KR20120016748A - Apparatus for led optical irradiation of medical - Google Patents

Abstract

PURPOSE: A light emitting diode light irradiating apparatus is provided to simultaneously obtain low output light irradiation and high output light irradiation for treatment by semi-permanently expanding the life expectancy of the apparatus. CONSTITUTION: A light emitting diode light irradiating apparatus includes a power supplying unit(10), a light emitting diode package(22), an optical cable(24), and a light irradiating injection needle(36). The power supplying unit is a multi connecting type and supplies power. The light emitting diode package receives the power from the power supplying unit and generates light. The optical cable is in connection with the light emitting diode package and transmits light. The light irradiating injection needle irradiates light to lesions. The power supplying unit includes a plurality of power supplying sockets(11), a power adjusting part(13), and a displaying part(15).

Description

LED light irradiation apparatus for medical use {Apparatus for LED optical irradiation of medical}

The present invention relates to a medical LED light irradiation apparatus, and more particularly to a medical LED light irradiation apparatus for treating by irradiating light to the affected area by using an LED instead of a laser treatment device.

The use of light in the treatment of diseases is considered to be quite old, as evidenced by the use of dyes in the treatment of skin diseases in Egypt, BC. The light-harvested strawworms died in the acridine solution, and when the light was not irradiated, the strawworms in the acridine solution survived.

Tappenier and Joblebauer called this phenomenon the photodynamic reaction.

This is a photochemical reaction that requires light, a chemical that absorbs light to cause a special reaction, and oxygen.

Since 1990, photodynamic therapy methods using photosensitizers such as hematopophyrin derivatives (HPD) have been widely used in various countries.

In the early 1970's, low-power lasers such as helium-neon lasers began to be applied to the immune system since Inuyshin, Russia and others first used low level laser therapy (LLLT) in clinical medicine.

As a representative example, the photochemical action can be seen in the carbon assimilation of the plant, but when the light is irradiated to the living body, the ATP is produced by the photochemical action to activate the cells.

The biochemical action of light is determined by the wavelength, polarization, and intensity of light. In low-power laser therapy, light with a wavelength of 530-1000 nm and energy of about 1 to 3 mW activates the immune system of the living body most effectively. It is known to optimally activate the metabolism of other cells.

Such light has conventionally used a helium-neon laser, a YAG laser, etc. The semiconductor laser is advantageous in terms of the accuracy, size, and price of the laser beam, and can be oscillated in various wavelength ranges and can be manufactured at low cost. (semiconductor laser or laser diode) has been developed and used recently.

When the laser and the light transmission device used in the conventional laser treatment are classified according to the Korea Food and Drug Administration's medical device registration regulations, the surgical cutting and tissue destruction using the high-power heat of the laser, and the light-sensitive material responding to a specific wavelength It can be classified into 1 watt or more high power irradiator for photodynamic therapy (PDT) to activate and treat the affected area, and a photothermal therapy to treat the affected area by applying appropriate heat to the human body.

Conventional low power therapeutic laser devices or photodynamic therapy laser devices have a laser main body that outputs a laser by mounting a semiconductor laser or a laser diode inside, a control unit that controls the output of the laser light, and occurs during laser output. It consists of a heat dissipation system that dissipates the heat, and a cable that transmits the laser light emitted from the laser body to the affected part.

Conventional photodynamic therapy using a laser is to administer a photosensitive material to the patient when a tumor occurs on the surface, such as skin cancer, and after a certain time, the light sensitive material selectively accumulates only in tumor cells, at this time the photosensitive material in the affected area When surface light is irradiated to the affected area with the appropriate energy and wavelength of the reaction, the photosensitive material is activated to release free radicals, thereby selectively killing only tumor cells by free radicals.

In addition, the conventional low-power laser treatment surface irradiation of light of a specific wavelength to the affected area when the tumor occurs on the surface, such as skin cancer effectively activate the immune system of the living body, and activate the metabolism of other cells.

For example, in the case of photodynamic treatment of skin cancer, when the skin tumor is within 5 mm from the skin and the laser beam is irradiated to the affected area while maintaining the laser irradiation device at a constant distance from the skin surface, the laser light penetrates the affected surface. By activating the light sensitizer, tumors on the skin surface can be removed.

However, the penetration depth of the laser light irradiated to the affected surface is limited to within 5 mm, and solid tumors occurring inside the human body such as lung cancer, stomach cancer, esophageal cancer, rectal cancer, and uterine cancer are located inside the human body more than the depth of light irradiation. In other words, there is a problem that the treatment is not possible by irradiating the affected area with laser light from the outside.

In order to solve the above problems, conventionally, the endoscope cable is inserted into the human body through the oral cavity, the endoscope cable is moved to the affected part, and the laser beam of a specific wavelength of the photosensitive material is irradiated to the affected part through the endoscope cable. In addition, tumor sensitive cells that selectively accumulate light-sensitive substances could be necrotic.

However, the conventional photodynamic therapy laser device or laser device for low power laser therapy has the following problems.

1. Conventional semiconductor lasers have the advantage of controlling and radiating a variety of output values, like diode lasers, but at present there are disadvantages of high price.

2. Conventional photodynamic therapy laser devices and low power laser therapy laser devices have been used separately from each other because they are irradiated with different light outputs. Due to the increase in manufacturing cost, there is a problem that can not use the device efficiently.

3. Conventional photodynamic therapy laser devices or low power laser therapy laser devices are limited to one light outlet, which is inconvenient for patients requiring multiple light irradiations, and simultaneously irradiates multiple lights on multiple affected areas. Because it can not be done, the procedure must be performed discontinuously, and the treatment is inefficient.

4. A conventional photodynamic therapy laser device or a low power therapy laser device outputs a plurality of laser lights by mounting a plurality of semiconductor lasers or laser diodes inside the device to output a plurality of laser lights, or outputs a high power semiconductor. A laser and a light splitting device can be mounted inside the device to split light into high power laser beams.

However, since the apparatus for splitting a single high power laser beam into a plurality of light and a device for controlling the light, and a heat dissipation system such as a heat sink and a cooling fan to cool the high heat generated by the laser of a high power, a component must be provided separately, Increasing the number increases the volume of the device, in the case of the optical splitting connector, there is a possibility that non-uniform light injection occurs, there is a problem that the price of the device increases.

5. The optical cable connected to the laser main body of the laser device for conventional photodynamic therapy and low power laser therapy decreases the light energy transmitted through the optical cable, so as to satisfy the optical energy required for the treatment of the affected area. To this end, the length of the optical cable is inevitably limited, which allows the patient to receive treatment only within the limited length of the optical cable from the laser body.

Recently, the low power laser therapy device and the photodynamic laser therapy device have been manufactured for desktop use due to the volume reduction of the main body, which is easy to carry, but there are still limitations in reducing the volume and weight of the power supply and the main body, and especially the endoscope to provide light inside the human body. In case of irradiation, the length of optical cable is limited and still various applications cannot be applied.

6. For most tumors occurring inside the human body, light irradiation is easy because the tumor is located at the end of the endoscope optical cable, but the endoscope optical cable has a large diameter and is attached to the end of the endoscope optical cable to diffuse the light. Since the volume of the catheter is large, it is inconvenient to insert it through the oral cavity of the patient, and there is a problem of causing severe pain to the patient when inserted through the oral cavity of the patient.

In particular, in the case of lung cancer patients whose surgical operation is impossible, photodynamic treatment using laser light is inevitable, but when the tumor is in the diaphragm such as lung cancer, the endoscope cable is applied to the lung and stomach. Because it does not reach far, even photodynamic therapy is difficult.

The present invention has been invented to solve the above problems, and inexpensive by irradiating light using a cheap and permanent LED (LED) instead of a semiconductor laser or a laser diode for conventional photodynamic therapy and low power laser therapy. It is an object of the present invention to provide a medical LED light irradiation apparatus which can manufacture a light irradiation apparatus at a cost and can semi-permanently extend the life of the light irradiation apparatus.

In addition, the present invention improves the conventional low-power laser therapy laser device and high-power photodynamic therapy laser device to separate the low-power phototherapy and high-power photodynamics by using the LED irradiation device having a 1mW ~ 2W class light output By simultaneously implementing the therapeutic light irradiation, there is another object to provide a medical LED light irradiation device that is easy to use and reduce the cost of the separate low-power laser treatment laser device and photodynamic therapy laser device.

In addition, the present invention improves that the conventional light outlet is limited to one by applying a multi-connected power supply having a plurality of power sockets, by separating a plurality of power supplies to each LED package to provide a plurality of light to the affected area It is another object to provide a medical LED light irradiation apparatus that can simultaneously irradiate and treat, and improve the efficiency of treatment.

In addition, the present invention improves the problem that the volume is increased by providing a separate heat dissipation system to cool the high heat generated by the existing high-power laser, to produce a plurality of LED packages made of metal such as copper excellent heat dissipation, Another object of the present invention is to provide a medical LED light irradiation apparatus capable of reducing volume and weight by increasing a heat dissipation area in a spiral structure, and thus eliminating the need for a separate heat dissipation system.

In addition, the present invention improves that the treatment of the patient was possible only within a limited length by the optical cable by separating the light from the conventional laser device, by separating a plurality of power in the multi-connected power supply, to a plurality of power sockets Another object of the present invention is to provide a medical LED light irradiation apparatus capable of treating a patient without limiting the length of an optical cable by extending the connected power connection line.

In addition, the present invention improves the point that the photodynamic treatment was impossible because the endoscope optical cable did not reach the diaphragm of the existing lung tissue, 0.2 ~ 0.5 mm in diameter and 60 ~ 150 mm in length of the injection needle for the affected surface Another object of the present invention is to provide a medical LED light irradiation apparatus that can be irradiated to the diaphragm to accurately irradiate light.

In order to achieve the above object, the present invention provides a multi-connected power supply for supplying a plurality of separate power supply;

An LED package for generating light by receiving power through the power connection line;

An optical cable connected to the LED package and transmitting light; And

A light irradiation needle connected to the optical cable to accurately irradiate light to the affected part;

It provides a medical LED light irradiation apparatus comprising a.

Here, the multi-connected power supply device includes a plurality of power sockets to which a plurality of power connection lines are separately connected to supply a plurality of powers to the LED package; A power adjusting unit for adjusting the power according to the light wavelength of the LED package; And a display unit for displaying the power supplied to the LED package. By separating a plurality of power sources and supplying the plurality of LED packages to the plurality of LED packages, a plurality of lights may be simultaneously irradiated to one or more affected areas simultaneously. By extending the length of the connecting wire as desired, it is possible to solve the problem that the treatment was possible at a limited distance by the length of the optical cable.

The LED package may include a housing disposed between a power connection line and an optical cable and having a lead wire mounted therein; An LED chip mounted to be connected to a lead wire in a receiving groove recessed at one end of the housing to generate light; And a condenser lens mounted at one end of the housing to condense the light generated from the LED chip and emit the light to the optical cable, wherein the LED package may accommodate specific power to form a specific wavelength. do.

The Teflon injection molded product is first mounted on the mounting seat of the LED chip of the housing, and then the LED chip is mounted on the Teflon injection product to dissipate heat generated from the LED chip, and an excessive current flows through the LED chip to the housing when a short occurs. It is characterized by preventing the short circuit.

The optical fiber connector is detachably coupled to the front end of the LED package to emit light to the optical cable, and the power connector is detachably coupled to the rear end of the LED package to be connected to the power connector of the multi-connected power supply. Power is supplied through, and the power connection portion and the optical fiber connection portion is characterized in that the outer surface is made of a spiral structure to expand and dissipate heat generated in the LED package.

The light irradiation needle has a length of 60 to 150 mm and a diameter of 0.2 to 0.5 mm, and invades to the periphery of the diaphragm during tumor treatment of the diaphragm of pulmonary tissues to accurately transmit light to the affected area.

In addition, by injecting a plurality of needles used for photonic use on the affected surface at a plurality of angles and simultaneously irradiating light on one affected area, since the diameter of the optical fiber is reduced, the output of light energy can be prevented from being lowered, thereby transferring proper energy to the affected area.

The advantages of the medical LED light irradiation apparatus according to the present invention are as follows.

1. By irradiating light to the affected area by using LED which is inexpensive and semi-permanently available, it is possible to manufacture light irradiating device for photodynamic therapy and low power light therapy at low cost and to extend the life of the device.

2. Multi-connect type power supply adjusts current and voltage to LED, and realizes LED light having light output range of mW class up to 2W for each disease. By simultaneously implementing the therapeutic light irradiation device, it is possible to reduce the cost of the separate use of the conventional photodynamic therapy laser device and the low power laser therapy laser device, and use the light because it is not necessary to provide a separate light therapy device. This can reduce the economic burden when treating various cancers.

3. The multi-connected power supply device has at least five or more power outlets (power sockets), and connects a power connection line to a plurality of LED packages, respectively, and supplies power separately, according to each disease. Single or multiple light irradiation devices can be implemented, and light can be irradiated to several affected areas at the same time, so that the treatment can be efficiently performed, thereby maximizing a therapeutic effect.

4. The heat dissipation area is increased by forming the housing of the LED package in a plurality of power connection wires in a spiral structure, and the package is made of a metal material such as aluminum or copper having excellent heat dissipation performance to dissipate heat generated when light is emitted. Since a separate heat dissipation system is not required, the treatment device can be manufactured at low cost by reducing the volume and reducing the cost of having a separate heat dissipation system.

5. The main body of the conventional laser equipment for photodynamic therapy and low power laser therapy by providing a plurality of power sockets in the multi-connected power supply and compensating for the limited optical cable length through the extension of the power cable connected to each power socket. With the limited length of the optical cable in the problem that the optical treatment was possible only within a certain distance can be solved.

6. Attach the irradiation needle which is made longer than the general needle to the end of the optical cable, and at the same time, the needle for light irradiation is invaded to the affected surface at various angles so that it can be accurately placed on the diaphragm of the lung tissue that the endoscope cable cannot reach when treating lung cancer. By irradiating light, photodynamic therapy can be performed even in patients with lung cancer whose surgical procedure is impossible and the endoscope optical cable does not reach the affected area and tumors develop in the diaphragm where photodynamic therapy is inevitable.

1 is an overall configuration diagram of a medical LED light irradiation apparatus according to an embodiment of the present invention.
2 is an overall configuration diagram of a medical LED light irradiation apparatus according to another embodiment of the present invention.
3 is a perspective view illustrating an LED light source unit in an embodiment of the present invention.
Figure 4a is a cross-sectional side view before the short circuit of the LED light source in the embodiment of the present invention.
Figure 4b is a side cross-sectional view after the short circuit of the LED light source in the embodiment of the present invention.

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

The present invention relates to a medical LED light irradiation apparatus that can implement a photodynamic therapy light irradiation and a low power therapy light irradiation at the same time by using an LED instead of a photodynamic therapy laser irradiator and a low power laser therapy laser irradiator.

1 is an overall configuration diagram of a medical LED light irradiation apparatus according to an embodiment of the present invention, Figure 2 is an overall configuration diagram of a medical LED light irradiation apparatus according to another embodiment of the present invention, which is an embodiment using a battery To indicate.

In addition, Figure 3 is a detailed view showing the LED light source in the embodiment of the present invention, Figure 4a is a side cross-sectional view before the short circuit of the LED light source in the embodiment of the present invention, Figure 4b is a short circuit of the LED light source in the embodiment of the present invention It is a side sectional view.

As shown, the medical LED light irradiation apparatus of the present invention, the multi-connected power supply device 10 for forming at least five or more light outlets, and a plurality of power sources from the power supply device 10 A light source unit 20 that is separately supplied to generate light of a specific wavelength, a light transmitting unit for transmitting the light emitted from the light source unit 20, and a light irradiation unit for stably irradiating light transmitted through the light transmitting unit stably to the affected part It includes.

The multi-connected power supply device 10 serves to supply and control power to the LED, and forms a plurality of power sockets 11 on the power supply body, and the power connection line 12 to the power sockets 11. By freeing the length of the connection, due to the limitation of the length of the optical cable 24 for transmitting the conventional laser light, the optical dynamics treatment and low power treatment could be performed only within a certain distance from the body of the conventional laser device The problem can be solved.

In other words, the multi-connected power supply device 10 includes a plurality of power sockets 11 on one side to supply a plurality of powers, and a power connection line 12 to the power socket 11 by a desired length. By extending and compensating the length of the existing limited optical cable 24, the distance from the multi-connected power supply 10 to the patient can be adjusted as desired, so that the conventional photodynamic therapy laser device or low power laser therapy laser device Compared to the convenience of use.

The power supply 10 includes a plurality of power sockets 11 formed on at least five front surfaces, a plurality of power adjusting units 13 installed adjacent to the power sockets 11, and a timer adjustment button 14, respectively. And a display unit 15.

At this time, the power adjustment unit 13 is configured so that the user can increase or decrease the current and voltage by turning left and right by hand, the timer adjustment button 14 is divided into an up adjustment button and a down adjustment button, the up adjustment button Press to increase the time and press the down button to shorten the time.

The power supply 10 connects a plurality of LEDs to the power socket 11 through the power connection line 12, and adjusts the current and voltage supplied to the LEDs through the power adjusting unit 13 according to the specific wavelength of the LEDs. And may be applied.

The power supply device 10 is designed to be supplied by adjusting the voltage within the range of 1 ~ 12V, and to apply the power in accordance with the optical power characteristics of the LED by expressing the current in mA units.

The LED operation indicator 16 is installed on one side of the front side of the power supply device 10 so that the user can easily see whether the LED connected to the power socket 11 is currently operating.

In addition, a start button 17 and a stop button 18 are respectively installed on one side of the front surface of the power supply device 10 to supply power to the LEDs through the start button 17 and the stop button 18. It can be cut off, and can supply power to the LED for a set time through the timer adjustment button (14).

And, a pedal switch connector is installed on one side of the rear surface of the power supply device 10, by connecting the pedal switch to the connector can easily operate the power supply and cut off via the pedal (19).

As the light source unit 20 of the present invention, an LED capable of emitting light of various wavelengths is used, and the LED receives a current and a voltage from the power supply device 10 to switch the light output and the light wavelength according to the application to treat photodynamic therapy. And low power therapeutic light irradiation can be performed simultaneously.

The LED light irradiation apparatus of the present invention limits the light output emitted through the LED to the range of 1 ~ 2000 mW (mili watt).

Particularly, when the light output is too large for more than 2000 mW for the photodynamic therapy light irradiation, excessively high light irradiation energy causes burning of the affected tissue, resulting in destruction of normal tissue. Because of the problem, it is desirable to limit the light output to within the range of 100-2000 mW.

In addition, when the light output energy is too much greater than 100 mW for the low-power therapeutic light irradiation, the activity of the biological immune system is rather reduced, and the metabolism of other cells is lowered, so that the light output is 1 to 100. It is desirable to limit the range to mW.

At this time, the wavelength band of the light irradiation apparatus is limited to the range of 530 ~ 745 nm.

For example, the wavelength band of the light irradiation apparatus is 530 nm, 632 nm, 652 nm, 662 nm, and maximum 745 nm.

If the wavelength range of light irradiation is less than 530 nm, it is insufficient to activate the biological immune system, and if it exceeds 745 nm, the activity of the biological immune system and metabolism of other cells are rather reduced.

The light source unit 20 includes a power connection unit 21 to which a power connection line 12 is connected, an LED package 22 detachably mounted to the power connection unit 21, the LED package 22, and an optical cable 24. ) Is composed of an optical fiber connecting portion 23 is connected.

The front end portion of the power connection line 12 is mounted inside the power connection portion 21, and the insertion portion is formed so that the LED package 22 can be screwed into the inside of the end of the power connection portion 21, the power connection portion The LED package 22 may be electrically connected to the power connection line 12 by the 21.

In addition, the power connection portion 21 is made of a metal material such as aluminum or copper having excellent heat dissipation performance, and the outer surface has a spiral structure to expand the heat dissipation area capable of dissipating heat transferred from the LED package 22. By doing so, the electrical connection function and the heat dissipation function can be secured at the same time.

The rear end portion of the optical cable 24 is mounted inside the optical fiber connecting portion 23, and an insertion portion is formed in the end of the optical fiber connecting portion 23 so that the LED package 22 may be screwed into and inserted into the optical fiber connecting portion 23. 23, the LED package 22 can be easily connected to the optical cable 24.

In addition, the optical fiber connecting portion 23 is made of a metal material such as aluminum or copper having excellent heat dissipation performance, and the outer surface has a spiral structure to expand the heat dissipation area capable of dissipating heat transferred from the LED package 22. In addition, optical connection and heat dissipation can be secured simultaneously.

The LED package 22 is mounted on the housing 25 in which the (+) / (-) lead wires 30 are mounted in the longitudinal direction, and mounted on the upper surface (metal surface) of the housing 25 to emit light of a specific wavelength. LED chip 26 for generating a light and a condensing lens 32 for condensing the scattered light generated by the LED chip 26 to be emitted to the optical cable 24 as a light transmission unit.

The housing 25 has a cylindrical structure, and protrusions 27 are formed at the center in the longitudinal direction of the cylinder, and threads are formed on the outer circumferential surfaces of the first half and the second half of the cylinder except the protrusions 27, and the first half of the housing 25. Is inserted and screwed into the insertion portion of the optical fiber connection portion 23, the second half of the housing 25 is inserted and screwed into the insertion portion of the power connection portion 21.

Forging molding the receiving groove 28 in the first half of the housing 25 by a high-power press, and bonding the teflon injection-molded product 29 in the form of film to the bottom of the compressed receiving groove 28, and then the Teflon injection ( 29) After attaching the LED chip on the lead, the wire 31 is bonded to the lead terminal.

In this case, the Teflon injection 29 is an insulating film having excellent heat dissipation, and is disconnected when a short occurs in the wire 31 that electrically connects the lead chip of the LED chip 26 and the housing 25 due to overcurrent. Due to the insulation function to prevent the current from leaking into the housing 25 and the heat generated from the LED chip 26 is rapidly transferred to the housing 25 to perform a heat radiation function to radiate heat through the housing 25 at the same time do.

Conventional LED package 22 is manufactured by die-bonding the LED chip 26 in the center of the package surface without the Teflon injection 29, and by bonding the wire 31 to the lead terminal, the LED without the Teflon injection 29 When an excessive current flows in the LED chip 26 during die bonding of the chip 26, the wire-bonded wire 31 is disconnected, and the disconnected wire 31 adheres to the LED package 22 body (+). ) The lead terminal and the negative lead terminal are connected, which causes current to flow through the package body and leak.

However, since the Teflon injection 29 is an insulator having excellent heat dissipation, even when the wire-bonded wire 31 is disconnected when an overcurrent flows through the LED chip 26, the disconnected wire 31 does not adhere to the package body and the Teflon injection ( 29, the current can be prevented from leaking into the housing 25 that is the package body by the Teflon injection 29.

In addition, in the case of attaching the Teflon injection 29 to the package surface first and then die-bonding the LED chip 26, the inexpensive bare chip (LED chip without insulator at the bottom of the chip) By using a bare chip that does not have a separate insulator attached to the lower part of the chip since the injection molding 29 replaces the function of insulating the housing 25 when the wire is broken, the LED package 22 may be used. In addition to reducing the price of), as the LED chip 26 is easily bonded to the Teflon injection molding 29 due to the characteristics of the chip, heat dissipation performance and insulation function can be secured at the same time, resulting in degradation of the LED package 22. It is possible to prevent shortening of life due to the phenomenon.

The condenser lens 32 includes a protruding flange portion 33 formed at the center of the lens body, and a condenser portion 34 protruding backward from the flange portion 33 to be inserted into the receiving groove 28 of the housing 25. ) And an optical fiber fixing part 35 which protrudes forward from the flange part 33 and is inserted into the insertion part of the optical fiber connecting part 23.

At this time, the light collecting part 34 is inserted into the receiving groove 28 of the housing 25 and screwed together, and a fixing groove is formed in the optical fiber fixing part 35, and the optical cable 24 is provided in the fixing groove. Insertion is fixed.

An optical cable 24 or an optical fiber is used as the light transmitting unit, and the optical cable 24 delivers the light generated from the LED package to the light irradiation needle 36.

Since the light output from the LED package 22 decreases as the length of the optical cable 24 increases, the optical cable 24 may provide a light output required according to the characteristics of the LED during photodynamic therapy and low-output light therapy. Its length is limited to 150-200 mm to ensure.

Since the optical cable 24 has a smaller diameter, the light output is lowered. Therefore, light is applied to the first optical cable 24a and the light irradiation needle 36 to secure the light output required according to the characteristics of the LED. And a second optical cable 24b for transmission.

The first optical cable connector 37 is mounted at the front end of the first optical cable 24a, the second optical cable connector 38 is mounted at the rear end of the second optical cable 24b, and the second optical cable connector 38 is mounted. Is screwed into the interior of the first optical cable connector 37 to detachably connect the first optical cable 24a and the second optical cable 24b by the first and second optical cable connectors 37 and 38. Can be.

At this time, the diameter of the optical fiber inserted into the first optical cable 24a is the same as the diameter of the optical fiber inserted into the second optical cable 24b, and the diameters of the first optical cable 24a and the second optical cable 24b At the connection portion, the socket for the optical fiber connection is connected in a male and female structure, thereby preventing optical loss during light transmission through the first and second optical cables 24a and 24b.

For example, at the front end of the first optical cable 24a, an optical fiber (female) is formed so as to enter a predetermined depth inside the coating material (the material coated on the outer surface of the optical fiber to protect the optical fiber), and the second optical cable 24b is provided. At the rear end of the optical fiber (male) protrudes in the longitudinal direction than the covering material of the second optical cable 24b, when the first optical cable 24a and the second optical cable 24b are connected, the optical fiber of the second optical cable 24b The first optical cable 24a is connected to the optical fiber of the first optical cable 24a while being inserted into the coating material of the first optical cable 24a, so that the light transmitted through the first optical cable 24a does not leak and is transmitted to the second optical cable 24b.

The second optical cable 24b is disposable, whereas the first optical cable 24a has to be repeatedly used for a long time, so that the diameter of the covering covering the optical fiber of the first optical cable 24a is the optical fiber of the second optical cable 24b. It is thicker than the diameter of the covering covering it.

In addition, the rear end of the second optical cable 24b may be compressed by a crimping tube to prevent the LED light from leaking from the second optical cable 24b.

A light irradiation needle 36 is used as the light irradiation part, and is connected to front ends of the plurality of second optical cables 24b, respectively.

The light irradiation needle 36 invades the skin surface of the affected area and reaches the diaphragm of the lung tissue, so that a plurality of LED lights can be simultaneously irradiated accurately on the tumor generated in the diaphragm through the light irradiation needle 36.

When the light irradiation needle 36 is less than 0.2 mm in diameter, the light irradiation diameter through which light is transmitted is excessively reduced so that proper light energy cannot be transmitted to the affected part, and when it exceeds 0.5 mm, when invading through the skin. Since there is a problem that causes pain to the patient, it is preferable that the inner diameter of the injection needle is 0.2 ~ 0.5 mm.

When the length of the light irradiation needle 36 is less than 60 mm, the needle does not reach the diaphragm of lung tissue, and when the length exceeds 150 mm, the length of the needle is longer than necessary, so it is inconvenient to use. For this reason, it is preferable to make the needle length 60-150 mm.

The light irradiation needle 36 is used for one time for hygiene of the patient, and is removable.

The needle holder 39 is mounted at the rear end of the light irradiation needle 36.

The needle holder 39 is composed of a holder body 40 having a fixing hole therein, and a fixed blade 41 integrally formed at both sides of an outer surface of the holder body 40.

The needle holder 39 connects the rear end of the needle and the front end of the second optical cable 24b through the fixing hole of the holder body 40, and the connection cap 46 is connected to the rear end of the needle holder 39. The screw is fastened, and the second optical cable 24b may pass through the needle holder 39 and be inserted into the light irradiation needle 36 through the through hole of the connection cap 46.

The holder body 40 of the needle holder 39 is cylindrical and easy to hold and aim by hand so that the needle 36 can invade accurately and easily to the affected part, and the fixed blade 41 is a holder. It is formed in both vertical directions at the rear end of the body 40, it is easy to be fixed to the body by a fixed blade 41.

Here, the light irradiation needle 36, the needle holder 39, the first optical cable 24a is easy to be detached and used as a single module for easy operation.

In addition, the portable power supply 42 may be used to supply power to the LED package instead of the multi-type power supply 10.

The portable power supply device 42 includes a power supply housing 43 having a terminal portion therein, and a power socket 44 formed on one side of the power supply housing 43, and a battery in the terminal portion of the power supply housing 43. Inserted and mounted (45), it is possible to supply power to the battery 45 by connecting the power connection line 12 to the power socket 44 connected to the terminal portion.

Referring to the method and operation of the medical LED light irradiation apparatus of the present invention by such a configuration as follows.

A photosensitizer (photosensitive material) is injected into a patient with lung cancer, and the administered photosensitizer selectively accumulates only in the place where a tumor develops in the patient's body, for example, in the diaphragm of the lung tissue. .

Press the start button 17 installed on the power supply body of the multi-connected power supply 10 or press the pedal 19 to turn on the power of the multi-connected power supply 10.

Then, the plurality of light irradiation needles 36 accurately invade the affected surface at various angles such that the plurality of LED lights are simultaneously irradiated to the diaphragm of the lung tissue in which the tumor is generated, and then the LED is controlled using the power adjusting unit 13. Adjust the power supply according to its characteristics, for example LED light wavelength.

The current and voltage adjusted by the power adjusting unit 13 are displayed on the display unit 15, and the control unit built in the multi-connect type power supply device 10 is preset to display the current and voltage displayed on the display unit 15. Is applied to the leader line 30 of the LED package 22 through the power connection line 12, the LED chip 26 emits light as power is applied through the leader line (30).

The light emitted from the LED chip 26 is collected through the condenser lens 32 and transmitted to the first optical cable 24a. The second optical cable 24b connected to the first optical cable 24a is the first optical cable 24a. LED is received through the) and delivered to the light irradiation needle 36.

The light irradiation needle 36 has a length in the range of 60 to 150 mm to reach the periphery of the diaphragm of lung tissue that the endoscope cable does not reach, and a plurality of light irradiation needles 36 are applied to the affected surface at various angles. Invaded, the light irradiation is made at the same time in one of the affected areas through a plurality of light irradiation needle (36).

As such, when a plurality of LED light is irradiated at one place of the tumor occurred at multiple angles at the same time, the light output is reduced as the diameter of the second optical cable 24b connected to the light irradiation needle 36 is reduced It can compensate for this and deliver proper light energy.

The light irradiated to the affected area through the light irradiation needle 36 has an appropriate energy and wavelength, and the light having the appropriate energy and wavelength activates a photosensitizer (photosensitive material) accumulated in the diaphragm to release active oxygen. In this way, tumor cells can be selectively necrosed by free radicals.

The multi-connected power supply 10 may use existing power and may supply power to the LED package 22 using a portable power supply 42 instead of the multi-connected power supply 10. have.

Therefore, according to the present invention, by irradiating light to the affected area using a low-cost and semi-permanently usable LED, it is possible to manufacture a light irradiating device for photodynamic therapy and low power light therapy at a low cost, and extend the life of the device. Can be.

In addition, by adjusting the current and voltage by the multi-connected power supply 10 to apply to the LED, by implementing the LED light having a light output range of mW class up to 2W for each disease, photodynamic therapy And low power therapeutic light irradiator at the same time to reduce the cost of separate use of conventional photodynamic therapy laser device and low power laser therapy laser device, and because it does not need to provide a separate light therapy device It can be used to reduce the economic burden when treating various cancers.

In addition, the multi-connected power supply 10 includes at least five or more power outlets (power sockets 11), and separates power by connecting power connection lines 12 to a plurality of LED packages, respectively. By supplying by supplying a single or a plurality of light irradiating devices according to each disease, it is possible to irradiate light to several affected areas at the same time can effectively perform the treatment can maximize the therapeutic effect.

In addition, the housing 25 of the LED package 22 is formed in a spiral structure on each of the plurality of power connection lines 12 to increase the heat dissipation area, and the package is made of a metal material such as aluminum or copper having excellent heat dissipation performance. Since a separate heat dissipation system is not needed to dissipate heat generated during the discharge, the treatment device can be manufactured at low cost by reducing the volume and reducing the cost of the heat dissipation system.

In addition, by providing a plurality of power sockets 11 in the multi-connected power supply 10 and compensating the length of the limited optical cable 24 through the extension of the power connection line 12 connected to the power sockets 11, respectively. In the conventional photodynamic therapy and low power laser therapy laser device, the length of the optical cable 24 defined by the main body can be solved the problem that the optical treatment was possible only within a certain distance.

In addition, the light irradiation needle 36 made longer than the general needle is mounted on the end of the optical cable 24, and at the same time the light irradiation needle 36 at various angles invade the affected surface for endoscopy when treating lung cancer By precisely irradiating light into the diaphragm of lung tissue that the cable does not reach, lung cancer patients whose tumors are in the diaphragm which cannot be surgically operated and the endoscopic optical cable 24 does not reach the affected area and the photodynamic therapy is unavoidable are also performed. can do.

10: power supply for multi connection type 11: power socket
12: power connection line 13: power control unit
14: timer adjustment button 15: display unit
16: Operation indicator 17: Start button
18: Stop button 19: Pedal
20: light source unit 21: power connection
22: LED package 23: fiber optic connection
24: optical cable 24a: first optical cable
24b: second optical cable 25: housing
26: LED chip 27: protrusion
28: receiving groove 29: Teflon injection
30: lead wire 31: wire
32: condenser lens 33: flange portion
34: condenser 35: optical fiber fixing
36: needle for light irradiation 37: first optical cable connector
38: second optical cable connector 39: needle holder
40: holder body 41: fixed wing
42: portable power supply device 43: power supply housing
44: power socket 45: battery
46: connection cap

Claims (11)

A multi-connected power supply 10 for supplying power;
An LED package 22 receiving power from the multi-connected power supply 10 to generate light;
An optical cable 24 connected to the LED package 22 to transmit light; And
A light irradiation needle 36 connected to the optical cable 24 for irradiating light to the affected part;
Medical LED light irradiation apparatus comprising a.
The method according to claim 1,
The multi-connected power supply 10 includes a plurality of power sockets 11 for connecting a plurality of power connection lines 12 separately to supply a plurality of powers to the LED package 22;
A power adjusting unit 13 for adjusting the power according to the light wavelength of the LED package 22;
A display unit 15 displaying power supplied to the LED package 22;
Medical LED light irradiation apparatus comprising a.
The method according to claim 1,
The LED package 22 is disposed between the power connection line 12 and the optical cable 24,
A housing 25 having a leader line 30 mounted therein;
An LED chip (26) which is mounted in a receiving groove (28) concave at one end of the housing (25) so as to be connected to the leader line (30) and generates light;
A condenser lens 32 mounted to one end of the housing 25 to cover the receiving groove 28 and condensing the light generated from the LED chip 26 and outputting the light to the optical cable 24;
Medical LED light irradiation apparatus comprising a.
The method according to claim 3,
Before mounting the LED chip 26, a Teflon injection 29 is mounted on the mounting seat of the LED chip 26 to dissipate heat generated from the LED chip 26, and exaggerates the LED chip 26. Medical LED light irradiation apparatus characterized in that the current flows to prevent the short-circuit current to the housing 25 when a short occurs.
The method according to claim 1,
The LED package 22 is detachably coupled to the power connector 21 connected to the power connection line 12 of the multi-connect type power supply 10 to receive power from the power supply 10. A front end portion is detachably coupled to the optical fiber connecting portion 23 connected to the optical cable 24 to emit light to the optical cable 24, and the power connection portion 21 and the optical fiber connecting portion 23 are formed in a spiral structure on an outer side thereof. Medical LED light irradiation apparatus, characterized in that the heat radiated heat generated from the LED package (22).
The method according to claim 1,
The light irradiation needle 36 has a length of 60 to 150 mm and a diameter of 0.2 to 0.5 mm, and invades to the periphery of the diaphragm to treat light generated in the diaphragm of lung tissue, and transmits light. LED light irradiation device.
The method according to claim 1,
The LED package 22 generates light at a light output of 100 to 2000 mW and a light wavelength of 530 to 745 nm and a light output of 1 to 100 mW and a wavelength of 530 to 745 nm for low power treatment. Medical LED light irradiation device.
The method according to claim 3,
The housing 25 is a medical LED light irradiation apparatus, characterized in that the outer surface is made of a spiral structure to increase the heat dissipation area.
The method according to claim 1,
Using a plurality of light irradiation needles 36 connected to the multi-connected power supply 10, each light irradiation needle 36 invades the affected surface at a plurality of angles to simultaneously irradiate one affected area with light. Medical LED light irradiation apparatus, characterized in that.
The method according to claim 1,
The optical cable 24 is a first optical cable 24a connected to the LED package 22 and the first optical cable 24a is detachably mounted at the rear end, and the light irradiation needle 36 is mounted at the front end. It consists of a second optical cable (24b), including the second optical cable (24b) connected to the back and the needle holder 39 and the light irradiation needle (36) can be used for replacement only once Medical LED light irradiation apparatus characterized in that.
The method according to claim 1,
The light irradiation needle 36 is a medical LED light irradiation apparatus, characterized in that the needle holder (39) is easy to hold and aim at the rear end by hand.

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