KR100503882B1 - Electrochemical Therapy Equipment - Google Patents

Abstract

It is an object of the present invention to generate an electrochemical and electrobiological response by inducing a DC current in the interior of the treatment device to be proportional to the size of the tumor and inducing the tumor of the cancer, thereby killing the cancer cells and reducing the size of the tumor. The treatment device of the present invention provides a main control unit for calculating the inputted parameter values using an internal arithmetic processing circuit; A storage unit connected to the main control unit and storing various programs and data; An input unit and an output unit connected to the main control unit and configured to include a keyboard for inputting the parameter values, a monitor for outputting a result, and a print; A converter for converting the digital values output through the arithmetic processing circuit into analog values or converting analog values into digital values; An output driver for rectifying an alternating current applied through a power supply into a direct current, and connected to the converter to amplify or reduce values of voltage and current; And an electrode part separated into a plus pole and a minus pole and connected to the main body of the treatment device through an interface, and allowing a direct current to flow between the plus pole and the minus pole inserted into the treatment part.

Description

Electrochemical Therapy Equipment

The present invention relates to a medical device, and more particularly to an electrochemical cancer treatment device for treating various tumors by using an electrochemical method.

In general, a medical device is a generic term for devices and tools that normally treat damaged body parts using tools employing mechanical, electrical or chemical methods.

Cancer is a terrible disease that threatens the health of modern people. It is a terrible disease in which normal cells are destroyed by mutations or proliferation of cells.

As a method for treating a tumor of cancer, a surgical method of resecting the tumor, a method of destroying tissue by irradiating the tumor, and a method of necroticting cancer cells by administering an anticancer agent are widely used.

Surgical methods for resecting tumors are a definite treatment for early cancer tumors, but there are risks for malignant tumors. Radiation or chemotherapy is effective for early cancer tumors but does not respond to malignancies. Many, especially because the patient's immunity is weakened because the body is weak, there is a problem that can not be applied to the weak patients.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-described problems, and its object is to appropriately control the amount of charge and current intensity of DC current according to the amount of the amount of the cancer and induce an electrochemical and electrobiological reaction by inducing an electrochemical and electrobiological reaction by inducing the cancer cells. It is to provide an electrochemical treatment device that necrosis and reduce the size of the tumor.

In order to achieve the above object of the present invention, the treatment unit of the present invention includes a main control unit for calculating an input parameter value using an operation processing circuit therein; A storage unit connected to the main control unit and storing various programs and data; An input unit and an output unit connected to the main control unit and configured to include a keyboard for inputting the parameter values, a monitor for outputting a result, and a print; A converter for converting the digital values output through the arithmetic processing circuit into analog values or converting analog values into digital values; An output driver for rectifying an alternating current applied through a power supply into a direct current, and connected to the converter to amplify or reduce values of voltage and current; And an electrode part separated into a plus pole and a minus pole and connected to the main body of the treatment device through an interface, and allowing a direct current to flow between the plus pole and the minus pole inserted into the treatment part.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. 1 is a block diagram showing the configuration of a treatment device according to the present invention.

The treatment device of the present invention, a main control unit 1, a storage unit 3 connected to the main control unit 1 for storing various programs and data, a keyboard and a monitor connected through the interface 5 of the treatment unit main body, An input unit 7 and an output unit 9 composed of a print, a digital analog conversion circuit (hereinafter referred to as a D / A conversion circuit) for converting a digital signal into an analog signal, and an analog to digital conversion for converting an analog signal into a digital signal. A conversion section 11 composed of a circuit (hereinafter referred to as an A / D conversion circuit), a connection section 13 connecting the conversion section 11 and the main control section 1, and an alternating current applied through a power supply section PW. An output driver 15 for rectifying the current into a direct current, an electrode unit 17 connected to the main body of the treatment device through an interface and making direct contact with the treatment unit, and a sensing for sensing an output voltage or an output current applied to the electrode Part 19 and applied to the electrode The protection unit 21 detects the current to prevent the overcurrent is induced to the patient, and automatically detects and forcibly cuts off the overvoltage current, and a warning unit 23 for warning the occurrence of an overcurrent or an open state due to a short between the electrodes. It includes.

Here, the main controller 1 controls the converter 11, the detector 19, the protector 21, the output driver 15, and the like through the parameters input through the input unit 7. The operation processing circuit operates on the parameter values input by the keyboard.

The storage section 3 includes a storage circuit employing a magnetic recording method, in which an operation control program is stored. In other words, the operation control program is a program that configures the software, such as a chart explanation program that shows the use process, a program that can explain the effects of the clinical use in a chart, an injection simulation program, a history management program, a result input program, and an expert guidance program. It is built.

Among the software stored in the storage unit 3, the table description program provides related information to the users in a medium such as a figure, such as a verification evaluation, a brief introduction of the program, a pathology description, and an operation description. In particular, a program that can graphically explain the effect of use during clinical trials can reveal a few treatment cases and provide relevant information to users in a chart-comparative manner.

The injection simulation program shows the injection simulation of the tumor by the treatment parameters entered by the user and provides the maximum dimension of theoretical charge.

The history management program manages the history of patients being treated. In other words, it is possible to input, investigate, and delete troops. The newly entered troops can be divided into two parts: the introduction of the troops and the contents of the troops, and the introduction of the troops can be edited. It is possible. In the search function of the troops, a character can be searched by inserting a letter through the name of the person or the number of the troops, and the search function can find an existing medical history and modify it. The ability to remove a troop can permanently remove a previously recorded troop from the troop store, depending on the person's name or troop number.

The result input program can input the history of the seedlings and display the patient's name, number of treatments, and treatment parameters (voltage, current, charge amount, tumor size and resistance value). Input the maximum treatment charge, the maximum treatment voltage, the maximum treatment current, and the tumor treatment for each type, and the results of statistical analysis of the comparative example and the treatment effect are output.

The expert guidance program controls the theory and history of the treatment device (low frequency stimulator), how to use the expert's opinion, how to use the help system, help information such as word index related to the keyboard, various information through the Tab key, and the ESC key. Provide a method.

The above programs automatically calculate the required voltage, current, and amount of charge according to the tumor size, perform the simulation of the optimum electrode position and the placement of the anode and cathode, determine the open state or the short state to be described later, and inform the voltage. You can lock and change the current, you can lock the current, change the voltage, record, save and manage the history.

The monitor 9a as an output unit 9 is a portion where software for inputting and controlling treatment parameters such as voltage, current, treatment time, amount of charge, etc. input to the treatment electrode is displayed, and the printer 9b is a patient's medical history. It is an output device that can print data such as treatment history.

As an input unit 7, the keyboard is connected to the main control unit via an interface and is used for inputting parameter values required by the software.

The protection unit 21 detects a current applied to the electrode to prevent overcurrent from being induced to the patient, and an overcurrent protection circuit for enhancing the safety of the patient, and an overvoltage for automatically detecting an overvoltage current to forcibly cut off when the voltage and current are higher than the predetermined voltage. And a switch for manually forcibly interrupting the overvoltage current.

Here, the over-voltage current forced blocking circuit plays a role of immediately blocking the circuit when a short, that is, a positive electrode and a negative electrode is stuck between the electrode and the electrode.

That is, when the overvoltage current of the electrode unit is automatically detected, when the difference voltage between the plus and minus poles is 1 to 30V and the difference current is 1 to 300mA, the current supply to the electrode unit is forcibly cut off.

When a short is generated, the warning unit 23 generates a warning using a message or a sound according to a signal fed back to the main control unit 1 through the detection unit 19 and the A / D conversion circuit. Treatment will allow the treatment unit to return to an operational state.

In addition, the overvoltage current forced cut-off circuit causes the circuit to be opened if the distance between the positive and negative poles is too far. The open state refers to a state in which a circuit does not operate when a current cannot flow due to a high electrical resistance of the tissue (for example, 25 mA or more). In this case, a warning circuit operates to give a message or warning to an operator.

The sensing unit 19 includes a voltage sensing circuit sensing an output voltage applied to an electrode and a current sensing circuit sensing an output current applied to the electrode, and the detected signal is sent to the A / D conversion circuit of the converter.

The warning unit 23 is composed of a warning circuit that warns of occurrence of overcurrent due to a short between the electrodes.

The output driver 15 rectifies the applied alternating current into a direct current, and includes an output driving circuit connected to the D / A conversion circuit to amplify or reduce the value of the voltage and current applied to the electrode.

The output drive circuit has an output current of 1 to 300 mA, an output voltage of 1 to 30 V, more preferably a current of 1 to 150 mA and a voltage of 1 to 20 V.

This current and voltage are transmitted to the electrode through the divider constituting the electrode portion 17.

As shown in FIGS. 2 to 5, the distributor may be designed in various structures.

First, the short channel distributor will be described with reference to FIGS. 2 and 3. In FIG. 2, a tong type is shown in the short channel distributor. The positive (+) terminal 25 and the negative (-) terminal 27 on one side are connected to the wire 29, respectively, and the subwire 31 is connected to each wire 29 in parallel. Tongs 33 are connected to the other side of the subwires 31 to pick up the connection terminals of the electrodes.

3 shows the binding type in the short channel distributor. In this case, the binding pipe 37 is connected to the other end of the subwire 35 so as to insert the connection terminal of the electrode into the binding pipe 37.

In the above-described short channel distributor, since the subwires 31 and 35 are connected in parallel, the current value of the electrode connected to the subwires 31 and 35 may vary depending on the contact point in the tumor. One distributor is a multichannel distributor described below.

As shown in FIGS. 4 and 5, the multi-channel distributor has a structure in which a wire 43 connected to a plus terminal 39 and a minus terminal 41 is connected together in one cable, and the plus terminal 39 on one side is connected. The other side of the wires 43 and 47 corresponding to the negative terminal 41 and the forceps 45 are connected or the binding pipe 49 is connected.

The electrode connected to or inserted into the forceps 45 and the binding pipe 49 of the distributor is a cable type electrode (hereinafter referred to as a cable electrode) shown in FIGS. 6 and 7, and a straight type shown in FIGS. 8 to 10. It is possible to produce an electrode, a wave shape as shown in Fig. 11 or a coil shape as shown in Fig. 12. These electrodes will be described in more detail below.

The cable electrode 51 may be inserted into the esophagus, anus, the vagina of the woman, the uterus, or a blood vessel to treat the structure, and the structure of the cable electrode 51 may be inserted to move the electrode wire 55 to the center of the flexible tube 53. In the front side of the tube 53, a bundle 57 of wires having positive or negative poles is provided at predetermined intervals. In this case, the bundle 57 of wires is formed by winding the wire three or four times.

Here, the electrode wire 55 may have a positive pole or a negative pole, and the bundle 57 of the wire may be used by selecting a positive pole or a negative pole for each bundle.

The guide cap 59 is fitted to the cable electrode 51. The guide cap 59 is formed so that the remaining portion except for the front end portion of one side is opened about half, so that the wire bundle 57 is exposed by gripping the other side so that the guide cap can be freely rotated while being inserted into the cable electrode. Adjust to ensure proper response to treatment location.

As shown in FIGS. 8 to 10, the straight electrode 61 is used as a single-use structure, and the connection terminal 61b is coupled to one side of the platinum-plated needle 61a. In the case of using at least two, multi-channel distributors, a plurality of electrodes are used, and an electrode capable of continuous use of 1000 coulombs.

The scale (63) is formed on the surface of the needle (61a) to check the insertion depth when inserted into the treatment site.

The electrode 61 is packaged in a plastic cap in a sterile state, and when the electrode is used, the vinyl cap is opened and then the electrode is removed from the plastic cap and used after disinfection. Disinfection can be locked in 75% medicinal alcohol for 20 to 30 minutes, or any other disinfection method.

And do not bend the electrode in the process of using the electrode 61, avoid the impact of the electrode and other metal products. It is also possible to select and use a needle that fits the length depending on the size and location of the tumor. The used electrode is incinerated according to the regulations. Red tube temperature of the packaged electrode is -5 ℃ to 40 ℃, red tube humidity should not exceed 80%. Because the electrodes are used for therapeutic purposes, they should be stored in a place without perishable gas and in a well-ventilated room.

The needle guide 65 is inserted into the needle 61a of the electrode 61. Needle guide 65 can be made of a material that can be insulated, preferably made of a plastic material. In the center of the needle guide 65, a through passage 67 into which the needle 61a is inserted is formed, and at one side, a binding hole 69 is formed.

A binding jaw 71 is formed inside the binding hole 69, and a locking jaw 73 corresponding thereto is formed at the connection terminal 61b of the electrode 61.

The electrode 75 shown in FIG. 11 is formed of a wave of the needle, and the electrode 77 shown in FIG. 12 is formed of a needle in the form of a coil, and both types of needles have connection terminals 75a and 77a on one side. Is combined.

The electrodes described above are used to remove a tumor, and there is no reference electrode as in the conventional electrode, which is already known, and is inserted into the surgical site based on the plus and minus electrodes.

And feedback on treatment area is done in the following way.

In addition to the positive and negative electrodes described above, a reference electrode may be inserted to determine a difference in charge amount or current intensity between the positive and negative electrodes based on the reference electrode, and the reference may be made to the treatment process and the treatment history.

In addition, a plurality of temperature sensors are inserted into the tumor treatment site where the electrode is inserted, and the plurality of temperature sensors are connected to the sensing unit 19 through an interface. Therefore, the progress of the procedure can be recognized by grasping the temperature change of the treatment site during the treatment process using the electrode.

In addition, feedback is also possible through changes in permittivity and resistance in the treatment of plus and minus poles in the tumor treatment area. In other words, when a DC current is applied to the electrode, an electrochemical reaction occurs in the tumor tissue, and a dielectric property is generated at the electrode having no dielectric property. The dielectric property can be calculated from the DC current to understand the treatment progress and condition. .

In addition, after irradiating a specific light to the tumor tissue, it is possible to identify and feed back the difference in the reflectance difference according to the change of the physical properties of the tumor tissue. Identify changes in the treatment of tumor tissue.

The necrosis range of one electrode in the procedure under the assumption of the above feedback is 1 to 1.5 cm, the number of electrodes used is selected according to the size or volume of the tumor, and all except the cable electrode 51 The electrodes 61, 75, 77 are manufactured in the form of needles of various lengths and diameters.

The amount of direct current, voltage and charge is proportional to the size and volume of the quantity and depends on the position. The amount of charge required is about 100C per 1cm of the payload.

Although the cross-sections of the electrodes 61, 75, 77 described above are not shown in the drawings, various shapes are possible.

In other words, it is possible to fabricate a form in which the structure of the SEM (scanning electron microscope) probe is imprinted on the surface of the electrode so that a large number of charges (electrons) are transferred to the tumor tissue. In order to increase the density, there is an electrode in which the surface of the electrode is cylindrical and a plurality of arcs are formed on the outer circumferential surface to enlarge the cross-sectional area of the surface.

The shape of the electrode cross section of this type can be produced, for example, pentagonal, hexagonal or radial.

All the electrodes described above are coated with platinum on tungsten and titanium, and are manufactured to withstand a charge amount of 1000C or more. In particular, the thickness of the platinum plated on the electrode is preferably 0.1 μm to 1 μm.

When the positive and negative poles as described above are inserted into the tumor at an appropriate distance (the distance between the positive and negative poles does not exceed 3 cm), the tumor cells are necrotic through the following treatment principle. .

A direct current is applied between the positive and negative poles, which may be a general direct current, or may be pulsed and sent to a bias voltage. At this time, the pulse width of the pulse current is 50ns to 100ms, the bias voltage is 0.5 to 3kV.

When the DC current flows in the payload structure, the body fluid moves from the positive pole to the negative pole.

At this time, dehydration occurs near the positive pole and edema occurs near the negative pole.

Here, dehydration and edema are phenomena caused by the movement of extracellular and intracellular fluids from positive to negative poles in the direction of the electric field, causing tumor metabolism to necrotic tumor cells.

And when the DC current flows through the tumor tissue, the electrochemical reaction occurs at the electrode and the pH value changes. Cations (H ⁺ , Na ^+, etc.) move to the negative pole, and anions (Cl ⁺ etc.) move to the anode. And each of these chemical reactions takes place:

The negative electrode _{(cathode): 2H 2 O +} 2e - -> H 2 + 2OH -

Plus electrode: 2Cl ^-- > Cl ₂ + 2e

OH ⁻ is generated at the minus pole but not at the plus pole. Therefore, near the positive pole is strongly acidic, and near the negative pole is strongly alkaline. These strong acids and strong alkalis have the effect of destroying tumor tissues.

And depolarization of tumor cell membranes causes disruption of metabolism. In other words, the intrcacellular environment is negatively charged compared to the extracellular one. This means that the cells have a stable membrane potential due to the concentration gradient of the constituents. When the potential difference of tumor cells decreases rapidly, a change in concentration occurs. DC current changes the concentration of ions, especially the concentration of ions in the extracellular. At this time, the potential difference also changes. This potential difference affects the movement of the ions, causing the cell membrane to repolarize and destroying the tumor cells.

The therapeutic device according to the present invention configured as described above has the following effects.

Depending on the tumor, decide whether to use cable electrodes or straight electrodes.

When data related to the size (length, width, thickness) and location of the tumor are input by using a keyboard, the computational processing circuit of the main control unit is driven through the interface 5 to treat the tumor by the programs of the storage unit 3. The amount of current, voltage, and charge required to do this is automatically calculated and output.

At this time, the main control unit 1 uses a calculation method in which the operation processing circuit controls the data using the software of the storage unit 3. In the calculation, all output voltage values enter the D / A conversion circuit through the connection unit 13. The value of the D / A conversion circuit is converted into the corresponding simulation amount.

The simulation voltage is output to the electrode portion 17 through the overcurrent protection circuit of the output driver 15.

First, the case of using the cable electrode 51, the electrode wire 55 and the wire bundle 57 of the outer periphery of the tube is connected to the positive and negative poles of the distributor, respectively. At this time, the guide cap 59 is coupled to the cable electrode 51.

In this state, the cable electrode 51 is inserted into the treatment site, the tumor site to be removed is approached, and the wire bundle is exposed to the site to be treated by rotating the guide cap 59.

When the linear electrode 61 is used, the electrode corresponding to the positive electrode is connected to the forceps 33 or the binding pipe 37 of the distributor. And the needle (61a) of the electrode 61 is inserted into the tumor, and the gap between the positive electrode and the negative electrode of the electrode at the time of insertion is 0.5cm to 4cm It should be about.

In this way, when a current is applied to the cable electrode 51 or the linear electrode 61, a direct current flows between the positive electrode and the negative electrode, and as described above, dehydration and edema, change of pH value and change of tumor cell membrane Depolarization causes tumor cells to become necrotic.

At this time, if the output is large, the reference value of the overcurrent protection circuit is decreased, and the overcurrent protection circuit is open, and if overloading, the limiting output current of the overcurrent protection circuit and the overvoltage current forced cut-off circuit of the protection unit 21 is the maximum value. Limited to.

If the overcurrent is not blocked due to the malfunction of the circuit, the overvoltage forced blocking circuit operates to forcibly cut off the overvoltage and current, and sends a warning message to the operator to protect the safety of the patient.

The voltage sensing circuit and the current sensing circuit of the sensing unit 19 detect voltage and current values of the load, respectively. In addition, they send the corresponding voltage value to the A / D conversion circuit, and the A / D conversion circuit converts the corresponding voltage value into a representative overcurrent and a voltage value, and then performs arithmetic processing of the main controller 1 through the connection part 13. Return to the circuit.

The operation processing circuit compares the return voltage and current values based on the stored voltage and current values, and adjusts the output voltage value once again based on the control processing method so that the voltage and current can be controlled to flow constantly.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. Naturally, it belongs to the range of.

As described above, the treatment device according to the present invention can be applied to patients who cannot be surgically resected due to a malignant tumor, do not respond to radiation or anticancer drugs, or cannot receive such treatment due to a weak constitution.

In addition, since the necrosis range per electrode is 1 to 3 cm, treatment can be performed while protecting normal tissues.

In addition, if the magnitude of the voltage and current exceeds a predetermined static load amount and the current amount, the circuit is opened through the blocking circuit, thereby minimizing damage to the human body.

And treatment using the electrochemical treatment device of the present invention has the effect of alleviating the pain of the patient.

In addition, an electrobiological and electrochemical mechanism of necrosis of the tumor causes currents to be concentrated in the tumor tissue, resulting in effective, low side-effects and no surgical treatment.

Furthermore, by treating the tumor in a manner different from the conventional cancer therapy, the tumor is converted to resistance and the immune system is increased.

In addition, it can be said to be suitable for both inpatients and outpatients.

In addition, the tumor can be removed without surgical intervention, so the patient can lower the cost of treatment.

1 is a block diagram showing the configuration of a treatment device according to the present invention.

Figure 2 schematically shows the structure of the short channel distributor of the treatment device according to the present invention.

Figure 3 schematically shows another structure of the short channel distributor according to the present invention.

4 schematically shows the structure of a multi-channel distributor according to the invention.

5 schematically illustrates another structure of a multi-channel distributor according to the present invention.

6 is a perspective view showing an embodiment of a flexible electrode according to the present invention.

FIG. 7 is a cross-sectional view of the electrode of FIG. 6; FIG.

Figure 8 is a side view showing a straight electrode and a derivative in accordance with the present invention.

FIG. 9 is a side view illustrating a coupled state of the straight electrode and the derivative of FIG. 8; FIG.

FIG. 10 is a perspective view illustrating a coupling structure between the straight electrode and the derivative of FIG. 8; FIG.

Figure 11 is a side view showing a wave electrode according to the present invention.

12 is a side view showing a coiled electrode according to the present invention.

Explanation of symbols on the main parts of the drawings

7 input unit 9 output unit

11 conversion unit 13 connection unit

15: output drive 17: electrode

19 detection unit 21 protection unit

23: warning unit 25: plus terminal

27: minus terminal 29: wire

31, 35: subwire 33: tongs

37: binding tube 51: cable electrode

53: tube 57: bundle of wires

59: guide cap 61: electrode

65: Needle Guide

Claims (25)

delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete A main control unit for processing the input parameter values for electrochemical treatment using an internal processing circuit; A storage unit connected to the main control unit and storing various programs and data; An input unit and an output unit connected to the main control unit and configured to include a keyboard for inputting the parameter values, a monitor for outputting a result, and a print; A converter for converting the digital values output through the arithmetic processing circuit into analog values or converting analog values into digital values; An output driver for rectifying the alternating current applied through the power supply into a direct current, and amplifying or reducing the value of the voltage and current applied from the power supply according to the analog value converted by the converter. ; And DC current between the plus and minus poles, which are separated into plus and minus poles, are connected to the output driver through an interface unit and receive the voltage and current values amplified or reduced from the output driver and inserted into the treatment area. Electrode part to let flow Including, The DC current electrochemical treatment device to send a pulse to the bias voltage. The method of claim 17, The output driver, An electrochemical therapy device comprising an output drive circuit for outputting current to 1 to 300mA, output voltage to 1 to 30V. The method of claim 17, Electrochemical treatment device further comprises a protection unit for detecting the current applied to the electrode unit from the output driver to prevent the overcurrent is induced to the patient. The method of claim 19, The protection unit, And an overvoltage current forced blocking circuit for automatically detecting an overvoltage current of the electrode unit to forcibly cut off the supply of current to the electrode unit when the voltage is 1 to 30V and the current is 1 to 300mA. The method of claim 20, And a warning unit generating a warning using a warning message or a sound by feeding back through the main control unit when a short is generated between the plus and minus poles. The method of claim 21, An electrochemical treatment device that causes the treatment device to switch back to a continuously operable state by the main control unit when the user takes care of the warning message after the warning message. The method of claim 20, The overvoltage current forced blocking circuit, Electrochemical treatment device to block the operation by opening the circuit when the distance between the positive electrode and the negative electrode is far beyond the predetermined electrical resistance. The method of claim 17, And a sensing unit for sensing an output voltage or an output current applied to the electrode unit. The method of claim 17, And a plurality of electrodes or one electrode connected to each of the plus and minus electrodes.