KR101105647B1 - Biological Decomposition Insertion Device for Muscle Strengthening - Google Patents

Abstract

Disclosed is a muscle strengthening biodegradable fiber yarn inserting device. The muscle-reinforced biodegradable fiber yarn inserting apparatus of the present invention includes a biodegradable fiber material, which is provided in a thread shape, and is inserted into muscles in the human body to induce native substances in the human body; A needle provided in a pipe shape and having the muscle-reinforced biodegradable fiber yarn inserted into the insertion hole such that at least a portion of the muscle-reinforced biodegradable fiber yarn is exposed to the outside of the insertion hole formed in the longitudinal direction; A fiber yarn fixing portion detachably coupled to the needle and preventing the detachment of the muscle-enhanced biodegradable fiber yarn from the needle by fixing the muscle-reinforced biodegradable fiber yarn exposed to the outside of the insertion hole to the needle; And it characterized in that it comprises a handle unit coupled to the needle. According to the present invention, since the muscle-strengthened biodegradable fibres, which are thinner than conventional ones, are inserted into the muscles, the muscle-reinforced biodegradable fibres can be inserted to double the muscle strengthening effect while reducing the degree of pain felt by the patient. The insertion process can be performed without any separate process of cutting muscle-enhanced biodegradable fibres, which not only suppresses the occurrence of infection, but also simplifies the insertion process and also prevents the release of muscle-enhanced biodegradable fiber from the needle. Packaging, sterilization, storage and transportation can be carried out reliably.

Description

Biological Decomposition Insertion Device for Muscle Strengthening}

The present invention relates to an apparatus for inserting muscle-reinforced biodegradable fibres, and more particularly, to strengthen muscle-reinforced biodegradable fibres, which can be easily inserted into the muscle without great pain, while improving the muscle strengthening effect compared to the conventional art. It relates to a biodegradable fiber yarn inserting device.

In general, there is resistance to disease in the human body and self-healing ability to treat the disease on its own. Self-healing ability refers to a self-supporting ability that is naturally generated in the body and maintains human health.

Within the human body, there is a resistance to disease and self-healing ability to treat the disease on its own. Self-healing ability refers to the ability to grow naturally in a person's body and maintain a person's health. These self-healing abilities include, for example, the ability to keep the body warm as the sweat glands open when the body is fevered, or to vomit when eating large amounts or spoiled foods. Its ability to protect organs and restore them to normal activities, or to control the pH of calcium ions by eluting to prevent immunity from disease when blood is acidified.

In the muscle fibers forming the muscles of the human body, there is a native substance having the aforementioned self-healing ability. Therefore, even if foreign matter enters the muscles, foreign substances gather around the foreign matter, which serves to protect the muscles from foreign matters. These native substances are produced to protect muscles, but also serve to strengthen muscles.

On the other hand, modern people are not only weak in physical strength due to various stress, lack of exercise or overeating, but also weak muscles of the body due to wrong lifestyle. At this time, in order to strengthen the muscles, the native substances in the muscles should fully function, if the muscles are significantly weakened, there is a problem that does not sufficiently strengthen the strength of the muscles as the native substances generated in the muscles.

Therefore, in order to solve this problem, recently, a method of artificially injecting an injection chamber into a muscle so that native substances can gather around the weakened muscle is considered, and a muscle strengthening chamber that can be used when applying such a method is considered. An insertion device has been introduced. Briefly described, when the injection chamber is inserted into the muscle of the human body using the muscle reinforcement chamber inserting device to induce autogenous substances to gather around the injection chamber, muscle and ligaments can be strengthened, thereby preventing musculoskeletal disorders. It can be treated more efficiently, can increase immunity, and can also strengthen the connective tissue of the skin to keep the skin elastic.

However, in the conventionally introduced muscle strengthening chamber inserting device, the injection chamber inserted into the muscle is thick and stiff, so that it is difficult to bend the end of the procedure for easy insertion into the muscle, and the injection chamber is inserted into the muscle strengthening chamber. In order to prevent random departure from the device, the exposed portion of the scanning chamber was bent outside of the posterior end of the needle. In this case, because the scanning chamber is longer than the syringe, a portion of the exposed scanning chamber cannot be inserted completely into the muscle. The blood flows out and the hemostasis may not be good, and because the exposed injection chamber has to be cut with scissors, the second infection may occur during the insertion process. In addition, in order to prevent such a problem, it is necessary to insert the chamber after moving the chamber so that the length of the needle is shorter than that of the needle, that is, the rear end of the chamber is not exposed to the outside of the needle. There is a problem.

In addition, the scanning chamber is packaged, sterilized, stored, and transported while being accommodated in a pipe-shaped needle. In this process, the injection chamber may frequently be separated from the needle. The needle also had to be coarse and because of this, there was a problem that makes the patient feel pain in the process of being inserted into the muscle.

Therefore, while reducing the degree of pain that occurs when the injection chamber is inserted can improve the muscle strengthening effect than conventional, and also the insertion process can proceed without the separate process of cutting the injection chamber to suppress the occurrence of infection Development of muscle strengthening chamber insertion device that can simplify the insertion process and prevent the departure of the injection chamber from the needle to reliably carry out the process of packaging, sterilization, storage and transportation. This is necessary.

The purpose of the present invention is to insert the muscle-reinforced biodegradable fibres, which are thinner than conventional ones, so that the degree of pain felt by the patient can be reduced while the double muscle-reinforced biodegradable fiber yarns are inserted to double the muscle strengthening effect. The insertion process can be carried out without cutting the muscle-reinforced biodegradable fiber yarns, which not only suppresses the occurrence of infection, but also simplifies the insertion process, and also prevents the release of the muscle-reinforced biodegradable fiber yarns from the needle. It is thereby to provide a muscle strengthening biodegradable fiber inserting apparatus that can be reliably carried out the process of packaging, sterilization, storage and transportation.

According to the present invention, the biodegradable fiber material is provided in a thread shape, the muscle-reinforced biodegradable fiber yarn which is inserted into the muscles in the human body to induce autogenous substances in the human body; A needle provided in a pipe shape and having the muscle-reinforced biodegradable fiber yarn inserted into the insertion hole such that at least a portion of the muscle-reinforced biodegradable fiber yarn is exposed to the outside of the insertion hole formed in a longitudinal direction; A fiber yarn fixing part detachably coupled to the needle and stopping the detachment of the muscle-enhanced biodegradable fiber yarn from the needle by fixing the muscle-reinforced biodegradable fiber yarn exposed to the outside of the insertion hole to the needle; And it is achieved by the muscle strengthening biodegradable fiber yarn inserting apparatus comprising a handle unit coupled to the needle.

Here, the muscle-reinforced biodegradable fiber yarn exposed to the outside of the insertion hole of the needle and the muscle-reinforced biodegradable fiber yarn inserted into the insertion hole of the needle is bent at the tip of the needle, the fiber yarn fixing portion is A through hole equal to the outer diameter of the needle is formed through the thickness direction, and a part of the needle and a portion of the muscle-reinforced biodegradable fiber yarn exposed to the outside of the insertion hole of the needle penetrate through the through hole of the fiber yarn fixing part. Can be combined.

The length of the muscle-reinforced biodegradable fiber yarn exposed to the outside of the insertion hole of the needle may be shorter than the length of the muscle-reinforced biodegradable fiber yarn inserted into the insertion hole of the needle.

When the needle is penetrated and coupled to the fiber thread fixing part, the fiber thread fixing part may be coupled to the rear end of the needle to fix an end of the muscle-reinforced biodegradable fiber yarn exposed to the outside of the insertion hole of the needle. .

The fiber yarn fixing part may be made of sponge vinyl having elasticity.

The handle unit may be provided with a non-slip portion protruding from the surface and having a plurality of non-slip grooves to prevent sliding when gripping.

The handle unit, the non-slip portion is provided on the outer surface, the handle body gripped during the procedure; And a needle insertion unit provided at one side of the handle body, and having a needle insertion groove recessed to partially insert the needle.

The handle body may be provided to have a curved shape in which the central portion is drawn inward compared to both ends.

The needle insertion unit may include a needle insertion body provided at one side of the handle body and forming the needle insertion groove; And a plurality of wings which are provided to be spaced apart from each other along the outer circumferential surface of the needle insertion body and extend radially from the needle insertion body.

Both ends are provided in an open pipe shape, and may further include a needle protection tube detachably coupled to one side of the handle unit to surround the needle.

The tip portion of the needle may be provided with an inclined cutting portion inclined in the diagonal direction.

The handle unit is made of synthetic resin by injection molding, the needle can be detachably coupled to the handle unit.

According to the present invention, since the muscle-strengthened biodegradable fibres, which are thinner than conventional ones, are inserted into the muscles, the muscle-reinforced biodegradable fibres can be inserted to double the muscle strengthening effect while reducing the degree of pain felt by the patient. The insertion process can be performed without any separate process of cutting muscle-enhanced biodegradable fibres, which not only suppresses the occurrence of infection, but also simplifies the insertion process and also prevents the release of muscle-enhanced biodegradable fiber from the needle. Packaging, sterilization, storage and transportation can be carried out reliably.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings which illustrate preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

1 is a combined perspective view of the muscle-reinforced biodegradable fiber yarn insertion apparatus according to an embodiment of the present invention, Figure 2 is an exploded perspective view of Figure 1, Figure 3 is a needle in the muscle-reinforced biodegradable fiber yarn insertion apparatus shown in Figure 1 4 is a perspective view showing the disassembled protective tube, Figure 4 is a perspective view of the handle unit shown in Figure 1, Figure 5 is a perspective view showing a state in which the muscle-reinforced biodegradable fiber yarn shown in Figure 2 accommodated in the needle, 6 is a view schematically illustrating a process of inserting the needle of the muscle-reinforced biodegradable fiber yarn inserting apparatus shown in FIG. 1 into the muscle of the human body.

As shown in these figures, the muscle-reinforced biodegradable fiber yarn inserting apparatus 1 according to an embodiment of the present invention, the muscle-reinforced biodegradable fiber yarn is inserted into the muscles of the human body (see 3, 6) for muscle strengthening 10, a needle 20 which is elongated in a pipe shape and has an insertion hole 21 (refer to FIG. 2) for partially inserting and receiving the muscle-reinforced biodegradable fiber yarn 10 therein, and a needle ( 20 is detachably coupled and the handle unit 30 serving as a handle, the needle 20 and the muscle-reinforced biodegradable fiber yarn 10 exposed to the outside of the needle 20 through the insertion hole 21 By fixing the muscle-reinforced biodegradable fiber yarn 10 exposed to the outside of the needle to the needle 20, the fiber-fiber fixing portion 40 to prevent the muscle-reinforced biodegradable fiber yarn 10 from the needle 20, and Removably coupled to the handle unit 30 to protect the needle 20 It includes a needle protection tube 50.

Muscle-reinforced biodegradable fiber yarn 10 is a fiber harmless to the human body made of a poly monofilament violet material, etc., and is inserted into the muscle 3 to play a role of strengthening the weakened muscle 3. . Unlike the conventional injection chamber, the muscle-reinforced biodegradable fiber yarn 10 has a thin, soft, and easily bent property, so that the actual procedure can be performed accurately and easily, and the patient has less pain than the conventional injection chamber. I feel it.

The needle 20 is made of a material that is harmless to the human body because it is manufactured in a pipe shape so that the muscle-reinforced biodegradable fiber yarn 10 is inserted into the human body. In this case, since the muscle-reinforced biodegradable fiber yarn 10 is thinner than a conventional injection chamber, the diameter of the needle 20 may also be made smaller than that of the conventional injection chamber. Accordingly, in the process of inserting the needle 20 into the muscle 3, This feeling of pain has an effect that can be reduced than before.

The length of the needle 20 may be variously provided as 3cm to 12cm because the length of the muscle-reinforced biodegradable fiber yarn 10 is inserted according to the part of the human body. For example, a muscle-reinforced biodegradable fiber yarn inserting device 1 coupled with a relatively short needle 20 may be used for a part such as a hand or a foot, and a muscle-reinforced muscle combined with a long needle 20 for a part such as the abdomen. Biodegradable fiber thread inserting device 1 may be used.

In addition, the tip portion of the needle 20 to be inserted into the muscle 3 is provided with an inclined cut portion 22 inclinedly cut so that the needle 20 can be easily inserted into the muscle (3). On the other hand, the rear end of the needle 20 is detachably inserted and coupled to the handle unit 30 to be described later.

In the needle 20 having such a configuration, as described above, the muscle-reinforced biodegradable fiber yarn 10 is partially inserted and accommodated. More precisely, the muscle-reinforced biodegradable fiber yarn 10 is substantially inserted into the insertion hole 21 of the needle 20 and accommodated in the insertion hole 21, as shown in detail in FIG. 5. ) Is placed outside. At this time, the length of the muscle-reinforced biodegradable fiber yarn 10 accommodated in the insertion hole 21 of the needle 20 is slightly shorter than the length of the needle 20 and the length of the portion exposed to the outside is also the length of the needle 20 Slightly shorter than That is, the muscle-reinforced biodegradable fiber yarn 10 folded in half with respect to the tip portion of the needle 20, that is, the inclined cut portion 22, half of which is inside the needle 20, and the other half of the needle 20. It's going to be outside.

Therefore, when the needle 20 is inserted into the muscle 3 to insert the muscle-reinforced biodegradable fiber yarn 10 coupled to the needle 20 into the muscle 3, the muscle-reinforced biodegradable fiber yarn coupled to the needle 20. (10) can be completely inserted into the muscle (3) in two strands, which can almost improve the strengthening effect of the muscle (3) compared with the prior art.

In addition, conventionally, the length of the scanning chamber disposed in the needle (not shown) is disposed to be exposed to the outside of the rear end of the needle, so that the process of cutting the scanning chamber by exposing the scanning chamber that is not inserted after completion of the insertion process is required. In the present embodiment, the muscle-reinforced biodegradable fiber yarn 10 is shorter than the needle 20 so that the needle 20 is almost completely inserted into the muscle 3. Since the reinforcing biodegradable fiber yarn 10 is completely inserted into the muscle 3, not only the cutting operation is required, but also the infection of an external virus or the like can be prevented.

On the other hand, as described above, since the length of the muscle-reinforced biodegradable fiber yarn 10 is inserted into the insertion hole 21 of the needle 20 is shorter than the length of the needle 20, the insertion process can be made smoothly. have. However, when the muscle-reinforced biodegradable fiber yarn 10 is inserted and accommodated in the needle 20 in such a structure, the muscle-reinforced biodegradable fiber yarn 10 is separated from the needle 20 in the process of packaging, transportation, and storage. There is an easy issue. Therefore, in the related art, part of the scanning chamber is exposed at the rear end of the needle and bending of the exposed scanning chamber is prevented from detaching the scanning chamber from the needle, but this method prevents the scanning chamber from being smoothly removed from the needle during the insertion process. There is a problem of preventing the insertion process from being made smoothly by obstruction.

Therefore, in the present embodiment, while the insertion process can proceed smoothly, even during the process of packaging, transport, and storage, the fibrous fixing portion 40 that can prevent the separation of the muscle-reinforced biodegradable fiber yarn 10 to the needle 20 ) Is detachably coupled to the needle 20.

Fiber fixing part 40 of the present embodiment, as shown in Figs. 2 and 3, the needle 20 and the portion of the muscle-reinforced biodegradable fiber yarn 10 exposed to the outside of the needle 20 is attached and detached Possibly combined. The fiber yarn fixing portion 40 has a square pillar shape, and a through-hole 42 for inserting the needle 20 and the muscle-reinforced biodegradable fiber yarn 10 exposed to the outside of the needle 20 in the center portion thereof. ) Is formed through.

The fiber yarn fixing part 40 serves to fix the muscle-reinforced biodegradable fiber yarn 10 exposed to the outside of the needle 20 by being coupled to the needle 20. Therefore, the fiber yarn fixing portion 40 is coupled to the rear end of the needle 20 so as to fix the end of the muscle-reinforced biodegradable fiber yarn 10 when coupled to the needle 20.

The fiber yarn fixing part 40 is made of a material having elasticity, that is, sponge vinyl. Therefore, when the fiber yarn fixing portion 40 is coupled to the needle 20, the coupling process can be easily performed. When the fiber yarn fixing portion 40 is coupled to the needle 20, the through-hole 42 is formed. The inner wall of the fibrous fixing part 40 may partially prevent the muscle-reinforced biodegradable fiber yarn 10 coupled to the needle 20 by partially pressing the muscle-reinforced biodegradable fiber yarn 10. Therefore, the process of packaging, transportation and storage can be made reliably.

In addition, the needle 20 is inserted into the muscle 3 of the human body due to the material property of the fiber yarn fixing part 40, and the needle 20 is also inserted into the muscle 3 when the muscle-reinforced biodegradable fiber yarn 10 is inserted into the muscle 3. Muscle strengthening biodegradable fiber yarn (10) can be smoothly removed there is an advantage that the insertion process can be made smoothly.

On the other hand, the handle unit 30 is a portion that serves as a handle when inserting the needle 20, the muscle strengthening biodegradable fiber yarn 10 is inserted into the muscle (3). The handle unit 30 is, as shown in detail in Figure 4, the handle body 31 is provided with a non-slip unit 32 to prevent slipping when gripping, and the needle provided on one side of the handle body (31) 20 is provided with a needle insert 35 is detachably coupled.

The handle unit 30 is injection molded using a synthetic resin such as acrylic resin having a predetermined flexibility. Meanwhile, in the present embodiment, the needle 20 is detachably coupled to the needle inserting part 35. However, if the needle is easy to manufacture, the needle 20 is placed in a mold and then inserted into the mold by inserting the needle together with the synthetic resin. 20 and the handle unit 30 may be molded to be integrated.

The handle body 31 is a trunk portion which is formed to be elongated substantially in the same direction as the longitudinal direction of the needle 20 so that the operator can easily grip it. However, in the present embodiment, the handle body 31 having a quadrangular cross section is described in detail, but the handle body may be provided to have other cross sections such as circles and ellipses.

As shown in detail in FIG. 4, the handle body 31 has a curved shape in which a central portion is drawn inward relative to both ends. Therefore, the operator grips the portion of the handle body 31 which is relatively inward during the procedure, thereby preventing the operator's hand from slipping from the handle body 31, thereby performing a more accurate procedure. can do.

In addition, the outer surface of the handle body 31, as shown in detail in Figure 4, the anti-slip 32 is provided. The non-slip portion 32 has a plurality of non-slip grooves 33 protruding from the surface, the plurality of non-slip grooves 33 are formed regularly along the longitudinal direction of the handle body 31.

The non-slip portion 32 may prevent the operator's hand from being pushed from the handle body 31 when the operator inserts the needle 20 into the muscle 3, and thus the needle 20 into the muscle 3. ) Can be inserted smoothly.

On the other hand, the needle insertion portion 35 which is provided integrally with the handle body 31 at one side of the handle body 31, the rear end portion of the needle 20 is detachably coupled, as shown in FIG. , A needle insertion body 36 having a needle insertion groove 37 formed in one side of the handle body 31 and recessed to insert and insert the needle 20, and the circumferential direction of the outer circumferential surface of the needle insertion body 36. It comprises a plurality of wings 38 disposed along.

The needle insertion groove 37 supports the needle 20 so that the force applied to the needle 20 can be transmitted as it is when the needle 20 is inserted into the muscle 3. Here, the inner diameter of the needle insertion groove 37 and the outer diameter of the needle 20 are substantially the same, and thus the needle 20 may be firmly supported and coupled to the needle insertion portion 35.

The plurality of wings 38 are portions to which the needle protection tube 50 to be described later are coupled, and the needle protection tube 50 is prevented from being separated or rotated with respect to the needle insertion portion 35 of the handle unit 30. Therefore, the needle 20 accommodated in the inside of the needle protection tube 50 may be safely protected from the outside.

Needle protection tube 50, as shown in detail in Figures 1 to 3, is formed in a pipe (pipe) shape as a portion that is coupled to surround the needle 20 to protect the needle 20, the needle insertion Removably coupled to the plurality of wings 38 provided in the portion 35. The needle protection tube 50 may be slightly longer than the length of the needle 20 to protect the needle 20 as a whole.

The needle protection tube 50 may not only prevent the needle 20 from being damaged by external impact during packaging, storage, and transportation of the muscle-reinforced biodegradable fiber yarn inserting apparatus 1 of the present embodiment, but also the needle ( 20) also plays a role in preventing contamination by outside viruses.

Hereinafter, the manufacturing method and the procedure of the muscle-reinforced biodegradable fiber yarn inserting apparatus 1 having such a configuration will be described.

First, the handle unit 30 is injection molded by filling a predetermined mold with synthetic resin such as acrylic resin. If the production is easy and reliable products can be obtained, insert injection molding method of inserting the injection needle 20 into the mold in advance so that the handle unit 30 and the needle 20 are integrated, and then filling the synthetic resin with injection molding You can also apply However, hereinafter, a case in which the needle 20 is detachably coupled to the needle insertion unit 35 of the handle unit 30 after the handle unit 30 is manufactured will be described.

Subsequently, the needle 20 is inserted into and coupled to the needle insertion unit 35 formed on one side of the injection molded handle unit 30. Here, since the inner diameter of the needle insertion groove formed in the needle insertion unit 35 and the outer diameter of the needle 20 are substantially the same, the handle unit 30 and the needle 20 may be firmly coupled.

After the needle 20 is coupled to the handle unit 30, the muscle-reinforced biodegradable fiber yarn 10 is inserted into the needle 20. At this time, the muscle-reinforced biodegradable fiber yarn 10, as described above, approximately half of the portion is inserted into the insertion hole 21 of the needle 20 is received and the other half is disposed outside the needle 20 do.

Subsequently, the fibrous yarn is allowed to penetrate the needle 20 and the muscle-reinforced biodegradable fiber yarn 10 exposed to the outside of the needle 20 to prevent the muscle-reinforced biodegradable fiber yarn 10 from being detached from the needle 20 arbitrarily. The fixing part 40 is coupled to the needle 20.

Thereafter, the preparation of the muscle-reinforced biodegradable fiber yarn inserting apparatus 1 is completed by coupling the needle protection tube 50 to the handle unit 30 so as to surround the needle 20 in the longitudinal direction.

Subsequently, the manufactured muscle-reinforced biodegradable fiber yarn inserting device 1 is packaged and transported to a required place, such as a hospital, and then kept in a storage state until used. However, this process may be performed reliably because the fiber yarn fixing part 40 prevents the muscle-reinforced biodegradable fiber yarn 10 from being separated from the needle 20 when the packaging, transporting, and storing process is performed.

Next, the procedure of the muscle-reinforced biodegradable fiber yarn inserting apparatus 1 will be described.

First, the main needle protection tube 50 that protects the needle 20 from the muscle-reinforced biodegradable fibre-insertion apparatus 1 is separated, and as shown schematically in FIG. 6, the muscle 3 requiring muscle strengthening 3. Place the needle 20 in the.

Subsequently, the tip portion of the needle 20, that is, the sharp portion of the inclined cut portion 22, is brought into contact with the muscle 3, and then the pressure is applied while the grip unit 30 is correctly gripped, so that the entire muscle of the needle 20 is to be treated. Insert it into (3). In this case, the muscle-reinforced biodegradable fiber yarn 10 partially inserted and accommodated in the needle 20 together with the needle 20 may be inserted into the muscle 3.

Here, the muscle-reinforced biodegradable fiber 10 inserted into the muscle 3 is two strands, thereby improving the reinforcing effect of the muscle (3) than conventional. In addition, when the needle 20 is inserted into the muscle 3, the elastic fiber fixing portion 40 having elasticity pushes naturally toward the rear end of the needle 20, and the muscle-reinforced biodegradable fiber yarn 10 that is being fixed is It can be smoothly introduced into the muscle (3).

Thus, according to the present embodiment, since the muscle-enhanced biodegradable fiber yarn 10, which is thinner than the conventional one, is inserted into the muscle 3, the degree of pain felt by the patient can be reduced while the double muscle-enhanced biodegradable fiber yarn ( 10) can be inserted to double the strengthening effect of the muscle (3), the insertion process can proceed without a separate process for cutting the muscle strengthening biodegradable fiber yarn 10 can not only suppress the occurrence of infection It is possible to simplify the insertion process, and also to prevent the muscle-reinforced biodegradable fiber yarn 10 from being separated from the needle 20, so that a process such as packaging, sterilization, storage and transportation can be reliably performed.

In the above-described embodiment, the fiber yarn fixing part is provided in the form of a rectangular parallelepiped having a central portion, but the shape of the fiber yarn fixing part is not limited thereto, and may be provided in another shape, for example, a hollow cylindrical shape. will be.

In addition, in the above-described embodiment, the needle is detachably penetrated through the penetrating hole of the fiber yarn fixing part, but if the structure is coupled to the needle to fix the muscle-reinforced biodegradable fiber yarn exposed to the outside, the fiber may be in other forms. Four fixings are self-evident.

As described above, the present invention is not limited to the described embodiments, and various modifications and changes can be made without departing from the spirit and scope of the present invention, which will be apparent to those skilled in the art. Accordingly, such modifications or variations are intended to fall within the scope of the appended claims.

1 is a perspective view of the combination of muscle strengthening biodegradable fiber inserting apparatus according to an embodiment of the present invention.

2 is an exploded perspective view of FIG. 1.

FIG. 3 is a view illustrating a state in which the needle protection tube is disassembled in the muscle-reinforced biodegradable fiber yarn inserting apparatus shown in FIG. 1.

Figure 4 is a perspective view of the handle unit shown in FIG.

FIG. 5 is a perspective view illustrating a state in which the muscle-reinforced biodegradable fiber yarn shown in FIG. 2 is accommodated in the needle. FIG.

FIG. 6 is a view schematically illustrating a process of inserting the needle of the muscle-reinforced biodegradable fiber yarn inserting apparatus shown in FIG. 1 into the muscle of the human body.

* Explanation of symbols for the main parts of the drawings

1: muscle strengthening biodegradable fiber inserting device

10: muscle strengthening biodegradable fiber yarn 20: needle

30: handle unit 31: handle body

32: non-slip unit 35: needle insertion unit

40: fiber yarn fixing portion 42: needle protection tube

Claims (12)

Muscle-reinforced biodegradable fiber yarn which is provided in a thread shape as a biodegradable fiber material and is inserted into muscles in the human body to induce autogenous substances in the human body; A needle provided in a pipe shape and having the muscle-reinforced biodegradable fiber yarn inserted into the insertion hole such that at least a portion of the muscle-reinforced biodegradable fiber yarn is exposed to the outside of the insertion hole formed in a longitudinal direction; A fiber yarn fixing part detachably coupled to the needle and stopping the detachment of the muscle-enhanced biodegradable fiber yarn from the needle by fixing the muscle-reinforced biodegradable fiber yarn exposed to the outside of the insertion hole to the needle; And Muscle strengthening biodegradable fiber inserting apparatus comprising a handle unit coupled to the needle. The method of claim 1, The muscle-reinforced biodegradable fiber yarn exposed to the outside of the insertion hole of the needle and the muscle-reinforced biodegradable fiber yarn inserted into the insertion hole of the needle are bent at the tip of the needle, The fiber yarn fixing portion has a through hole that is the same as the outer diameter of the needle penetrates along the thickness direction, and the muscle exposed to a part of the needle and the insertion hole of the needle in the through hole of the fiber yarn fixing part. An apparatus for inserting muscle-reinforced biodegradable fiber yarns, wherein a portion of the reinforcing biodegradable fiber yarns is coupled through. 3. The method of claim 2, The muscle-reinforced biodegradable fiber yarn inserting apparatus, characterized in that the length of the muscle-reinforced biodegradable fiber yarn exposed to the outside of the insertion hole of the needle is shorter than the length of the muscle-reinforced biodegradable fiber yarn inserted into the insertion hole of the needle. The method of claim 3, When the needle is penetrated and coupled to the fiber yarn fixing portion, the fiber yarn fixing portion is coupled to a rear end portion of the needle to fix an end portion of the muscle-reinforced biodegradable fiber yarn exposed to the outside of the insertion hole of the needle. Muscle-reinforced biodegradable fiber inserting device. 3. The method of claim 2, The fibrous yarn fixing portion is muscle-strengthening biodegradable fibres inserting device, characterized in that provided with a sponge vinyl having elasticity. The method of claim 1, The handle unit, the muscle strengthening biodegradable fiber yarn inserting apparatus is provided with a non-slip portion protruding from the surface is provided with a plurality of non-slip grooves to prevent slipping when gripping. The method of claim 6, The handle unit, The non-slip is provided on the outer surface, the handle body gripped during the procedure; And Is provided on one side of the handle body, muscle strengthening biodegradable fiber yarn inserting apparatus comprising a needle inserting portion is formed in the needle insertion groove in which the needle is partially inserted coupling. The method of claim 7, wherein The handle body is inserted muscle strengthening biodegradable fiber yarns, characterized in that the central portion is provided with a curved shape that is drawn inwards compared to both ends. The method of claim 7, wherein The needle insertion unit, A needle insertion body provided at one side of the handle body and forming the needle insertion groove; And Is provided to be spaced apart from each other along the outer circumferential surface of the needle insertion body, muscle strengthening biodegradable fiber insertion apparatus, characterized in that it comprises a plurality of wings extending radially from the needle insertion body. The method of claim 1, It is provided in an open pipe shape at both ends, and further comprising a needle protection tube detachably coupled to one side of the handle unit to surround the needle, characterized in that the muscle-reinforced biodegradable fiber yarn inserting apparatus. The method of claim 1, The muscle-reinforced biodegradable fiber inserting apparatus, characterized in that the inclined cutting portion inclined in the oblique direction is provided at the tip of the needle. The method of claim 1, The handle unit is made of a synthetic resin material by injection molding, the injection needle muscle strengthening biodegradable fiber inserting apparatus, characterized in that the detachable coupling to the handle unit.

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