KR102024334B1 - Far infrared ray radiation suture line, manufacturing divece and method the same - Google Patents

Abstract

The present invention is a high pressure tank in which the suture is disposed in the inner space, the pressure inside the high pressure tank to 7 to 10kg / ㎠, and the pressure control unit for reducing the pressure in the high pressure tank within atmospheric pressure after a set time, far infrared rays Mineral powder that has a particle size of 6.5 μm to 1.3 μm, a powder container for accommodating the mineral powder, a stirring blade for stirring the powder inside the powder container, a stirring motor for rotating the stirring blade, and the powder container An electromagnetic radiation radiating unit for irradiating electromagnetic waves to the mineral powder inside the powder container at one side, a far-infrared radiating unit disposed in the high pressure tank, and the suture being disposed and sliding into the internal space of the high pressure tank, the tray Comprising a tray rotating motor for rotating the It provides a far infrared radiation suture manufacturing apparatus and method comprising a suture rotation unit and a far infrared radiation suture manufactured thereby.

Description

Far infrared ray suture, apparatus and method for manufacturing the same {FAR INFRARED RAY RADIATION SUTURE LINE, MANUFACTURING DIVECE AND METHOD THE SAME}

TECHNICAL FIELD The present invention relates to a medical suture for radiating far infrared rays, an apparatus and a manufacturing method thereof.

Suture is a surgical thread used to collect the cut body tissue and keep it in its normal position until the wound heals.

Suture is composed of PGA suture made by twisting several strands and PDO suture made of one strand. PGA suture has the advantage of flexibility and elasticity because it is twisted by several strands, but the surface is rough and there is space between the threads. In contrast to PGA sutures, PDO sutures are less flexible and resilient because they are easier to infect with bacteria. On the other hand, PDO sutures are mainly used in recent years because they have smoother surfaces and fewer bacterial infections than PGA sutures.

However, in case of PDO suture, there is a disadvantage that the thread cannot be loosened or easily knotted after surgery due to less flexibility and elasticity. Thus, a copolymer suture is developed to compensate for this, while silver nano and antimicrobial agents are manufactured when manufacturing PGA suture or PDO suture. The development of the technology of suture for improving the function of improving the strength, flexibility and the like by adding the back is actively progressing.

The following are the conditions for sutures:

Sutures must be adequately tensioned and resilient until their purpose is achieved, and they should not cause reactions in the tissues and create an environment conducive to the growth of bacteria, bacteria, and viruses. In addition, allergies, capillary phenomena, hypersensitivity reactions and carcinogenicity should not be possessed, and sutures should be convenient to handle, the knot or olea should not be easily released or broken, and the cutting force should be good after the knot. B. Ingredients should not be altered.

In addition, how much strength is needed and for how long the suture should maintain this strength is important, and because the tension gain and scar remodeling are slow, the sutures are also needed for some time to achieve tissue union. This is because the material needs to maintain tension or elasticity continuously.

As such, surgical sutures are classified into absorbent sutures (biodegradable sutures) and non-absorbable sutures, depending on the material used as a medical means mainly used to fix an implant (seam) that sutures or inserts tissues in a surgical operation.

The selection of the appropriate material should be based on an understanding of the healing process, and in most cases nonabsorbable sutures can be the nucleus of the infection, so it is advisable to use absorbent sutures for contaminated or potentially suspicious wounds and internal sutures. . In the case of absorbent sutures, the reactivity with tissue is much stronger, and non-absorbable sutures should be used if a minimal tissue reaction is required.

On the other hand, the meditation procedure is also called meditation therapy, and it does not incise the skin of the body and pulls the skin or muscles tightly to improve wrinkles or to maintain the elasticity of the skin tissue as well as to maintain a stable state by stretching the ligaments. It is widely used in the procedure to make it possible.

Suture is absorbed after 3 to 6 months after the procedure in the body. The suture is a factor that causes wound irritation in the skin, which induces the release of immune substances that heal the wound. After the body tissue is healed, it is possible to continuously maintain the pulled (lifted) state by the suture, so that the sagging skin is kept in a taut state or stretched to obtain an effect of improving.

Republic of Korea Patent Publication No. 10-2016-0053252 (Published: 2016.05.13) Republic of Korea Patent Publication No. 10-2014-0147683 (Published: 2014.12.30) Republic of Korea Patent Publication No. 10-2001-0089357 (published: 2001.11.08)

An object of the present specification is to provide a suture capable of emitting far infrared rays to skin tissue after being inserted into the skin.

An object of the present specification is to provide a suture production apparatus capable of emitting far infrared rays.

An object of the present specification is to provide a suture manufacturing method capable of emitting far infrared rays.

In order to solve the above problems, according to one embodiment of the present specification, a high pressure tank in which a suture is disposed in an inner space;

A pressure regulating unit for pressurizing the pressure inside the high pressure tank to 7 to 10 kg / cm 2 and reducing the pressure within the high pressure tank to within atmospheric pressure after a set time elapses;

Mineral powder that emits far infrared rays and has a particle size of 6.5 μm to 1.3 μm, a powder container containing the mineral powder, a stirring blade for stirring the powder inside the powder container, a stirring motor for rotating the stirring blade, and the A far infrared radiation unit including an electromagnetic radiation unit for irradiating electromagnetic waves to the mineral powder inside the powder container from one side of the powder container, the far infrared radiation unit disposed in the high pressure tank; And

The suture is disposed and provides a far-infrared radiation suture manufacturing apparatus comprising a suture rotation unit including a tray that slides into the inner space of the high pressure tank, the tray rotating motor for rotating the tray.

The stirring blade is characterized in that the material of far-infrared radiation minerals.

The suture is characterized in that a biodegradable polymer.

The sutures are catgut, polyglycolic acid, lactic acid polymer, polyether-ester, copolymer of lactide and glycolide, copolymer of diethylene glycol and glycolide and trimethylene carbonate (e.g., Ternary copolymer consisting of MAXONTM, Tyco Healthcare Group, glycolide, trimethylene carbonate, and dioxanone, glycolide, caprolactone, trimethylene carbonate, and lactide Characterized in that the material is selected from the group containing the coalescence.

The suture is characterized in that it is disposed in the high pressure tank in a sterile packaging state.

According to another embodiment of the present invention,

In a degradable suture that denatures when heated, the suture provides a far infrared radiation suture that emits far infrared rays.

The suture is characterized in that the pressurized at a pressure of 7 to 10kg / ㎠ in the high-pressure tank of the far-infrared radiation suture manufacturing apparatus of claim 1.

According to another embodiment of the present invention,

a) placing the mineral powder emitting far infrared rays in a high pressure tank;

b) placing a suture made of thermoplastic polymer in the high pressure tank;

c) sealing the high pressure tank and maintaining an internal pressure of the high pressure tank at 7 to 10 kg / cm 2; And

d) providing a far-infrared radiation suture manufacturing method comprising the step of stirring the mineral powder in the high pressure tank.

The suture manufactured by the apparatus and method for producing far-infrared radiation sutures may emit far infrared rays into skin tissue after being inserted into the skin.

The suture manufactured by the apparatus and method for producing a far infrared ray suture may emit far infrared rays from the suture itself, which is biodegradable in skin tissue after being inserted into the skin without including minerals emitting far infrared rays. Therefore, the suture does not contain foreign matter other than the biodegradable material can prevent the side effects occur in the skin tissue.

Far-infrared rays may be emitted from the medical suture itself without heating the medical suture made of protein or polymer material that is denatured by heat.

1 is a block diagram schematically showing an apparatus for manufacturing far-infrared radiation suture according to an embodiment of the present specification.
Figure 2 is a view schematically showing a device for producing far-infrared radiation suture according to an embodiment of the present disclosure.
Figure 3 is a flow chart schematically showing a method for manufacturing a far infrared radiation suture according to an embodiment of the present disclosure.
Figure 4 is a photograph of a patient undergoing a stapling procedure using a suture and a conventional suture emitting far infrared rays according to an embodiment of the present disclosure.

Hereinafter, the present invention will be described in more detail with reference to Examples. Since these examples are only for illustrating the present invention, the scope of the present invention is not to be construed as being limited by these examples.

1 is a block diagram schematically showing a device for producing far-infrared radiation suture according to an embodiment of the present invention, Figure 2 is a view showing a device for producing far-infrared radiation suture according to an embodiment of the present invention.

As shown, the far-infrared radiation suture manufacturing apparatus 1000 is a high pressure tank 110 in which the suture 2000 is disposed in the inner space, a pressure control unit 200 for adjusting the pressure inside the high pressure tank 110, high pressure tank Far-infrared radiation unit 300 disposed in the 110, the temperature control unit 500 for adjusting the temperature inside the high pressure tank 110, the suture rotating unit 400 for rotating the suture in the high pressure tank 110, high pressure tank 110 includes a sensing unit 600 for sensing the temperature and / or pressure inside and the control unit 100 for controlling the pressure and temperature inside the high pressure tank.

Suture according to an embodiment of the present disclosure processed in the high pressure tank 110 is preferably to use a decomposable suture. Biodegradable suture material (also referred to as "biodegradable" or "bioabsorbable") refers to a suture that is degraded and absorbed by the body after introduction into human tissue. Typically, the degradation process is carried out at least partially in the biological system. "Decomposition" refers to a chain separation process in which the polymer chain is cleaved into oligomers and monomers. Chain separation can occur via a variety of mechanisms, including, for example, by chemical reactions (eg, hydrolysis, oxidation / reduction, enzymatic mechanisms or combinations thereof) or by thermal or photolysis processes. Polymer degradation can be characterized using, for example, gel permeation chromatography (GPC), which monitors changes in polymer molecular mass during erosion and degradation. Degradable suture materials include catgut, polyglycolic acid, lactic acid polymers, polyether-esters (e.g. polyglycol and polyglycolide, polyether and polyglycolide, polyglycol and polylactic acid or polyether and poly) Copolymers of lactic acid), copolymers of lactide and glycolide, copolymers of diethylene glycol and glycolide and trimethylene carbonate (e.g., MAXONTM, Tyco Healthcare Group), glycols Ternary copolymers consisting of reed, trimethylene carbonate, and dioxanone (eg, BIOSYNTM [glycolide (60%), trimethylene carbonate (26%), and dioxanone (14%) ], Tyco Healthcare Group), glycolide, caprolactone, trimethylene carbonate, and copolymers of lactide (eg, CAPROSYN ™, Tyco Healthcare Group) . Such sutures may be in the form of braided multifiber or in the form of short fibers. Polymers used in the present invention may be linear polymers, branched polymers or multiaxial polymers. Examples of multiaxial polymers used in sutures are described in US Patent Application Publication Nos. 20020161168, 20040024169, and 20040116620. Degradable sutures may also include soluble sutures made of soluble polymers such as, but not limited to, polyvinyl alcohol partially deacetylated polymers, for example. The suture may consist of a suture thread on the fibre and a needle having a sharp point. The suture 2000 is preferably sterilized and packaged in the high pressure tank 110 in the far-infrared.

The high pressure tank 110 is composed of a cylindrical pressure vessel 111 configured to withstand high pressure of 10 kg / cm 2 or more and a door 112 for entering and exiting the suture 2000. The door 112 is preferably formed on one side of the pressure vessel 111 to be opened and closed circumferentially, improving the sealing property to withstand the high pressure of 10kg / ㎠ or more to the contact area between the pressure vessel 111 and the door 112. Configuration is applied. In the high-pressure tank 110, it is preferable that the tray 410 on which the biodegradable suture 2000 is placed is installed to be accessible through the door 112 by sliding on the bottom surface.

The pressure regulating unit 200 is provided with a pressurizing means and a decompression means and connected to the inside of the high pressure tank 110 to pressurize the internal pressure within a short time by a pressurized medium such as argon gas by a pressurizing means to the high pressure tank 110. It can pressurize to / cm2, and can reduce the pressure within atmospheric pressure (1kg / cm2) by the decompression means after the far-infrared treatment is completed.

The temperature control part 500 is provided with a cooling means so that the temperature rise caused by the pressure inside the high pressure tank 110 does not damage the suture 2000 of the protein or polymer material being processed in the high pressure tank 110. It can be kept within range.

The far infrared radiation unit 300 includes a far infrared radiation mineral powder 360, a powder container 310, a stirring blade 320, a stirring motor 340 for rotating the stirring blade 320, the electromagnetic radiation unit 350. .

Far-infrared mineral powder 360, the mineral powder is jade, jade, tourmaline, loess, biotite, amethyst, raw ore, bamboo charcoal, Uranite, precious stone, obsidian, ganbanite, ore, lava gemstone, quartz, monzoite, gneiss Or at least one mineral selected from the group consisting of rhyolite tuff, strontium, vanadium, zirconium, cerium, neodymium, lanthanum, barium, rubidium, cesium, and gallium into fine particles of 6.5 μm or less. Mineral powders are preferably smaller in size. The mineral powder preferably has a particle size of 6.5 μm to 1.3 μm. As the mineral powder, it is preferable to use jade or jade powder because of its high far-infrared radiation efficiency.

The powder container 310 is made of tempered glass, polypropylene (PP), polyethylene (HDPE), crystallized polyethylene terrestrial to withstand electromagnetic waves and high pressure so that far-infrared rays are transmitted through the mineral powder contained therein without loss and are irradiated to the suture 2000. It is preferably made of a phthalate (C-PET) material.

The stirring blade 320 is preferably formed of the above-mentioned far-infrared radiation mineral. The stirring blade 320 may be installed and rotated in the powder container 310 to enhance the far-infrared radiation efficiency by stirring the powder 360. By stirring, the far-infrared radiation efficiency is improved due to the friction between the stirring blade 320 and the mineral powder 360 and the mineral powder 360 made of the far-infrared radiation mineral.

The electromagnetic wave radiator 300 is composed of a magnetron and a waveguide, and is installed on one side of the powder container 310 to emit microwaves of 2.45 GHz in the mineral powder 360 accommodated in the powder container 310. Mineral powder increases the radiation efficiency of far infrared rays when electromagnetic wave is irradiated.

The suture rotating part 400 is composed of a tray 410 on which the suture 2000 installed on the inner bottom of the high pressure tank 110 is placed, and a tray rotation motor 420 rotating the tray 410. Rotating the far-infrared to the suture (2000) to be evenly irradiated.

The sensing unit 600 includes a temperature sensor and a pressure sensor for measuring the temperature and the pressure inside the high pressure tank 110.

The control unit 100 is connected to the pressure control unit 200, far-infrared radiation unit 300, temperature control unit 500, suture rotation unit 400, the detection unit 600, the high pressure tank according to the user's operation command A control signal is applied to the pressure regulating unit 200 and the temperature adjusting unit 500 to adjust the temperature and the pressure in the 110, and the stirring motor 340 and the electromagnetic wave shield so that far infrared rays are effectively radiated from the far infrared radiating unit 300. The control signal is applied to the dead part 350, and a control signal is applied to the tray rotating motor 420 so that the tray on which the suture 2000 is placed is rotated during the far infrared ray processing.

Figure 3 is a flow chart schematically showing a method for manufacturing a far infrared radiation suture according to an embodiment of the present disclosure. Referring to Figure 3 describes the far-infrared radiation suture manufacturing method using the far-infrared radiation suture manufacturing apparatus configured as described above are as follows.

The mineral powder 360 emitting far infrared rays is disposed in the powder container 310 in the high pressure tank 110 (S10). Next, the suture 2000 of the biodegradable polymer material is placed on the tray 410 to slide into the high pressure tank 110 (S20). Thereafter, the high pressure tank 110 is sealed to the door 112 and the pressure adjusting unit 200 is driven to press the internal pressure of the high pressure tank 110 to 7 to 10 kg / cm 2 (S30). . Higher pressures reduce processing time. Pressurization is carried out for 1 to 2 hours.

When the internal pressure of the high pressure tank 110 reaches the set pressure, the stirring motor 340 is driven to rotate the stirring blade 320 in the mineral powder container 310 inside the high pressure tank to stir the mineral powder 360. (S40). If the friction occurs between the mineral powder and the mineral powder and the stirring blade by the rotation of the stirring blade 320 increases the far-infrared radiation amount.

Along with the stirring of the step S40, by driving the electromagnetic radiation unit 350 installed on the mineral powder container 310, irradiating the electromagnetic powder to the mineral powder 360 (S41). Mineral powder increases far-infrared radiation when electromagnetic wave is irradiated.

The suture 2000 disposed inside the high pressure tank 110 is disposed on the rotary tray 410, and the rotary tray 410 is rotated according to the drive of the tray rotating motor 420 so that the suture 2000 is connected to the high pressure tank ( 110) to be rotated inside (S42). Rotating the suture while stirring the mineral powder so that far infrared rays are evenly irradiated under high pressure.

After the set time, preferably 1 to 2 hours, the pressure regulator 200 depressurizes the inside of the high pressure tank 110 to be within atmospheric pressure (S50).

The far-infrared ray-treated suture 2000 slides out the tray 410 and is taken out of the high pressure tank 110 (S60).

The far-infrared radiation suture manufacturing apparatus according to an aspect of the present invention is irradiated with an electromagnetic wave to the stirrer 320 and the far-infrared radiation mineral powder 360 to agitate the mineral powder 360 is composed of the far-infrared radiation portion 300 is far infrared radiation minerals It further comprises an electromagnetic wave radiation unit 350, so that sufficient far-infrared rays are emitted without polishing the particle size of the mineral powder to a nano size. The handling of mineral powders becomes easier and the cost can be reduced.

Sutures may be inserted into the skin layer by methods conventionally used in the art. Sutures may be placed in the high pressure tank, with one or both ends coupled to a needle and sealed in a sterile pouch. The suture may be manufactured in a braided manner and a monofilament manner depending on the manufacturing method.

Far-infrared radiation suture according to an aspect of the present invention to enhance the biological activity in the affected area by radiating far infrared rays in the skin during the procedure.

Far infrared rays are electromagnetic waves that are farthest from visible light when the infrared region is subdivided according to wavelengths, that is, the longest wavelength and the lowest frequency. It exists in the wavelength range of 0.76 ~ 1,000㎛ is called far infrared rays, which is included in 4-15㎛, the intrinsic absorption wavelength band of all living organisms composed of organic compounds.

Far infrared rays are radiated to the water and protein molecules that make up the cells in the human body and resonate with minute vibration about 2,000 times a minute to make the activity of the cells vigorous. In the process of cell activity, heat energy is generated, which increases body temperature.As the body temperature increases, microvascularization expands and blood circulation is activated, and the metabolism is strengthened, and tissue regeneration power increases to break down blood clots in blood vessels and promote blood circulation. do.

It causes biological activity or boils water clusters to enhance the biological activity of the organism.

Figure 4 is a photograph of the neck of the patient who performed the stapling procedure, A side was performed by the far-infrared radiation suture, B side was performed by the general suture. When performing a stapling procedure using a far infrared radiation suture, it can be seen that the swelling of the affected area is significantly less. In addition to the swelling, the lifting effect of the percutaneous procedure was also superior to the use of far-infrared sutures.

As used herein, the term "skin" refers to an organ covering the outside of an organism, and is composed of the epidermis, the dermis and the subcutaneous fat layer and includes the scalp and hair as well as the tissue covering the outside of the face or the entire body. Concept.

As used herein, "suture" means a thread that can be inserted into the skin for medical or cosmetic purposes, without limiting its shape.

As used herein, "lifting" means pulling or pulling up the skin by a suture, and the lifting may be performed by protrusions, knots or clasps included in the suture. The suture herein may have the effect of physically improving or removing wrinkles on the skin surface by lifting. Specifically, in one aspect of the present invention, the suture is inserted in the epidermis, dermis or subcutaneous fat layer in the sagging or crumpled skin to lift the wrinkled skin layer by protrusions, knots or clasps that the suture contains. I can lose it.

Claims (14)

High pressure tank in which the suture is disposed in the inner space;
A pressure regulating unit for pressurizing the pressure inside the high pressure tank to 7 to 10 kg / cm 2 and reducing the pressure within the high pressure tank to within atmospheric pressure after a set time elapses;
Mineral powder that emits far infrared rays and has a particle size of 6.5 μm to 1.3 μm, a powder container containing the mineral powder, a stirring blade for stirring the powder inside the powder container, a stirring motor for rotating the stirring blade, and the A far infrared radiation unit including an electromagnetic radiation unit for irradiating electromagnetic waves to the mineral powder inside the powder container from one side of the powder container, the far infrared radiation unit disposed in the high pressure tank; And
The suture is disposed and includes a suture rotating unit including a tray for sliding and entering the inner space of the high pressure tank, a tray rotating motor for rotating the tray,
The stirring blade is made of a far-infrared radiation mineral,
The electromagnetic radiation unit is far infrared radiation suture manufacturing apparatus disposed in the high pressure tank. delete The method of claim 1,
The suture is a far-infrared radiation suture manufacturing apparatus, characterized in that the biodegradable (Biodegradable) polymer. The method of claim 1,
The suture is catgut, polyglycolic acid, lactic acid polymer, polyether ester, copolymer of lactide and glycolide, copolymer of diethylene glycol and glycolide and trimethylene carbonate, glycolide, tri An apparatus for producing far-infrared radiation sutures, comprising a material selected from the group consisting of methylene carbonate, a ternary copolymer consisting of dioxanone, glycolide, caprolactone, trimethylene carbonate, and a copolymer of lactide. The method of claim 1,
The suture is far infrared radiation suture manufacturing apparatus disposed in the high pressure tank in a sterile packaging state. delete delete a) placing the mineral powder emitting far infrared rays in a high pressure tank;
b) placing a suture made of thermoplastic polymer in the high pressure tank;
c) sealing the high pressure tank and maintaining an internal pressure of the high pressure tank at 7 to 10 kg / cm 2; And
d) stirring the mineral powder in the high pressure tank,
The step d) is made of a far-infrared radiation mineral, and the stirring is performed by stirring the mineral powder with a blade, further comprising the step of irradiating the electromagnetic powder to the mineral powder,
The electromagnetic wave radiation unit is disposed in the high pressure tank,
The blade is connected to the stirring motor is a far-infrared radiation suture manufacturing method for stirring the mineral powder. The method of claim 8,
The mineral powder is far infrared ray suture manufacturing method having a particle size of 6.5㎛ 1.3㎛. The method of claim 9,
Far infrared radiation suture manufacturing method of irradiating the electromagnetic wave to the mineral powder in step d). The method of claim 8,
The d) step is far infrared radiation suture manufacturing method characterized in that performed for 1 hour or more. The method of claim 8,
Far-infrared radiation suture manufacturing method, characterized in that for rotating the suture in the high pressure tank in step d). The method of claim 8,
In step b), the suture is far infrared radiation suture manufacturing method disposed in the high pressure tank in a sterile packaging state. In a degradable suture that denatures when heated,
The suture is far-infrared radiation suture produced by the method of any one of claims 8 to 13 to radiate far infrared rays.

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