KR101318844B1 - Implant for neurotization by lectrostimulation - Google Patents

Abstract

The present invention relates to an electrical stimulation nerve regeneration implant, and more particularly to an electrical stimulation nerve regeneration implant that enables early bone fusion and bone density enhancement by allowing the internal bone of the alveolar bone to undergo electrical stimulation during dental implant procedures.
The implant for electrical stimulation nerve regeneration according to the present invention, the thread is formed on the rim so that the screw can be screwed into the alveolar bone and the through-hole is formed in the center and extends from the top of the body is formed with an opening at the top to form an inner space portion An electrode having an insert having a head to be inserted into a through hole formed in the body of the insert, the electrode having a lower end exposed to the outside of the body, and detachably coupled to the lower end of the electrode to be in contact with a nerve inside the alveolar bone A tip, a power source installed in the space formed in the head of the insert, a printed circuit board installed to be in contact with the power supply, and a printed circuit board installed in contact with the upper end of the magnetic pole electrode, and electrically connected to each other. And a cap coupled to an opening formed in the head of the insert, wherein the cap is formed in the opening formed in the head of the insert. When the sum, through the substrate, the magnetic pole chip, and stimulating electrodes printed circuit from the power source is electricity is supplied to the electrode tip it is characterized in that the electrical stimulation is applied so as to close to the electrode tip nerves.

Description

Implant for neurotization by lectrostimulation

The present invention relates to an electrical stimulation nerve regeneration implant, and more particularly to an electrical stimulation nerve regeneration implant that enables early bone fusion and bone density enhancement by allowing the internal bone of the alveolar bone to undergo electrical stimulation during dental implant procedures.

After implanting a screw-shaped titanium tooth, or a fixture, into the alveolar bone, the bone is fused around the implanted fixture, and when it is hardened, abutments are attached to it and an artificial tooth is created there. It is put in.

Compared to the bridge, the most common method of dental restoration, the implant can be performed only on the damaged area without damaging adjacent teeth, surrounding soft tissue or bone tissue, and it is continuously supported and supported by bone tissue, As the absorption rate of bone tissue is delayed and can be restored to the same level as chewing power and natural teeth, and aesthetically similar to natural teeth, implantation is a global trend recently.

These implants are made of titanium to improve the compatibility with the alveolar bone, and threads are formed from the upper end to the lower end so that they are lodged with screws when they are lodged in the alveolar bone, and after being implanted, the implant is fused and firmly fixed to the contact bone. .

However, after the implant is embedded in the alveolar bone, the jawbone tissue is regenerated, and since the implant takes a long time to be fused, the procedure must be performed for a long time for the regeneration of the jawbone tissue, and it does not fuse well so that it does not stick well in the jawbone. There was a problem.

On the other hand, Korean Utility Model Registration No. 20-0327089 discloses an implant for artificial teeth surgery for maintaining the electric field. This design inserts a bio-magnet into the dental implant and attaches a copper plate on top to restore the bio-electric field with the bio-magnet, which aids in the regeneration of tissue and allows tissue within the body to bind well with the implant. However, there is a limit to the correction of the bio magnetic field with only the bio magnet without any external power.

The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide an electrical stimulation nerve regeneration implant that enables early bone fusion and bone density enhancement by allowing the inner nerve of the alveolar bone to undergo electrical stimulation during dental implant procedure. .

An object of the present invention described above, the head is formed in the rim so that the screw can be screwed into the alveolar bone and the through-hole is formed in the center and the head extending from the top of the body is formed with an opening at the top to form an inner space is formed head An insert having an insert, a stimulation electrode inserted into a through hole formed in the body of the insert, and having a lower end exposed to the outside of the body, and detachably coupled to a lower end of the stimulating electrode to be in contact with a nerve inside the alveolar bone A tip, a power source installed in the space formed in the head of the insert, a printed circuit board installed to be in contact with the power source, and installed to be in contact with the printed circuit board, and an upper end of the magnetic pole electrode. And a cap coupled to an opening formed in the head of the insert, the cap being electrically connected to the magnetic pole chip. When coupled to the opening formed in the head of the sieve, electricity is supplied to the electrode tip from the power supply through the printed circuit board, the magnetic pole chip and the magnetic pole electrode to apply electrical stimulation to the nerves around the electrode tip. It can be achieved by providing an implant for electrical stimulation nerve regeneration.

According to a preferred feature of the invention, it may further include a stimulation control module is installed in the space portion formed in the head of the insert to adjust the stimulation level of the stimulation chip.

According to another preferred feature of the invention, it is further provided with an elastic means which is installed on the top of the power source is compressed when the cap is coupled to the opening formed in the head of the insert to contact the power supply circuit board; Can be.

According to another preferred feature of the invention, the stimulation electrode may be made of a bipolar stimulation electrode.

According to another preferred feature of the invention, the electrode tip may comprise a reference electrode and a channel electrode spaced apart from each other.

According to another preferred feature of the invention, between the reference electrode and the channel electrode of the electrode tip is wrapped with an insulating material.

According to another preferred aspect of the present invention, the stimulus chip comprises a parameter memory having pulse width and amplitude information of a stimulus parameter, a time controller for generating pulse width information from the parameter memory, and amplitude information from the parameter memory. It may include a current controller for receiving and generating, and an electrode controller for receiving the time information and amplitude information from the time controller and the current controller to generate a stimulus signal and to send it to the stimulation electrode.

In addition, the object of the present invention described above is made of a cylindrical shape in which a through-hole is formed in the center portion, the thread is formed on the rim so that the screw can be screwed into the alveolar bone, the fixing body is formed in the screw bone on the inside, and the fixing body It is made of a cylindrical shape that can be fitted into the through hole of the screw thread corresponding to the screw bone of the fixing body is formed on the edge and the through-hole is formed in the center and extends from the top of the body with an opening formed at the top of the inner space An insert having an head having an additional portion formed therein, a stimulation electrode inserted into a through hole formed in the body of the insert, and having a lower end exposed to the outside of the body, and detachably coupled to a lower end of the stimulation electrode to form an internal alveolar bone. An electrode tip in contact with the nerve, a power source installed in a space portion formed in the head of the insert, and the power source And a magnetic pole chip installed to be in contact with the printed circuit board, the magnetic pole chip electrically connected to an upper end of the magnetic pole electrode, and a space formed in the head of the insert. A stimulation control module for adjusting a stimulation level of the cap, a cap coupled to an opening formed in the head of the insert, and installed at an upper end of the power source and compressed when the cap is coupled to an opening formed in the head of the insert. And elastic means for providing a restoring force such that the power is in contact with the printed circuit board. When the cap is coupled to an opening formed in the head of the insert, the power supply may be connected to the printed circuit board, the magnetic pole chip, and the magnetic pole electrode. Electrical stimulation is characterized in that the electrical is supplied to the electrode tip through the electrical stimulation to the nerve around the electrode tip It can also be achieved by providing an implant for nerve regeneration.

According to the implant for electrical stimulation nerve regeneration according to the present invention, by supplying electricity to the electrode tip located inside the alveolar bone to receive electrical stimulation of the nerves around the electrode tip, it is possible to achieve early bone fusion and increase bone density. have.

1 is a schematic cross-sectional view of an implant for electrical stimulation nerve regeneration according to an embodiment of the present invention.
Figure 2 is a block diagram showing the operation principle of the stimulation chip shown in FIG.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood, however, that the embodiments described below are only for explanation of the embodiments of the present invention so that those skilled in the art can easily carry out the invention, It does not mean anything. In describing various embodiments of the present invention, the same reference numerals will be used to refer to elements having the same technical features.

Referring to Figure 1 will be described with respect to the implant for electrical stimulation nerve regeneration according to an embodiment of the present invention. As shown, the implant for electrical stimulation nerve regeneration the insert 100, the stimulation electrode 200, the electrode tip 300, the power supply 400, the printed circuit board 500, the stimulation chip 600 and the cap ( 700, and may further include a stimulation control module 800 and an elastic means 900.

The insert 100 is inserted into the alveolar bone and is supported by the alveolar bone and has a body 110 and a head 120.

Here, the body 110 may be screwed into the alveolar bone with a thread 112 formed on the rim. In addition, the body 110 has a through hole 114 formed in the center portion, and the magnetic pole 200 is inserted into the through hole 114 as described later.

The head 120 extends from an upper end of the body 110, and has an inner space 122 by forming an opening (not shown). The inner space 122 of the head 120 is provided with a power supply 400, a printed circuit board 500, a magnetic pole chip 600, a magnetic pole control module 800, and an elastic means 900.

The pole electrode 200 is inserted into and installed in the through hole 114 formed in the body 110 of the insert 100, the lower end of which is exposed to the outside of the body 110. Here, it is preferable that a pole electrode is a bipolar pole electrode.

The electrode tip 300 directly contacts the nerve inside the alveolar bone and serves to apply electrical stimulation to the surrounding nerve, and is provided at the bottom of the stimulation electrode 200. The electrode tip 300 preferably includes a reference electrode 310 and a channel electrode 320. The reference electrode 310 and the channel electrode 320 are spaced apart from each other. . And the electrode tip 300 is preferably formed to be tapered, the end is pointed to be inserted into the nerve. In addition, the electrode tip 300 is electrically connected to the reference electrode 310 and the channel electrode 320 to the output terminal of the magnetic pole chip 600, in which case each connection portion is preferably wrapped with an insulating material.

On the other hand, the reference electrode 310 and the channel electrode 320 is preferably made of a conductive material such as platinum (Pt), gold (Au) or iridium (Ir) so that the current flows well, respectively, the reference electrode 310 More preferably, the channel electrode 320 is surrounded by an insulating material to prevent current from flowing.

The reference electrode 310 and the channel electrode 320 are configured with different potentials to enable current or voltage stimulation in both directions. For example, when stimulating with voltage, if the channel electrode is made to be a positive potential and the reference electrode is made to be a negative potential, an electric field effect is generated through a potential difference. Thus, cells or tissues present between the electrodes are electrically stimulated. Will receive.

On the other hand, when stimulating with current, if the current stimulus is applied by adjusting the direction of the current flow by making the channel electrode 320 a current source or the reference electrode 310 being a current source, Cells or tissues present between the electrodes are subjected to electrical stimulation.

On the other hand, the electrode tip 300 is preferably detachable to the stimulation electrode 200 to be able to adjust to the size of the tissue to be applied to the electrical stimulation.

The power source 400 serves to supply power, and is installed in the inner space 122 formed in the head 120 of the insert 100.

The printed circuit board (PCB) 600 is installed to be in contact with the power source 400 and the magnetic pole chip 600, and serves to electrically connect the power source 400 and the magnetic pole chip 600.

The magnetic pole chip 600 is installed to be in contact with the printed circuit board 500 and is also electrically connected to the upper end of the magnetic pole electrode 200.

The stimulus chip 600 may include a parameter memory, a time controller, a current controller, and an electrode controller, as shown in FIG. 2, wherein the parameter memory has pulse width information and amplitude information of the stimulation parameter. The time controller receives the pulse width information from the parameter memory and generates it, and the current controller receives the amplitude information from the parameter memory and generates it. The electrode controller receives time information and amplitude information from the time controller and the current controller, respectively, and generates a stimulus signal and sends the stimulus signal to the stimulus electrode.

The cap 700 is coupled to an opening formed in the head 120 of the insert 100 to cover the head 120. In this case, when the cap 700 is coupled to the opening of the head 100 of the insert 100, the electrode tip is passed from the power supply 400 to the printed circuit board 500, the magnetic pole chip 600, and the magnetic pole electrode 200. The electricity is supplied to the 300, and electrical stimulation is applied to nerves around the electrode tip 300. That is, when the cap 700 is coupled to the head 120 of the insert 100, the (+) and (-) poles of the power supply are connected to the printed circuit board 500 to start the operation. On the other hand, it is also possible to operate by transmitting a radio signal from the outside without the moment the cap 700 is coupled to operate.

The stimulation control module 800 is provided to adjust the stimulation level of the stimulation chip 600, is installed in the inner space 122 formed in the head of the insert 100. In this case, the stimulation control module 800 may be installed to be in contact with the stimulation chip 600, by transmitting a radio signal from the outside when it is necessary to adjust the intensity or time of the stimulation provided by the stimulation chip 600 By the stimulation control module 800 to adjust the stimulation level of the stimulation chip 600.

Meanwhile, when the cap 700 is coupled to the opening of the insert 100, the head 120 may further include an elastic means 900 for electrically connecting the power source 400 and the magnetic pole chip 600. Elastic means 900 is installed on the top of the power source 400 is disposed between the cap 700 and the power source 400 when the cap 700 is coupled to the head 120 of the insert 100, the cap 700 compresses the elastic means 900 so that the elastic means 900 provides a restoring force so that the power source 400 is in contact with the printed circuit board 500. Elastic means 900 may be applied to a variety of elastic materials, such as elastic material or compression spring, compression spring is suitable.

Referring to the operating relationship of the electrical stimulation nerve regeneration implant according to the present invention. When the cap 700 is coupled to the opening formed in the head 120 of the insert 100, the cap 700 compresses the elastic means 900, and the power source 400 is connected to the printed circuit by the restoring force of the elastic means 900. In contact with the substrate 500, electricity is supplied to the stimulation chip 600 by the power supply 400, and the voltage or the reference electrode 310 and the channel electrode 320 of the electrode tip 300 are passed through the stimulation electrode 200. Current is supplied. Accordingly, a stimulus is applied to nerves around the electrode tip 300.

In the above description, the insert 100 of the electrical stimulation nerve regeneration implant is directly screwed into the alveolar bone, but may be provided separately to be fixed to the alveolar bone and accommodate the insert 100.

In this case, although not shown, the fixture has a cylindrical shape, has a screw thread formed on the rim so that it can be screwed to the alveolar bone, and the insert is formed inside the through hole and the through hole formed in the center for receiving and fixing. It is preferable to be formed to have a screw bone.

And the insert is made of a cylindrical shape that can be inserted into the through-hole of the fixture and has a thread formed on the rim to correspond to the screw bone of the fixture.

Other technical features of the insert, magnetic pole electrode, electrode tip, power supply, printed circuit board, magnetic pole chip, magnetic pole control module, cap, elastic means of the implant for the electrical stimulation shown in Figures 1 and 2 Since it is substantially the same, a detailed description is abbreviate | omitted.

100: insert 110: body
112: thread 114: through hole
120: head 122: inner space part
200: stimulation electrode 300: electrode tip
310: reference electrode 320: channel electrode
400: power 500: printed circuit board
600: stimulation chip 700: cap
800: stimulation control module 900: elastic means

Claims (8)

It is composed of a body and the head, the body is formed with a screw thread on the rim to be screwed into the alveolar bone and a through hole is formed in the center, the head is extended from the upper end of the body is formed with an opening at the upper end of the inner space portion Formed inserts;
A stimulation electrode inserted into the through hole formed in the body of the insert to expose a lower end to the outside of the body;
An electrode tip detachably coupled to a lower end of the stimulation electrode to contact a nerve inside the alveolar bone;
A power supply installed in a space formed in the head of the insert;
A printed circuit board installed to be in contact with the power source;
A magnetic pole chip installed to be in contact with the printed circuit board and electrically connected to an upper end of the magnetic pole electrode; And
And a cap coupled to an opening formed in the head of the insert. When the cap is coupled to an opening formed in the head of the insert, the cap is connected to the opening through the printed circuit board, the magnetic pole chip, and the magnetic pole electrode. The electrical stimulation nerve regeneration implant, characterized in that electric stimulation is applied to the nerve around the electrode tip is supplied with electricity to the electrode tip. The method according to claim 1,
And a stimulation control module installed in the space formed in the head of the insert to adjust the stimulation level of the stimulation chip. The method according to claim 1,
It is installed on the upper end of the power supply for the electrical stimulation nerve regeneration, characterized in that the cap is coupled to the opening formed in the head of the insert is compressed so that the power directly in contact with the printed circuit board Implants. The method according to claim 1,
The stimulation electrode is an electrical stimulation nerve regeneration implant, characterized in that the bipolar stimulation electrode. The method according to claim 1,
The electrode tip is an electrical stimulation nerve regeneration implant comprising a reference electrode and a channel electrode spaced apart from each other. The method of claim 4,
An implant for electrical stimulation nerve regeneration, characterized in that between the reference electrode and the channel electrode of the electrode tip is wrapped with an insulating material. The method according to claim 1,
The stimulus chip includes a parameter memory having pulse width and amplitude information of a stimulus parameter, a time controller for generating pulse width information from the parameter memory, a current controller for receiving amplitude information from the parameter memory, and a time controller. And an electrode controller which receives time information and amplitude information from a current controller and generates a stimulus signal and sends the stimulus signal to the stimulus electrode. It is made of a cylindrical shape through-hole is formed in the center portion, the screw thread is formed on the rim so that it can be screwed into the alveolar bone, the fixing body is formed screw thread inside;
Consists of a body and a head, the body is made of a cylindrical shape that can be fitted into the through hole of the fixing body, the screw thread corresponding to the screw bone of the fixing body is formed on the edge and the through hole is formed in the center portion, the head is An insert extending from an upper end of the body and having an opening formed at an upper end thereof so that an inner space is formed;
A stimulation electrode inserted into the through hole formed in the body of the insert to expose a lower end to the outside of the body;
An electrode tip detachably coupled to a lower end of the stimulation electrode to contact a nerve inside the alveolar bone;
A power supply installed in a space formed in the head of the insert;
A printed circuit board installed to be in contact with the power source;
A magnetic pole chip installed to be in contact with the printed circuit board and electrically connected to an upper end of the magnetic pole electrode;
A stimulation control module installed in the space formed in the head of the insert to adjust the stimulation level of the stimulation chip;
A cap coupled to an opening formed in the head of the insert; And
And an elastic means installed at an upper end of the power source to provide a restoring force when the cap is coupled to an opening formed in the head of the insert, thereby providing a restoring force so that the power source comes into contact with the printed circuit board. When coupled to the opening formed in the head of the sieve, electricity is supplied to the electrode tip from the power supply through the printed circuit board, the magnetic pole chip and the magnetic pole electrode to apply electrical stimulation to the nerves around the electrode tip. Implants for electrical stimulation nerve regeneration.

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