impedance value of the affected part, and apply effective high-frequency energy by the calculated impedance value to treat and treat the affected part of the patient Step, calculating the difference value (P1-P2) between the active power (P1) and the return power (P2) using the voltage/current values of the measured active electrode and the return power, the calculated difference value (P1-P2) It may include calculating the impedance value of the affected part using the and controlling the output of high frequency energy by the calculated impedance value.

In addition, when the difference value (P1-P2) or the calculated impedance value between the calculated active power (P1) and the return power (P2) is equal to or greater than a preset reference value, the output of high-frequency energy is stopped. can

In addition, the preferred frequency value of the reference value or the calculated impedance value may be any one or more high frequency values of 100 kHz, 250 kHz, 400 kHz, 500 kHz, 1 MHz, and 5 MHz.

The present invention calculates the impedance of the affected area by measuring the difference in the power value of the affected area, and by controlling the output of the high frequency input to the affected area according to the calculated value, by injecting the most suitable high frequency according to the condition of the affected area, treatment and treatment There are advantages to being effective.

1 is a configuration diagram showing the configuration of a high-frequency electrotherapy apparatus according to an embodiment of the present invention;
2 is a flowchart illustrating a radiofrequency treatment method according to a preferred embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to describing the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, a detailed description thereof will be omitted.

In addition, in the present invention, high frequency refers to a radio transmission frequency (300 kHz to 1,200 kHz) in a dictionary meaning. However, for therapeutic purposes, RF means high-frequency current. In general commercial AC electricity, the number of alternating + and - changes is 60 times per second (60Hz), but to use it for treatment, an AC current of 03Mhz to several tens of Mhz is required. In other words, when high-frequency electricity is applied to living tissue, the ions in the cells move back and forth from the cathode to the anode, generating enormous frictional heat by itself.

1 is a configuration diagram showing the configuration of a high-frequency electrotherapy apparatus according to an embodiment of the present invention.

Referring to FIG. 1 , the present invention includes a high-frequency energy generator 100 for generating high-frequency energy, a high-frequency energy controller 200 for controlling the output of the high-frequency energy generated by the high-frequency energy generator 100, and the high-frequency energy The electrode unit 300 including the active electrode 310 and the return electrode 320 for receiving the high-frequency energy of which the output is controlled from the control unit 200 and applying the high-frequency energy to the affected area when it is in contact with the affected area, the active A voltage/current detector comprising an active electrode voltage/current detector 410 for measuring the voltage/current value of the electrode 310 and a return electrode voltage/current detector 420 for measuring the voltage/current value of the return electrode ( 400) may be included.

The high frequency energy generating unit 100 may generate a high frequency required to operate on the affected part of the patient.

The high-frequency energy control unit 200 may adjust the output of the high-frequency energy generated by the high-frequency energy generator 100 to suit the patient's condition.

The electrode unit 300 is in contact with the affected area to inject high-frequency energy, and may be configured in various forms depending on the patient's affected area and surgical conditions.

Meanwhile, the electrode unit 300 may include an active electrode 310 and a return electrode 320 , and the active electrode 310 and the return electrode 320 may deliver high-frequency energy into the tissue of the affected area.

The voltage/current detection unit 400 includes an active electrode voltage/current detection unit 410 for measuring the voltage/current value of the active electrode, and a return electrode voltage/current detection unit 420 for measuring the voltage/current value of the return electrode. can do.

That is, when the current value is variable, the voltage/current detector 400 measures the voltage/current values of the active electrode 310 and the return electrode 320 to measure the high-frequency output of the high-frequency energy controller 200 described above. It provides information necessary to measure the impedance value of the affected area to be controlled. This is because the impedance value of the affected area varies depending on the condition of the affected area, that is, the condition of the affected area before the high frequency injection is not large due to blood and moisture (P1), but as the high frequency is injected into the affected area, the affected area is heated. As it solidifies, the impedance value becomes larger than before the high frequency input (P2). (Z=(P1-P2) X (V1-V2)²)

Therefore, the control unit that calculates the impedance value by using the voltage / current value of the active electrode of the affected part and the voltage / current value difference value of the return electrode, the impedance value of the affected part reaches a predetermined therapeutic impedance value (reference value) In this case, by controlling the output frequency value of the high frequency to adjust the output of the high frequency injected into the affected area, it is possible to inject the most suitable high frequency for the treatment and treatment of the affected area.

For example, when the current value is variable, the high frequency energy control unit may include a voltage value (V1) and a current value (I1) of the active electrode measured by the active electrode voltage/current detector 410, and the return electrode voltage/ Active power and return power values and their difference values (P1-P2) are calculated based on the return electrode voltage value (V2) and the current value (I2) measured by the current detector 420, and the impedance is determined by the calculated difference value By calculating a change in the value of can detect the state of the affected part, it is possible to control the high frequency output that is most suitable for the state of the affected part.

In addition, the high frequency energy control unit 200, the difference value (P1-P2) between the voltage/current value P1 of the active electrode 310 and the voltage/current value P2 of the reflective electrode 320 is predetermined When it is equal to or greater than the reference value, the high frequency energy generator 100 may be controlled to stop the high frequency energy output.

The reference value is a high frequency energy value calculated by an experiment, and a preferable frequency value may include any one or more of 100 kHz, 250 kHz, 400 kHz, 500 kHz, 1 MHz, and 5 MHz. This is to prevent medical accidents caused by excessive high-frequency output.

2 is a flowchart illustrating a radiofrequency treatment method according to a preferred embodiment of the present invention.

Referring to FIG. 2 , in the present invention, first, the active electrode value and the voltage/current value of the return electrode are measured in the affected part of the patient (S500), and a difference value between the measured values is calculated (S510). In addition, the active power P1 and the return power value P2 and the difference values P1-P2 are calculated based on the detected voltage/current values (S520).

Then, the impedance value is calculated using the calculated power value (Z=(P1-P1) X (V1-V2)²) (S530), and effective high-frequency energy is applied by the calculated impedance value to the affected part of the patient can be treated and treated.

That is, the present invention comprises the steps of measuring the voltage/current values of the active electrode and the return electrode of the affected part of the patient (S500), and calculating the difference value of the voltage/current values of the measured active electrode and the return electrode (S510). , using the voltage / current value of the active electrode and the return electrode of the affected part, calculating the difference value between the active power (P1) and the regression power (P2) and the active power (P1) and the regression power (P2) There is (S520).

In addition, it may include calculating the impedance value of the affected part using the calculated active / regression voltage, current and power value (S530), and controlling the output of high frequency energy by the calculated impedance value (S550) .

In particular, when the calculated power values P1 and P2 or the impedance value Z is equal to or greater than a preset reference value, the output of high frequency energy may be controlled ( S540 ).

The frequency value of the preset reference value may be set to any one or more high frequency values among 100 kHz, 250 kHz, 400 kHz, 500 kHz, 1 MHz, and 5 MHz. This is to prevent medical accidents caused by excessive high-frequency output.

The best embodiment has been disclosed in the drawings and the specification above, and the terms used here are only used for the purpose of describing the present invention, and are used to limit the meaning or the scope of the present invention described in the claims. no. Therefore, various modifications and equivalent other embodiments will be possible therefrom by those skilled in the art, and therefore, the true technical protection scope of the present invention should be defined by the technical spirit of the appended claims.

100: high frequency energy generation unit 200: high frequency energy control unit
300: electrode 310: active electrode
320: return electrode 400: voltage detection unit
410: active electrode voltage / current detection unit
420: return electrode voltage / current detection unit

Claims (7)

It relates to a high frequency electric therapy device for treating an affected area by applying a high frequency to a patient's body when the current value is variable,
a high-frequency energy generator for generating high-frequency energy;
a high-frequency energy control unit for controlling an output of the high-frequency energy generated by the high-frequency energy generator;
An electrode unit including an active electrode and a return electrode for receiving the high-frequency energy of which the output is controlled from the high-frequency energy control unit, and applying the high-frequency energy to the affected area when in contact with the affected area;
an active electrode voltage and current detector for measuring a voltage value (V1) and a current value (I1) of the active electrode; and
A return electrode voltage and current detector for measuring the voltage value (V2) and the current value (I2) of the return electrode,
The high frequency energy control unit,
Based on the voltage value (V1) and the current value (I1) of the active electrode measured by the active electrode voltage and current detection unit, the power value (P1) of the active electrode, the return electrode voltage value (V2), and the current value (I2) Measure the power (P2) of the return electrode based on
Control the output of high frequency energy according to the impedance value (Z = (P1-P2) X (V1-V2)²) of the affected part calculated using the difference value (P1-P2) of the active power value and the regression power value, and , When the difference value (P1-P2) or the calculated impedance value of the affected part is equal to or greater than a predetermined reference value, the high frequency treatment device, characterized in that the high frequency energy generator is controlled to stop the high frequency energy input . delete delete According to claim 1,
The frequency value of the reference value or the calculated impedance value is 100 kHz, 250 kHz, 400 kHz, 500 kHz, 1 MHz, 5 MHz, characterized in that any one or more high-frequency values of the power value difference based control high-frequency treatment device . delete delete delete

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