KR20120071906A - Clamping member of a fixing screw for an electrode of a miniaturized brain stimulating electrode system - Google Patents

Abstract

PURPOSE: An electrode support screw fastener of a miniature electrode system for brain nerve stimulation is provided to prevent collision with other structures. CONSTITUTION: An electrode support screw fastener of a miniature electrode system for brain nerve stimulation comprises a handle unit(210), an anchor member supporting unit(230), and an anchor member cover joint(250). On both sides of the handle unit, a long and thin slit is formed. In each slit, a pair of penetration holes is formed. The anchor member supporting unit comprises an insertion unit(220) and a hollow unit(222). The anchor member cover joint is attached to the other end of the handle unit.

Description

Clamping member of a fixing screw for an electrode of a Miniaturized Brain Stimulating Electrode System}

The present invention relates to an electrode support screw fastener of a small electrode system for stimulating brain nerves, and more particularly, to develop a next-generation deep brain stimulator for treating a movement disorder and pain, and implanting into a head cavity to stimulate a specific structure of the brain. When anchoring (fastening) the anchor member used to stably and easily used to the stimulus electrode to the test object to the skull, it can facilitate the fixation, and the collision with other structures The present invention relates to an electrode support screw fastener of an electrode system for minimizing nerve stimulation, which is easily prevented and separated from an anchor.

As is well known, in order to develop therapeutics for the treatment of pain and movement disorders caused by lesions such as Parkinson's disease, pain, and epilepsy, the artificially created specimens are used to stimulate specific brain nerves of the specimens. Behavioral experiments are conducted to investigate the improvement of the condition.

The advantages of this Deep Brain Stimulation (DBS) procedure are that it is easier to apply new therapies because they have a greater therapeutic effect, less risk of brain damage, and no removal of brain tissue. In addition, the current cardiac brain stimulator has to overcome the frequent stimulator replacement due to limited battery life and the complexity of surgery due to the large size, and the next-generation cardiac stimulator is being actively developed to solve these disadvantages. Animal models are used to verify the effectiveness of stimulators and to extend the range of application of the device (pain, epilepsy, etc.).

In conducting the deep brain stimulation using such a specimen, the animal model should be biologically safe, so there should be no influence on the living body, there should be no destruction of brain cells by the stimulation electrode and the electrical stimulation, and the electrode used for the brain electrode. The material and associated devices must be safe for application in vivo. To this end, it is necessary to set the exact position of the target site in the deep structure, and by using an image using magnetic resonance imaging (MRI) together with the microelectrode, the accuracy of the positioning and the operation can be greatly improved.

Meanwhile, a test rat is usually used as a test subject, and in order to stimulate the cranial nerve while satisfying the above safety standards, the brain 1 of the rat is first perforated using a conventional deep brain stimulator as shown in FIG. 1. A 5 μm parylene-coated tungsten metal electrode 6 is inserted into a target site 3 of the brain using an anchor 2 made of a stainless steel suitable for a living body, After embedding with a small amount of dental cement (4), and stably fixed, the anchor (2) in which the metal electrode (6) is inserted is mounted to the rat as a fixing mechanism (10) as shown in FIG. Doing. Fixing mechanism (10) is a tether band (14) composed of a soft elastic body so that the rat does not feel the pressure, the upper portion of the rat in order to prevent abnormal high fever from occurring in the incision site, The saddle 12 is provided with a stimulator, which serves to stably fix the stimulator when the subject performs a behavioral experiment.

However, in the conventional cranial nerve stimulation system as described above, the rats move from place to place in the breeding pit (Uri) and collide with each other, resulting in breakage, and it is impossible to transmit a desired stimulus signal to the subject. There is a problem in deriving.

In order to fix the stimulation electrode at the correct position of the skull of the test subject, an anchor member is used to insert the stimulation electrode to be fixed to the skull of the test subject. However, the anchor member supports the stimulation electrode by fastening a support screw to the anchor member. Since the member is small, there is a problem in that it is inconvenient to use during electrode fixation.

Accordingly, an object of the present invention is to facilitate the anchoring of the anchor member into which the stimulation electrode is inserted during the electrode fixation operation, to prevent collision with other structures, and for the cranial nerve stimulation as an auxiliary device that is easily separated from the anchor. An electrode support screw fastener of a small electrode system is provided.

Electrode support screw fastener of the miniature electrode system for cranial nerve stimulation of the present invention for achieving the above object is formed so that the handle portion and the anchor member can be inserted, including an anchor member support portion attached to one end of the handle portion, The anchor member may include a flange portion having a pair of screw grooves facing each other, and an electrode holder protruding integrally with the flange portion so as to support the magnetic pole electrode inserted therein.

The anchor member support part includes an insertion part attached to the handle part and a hollow part bent at the insertion part to insert the anchor member, wherein the hollow part is a flange part of one side of the anchor member is inserted and the screw groove is exposed. The flange portion of the other side may be exposed, and support screw fastening grooves may be formed on both sides of the hollow part to enable screwing of the pole electrode support screw to which the connecting line for supporting the pole electrode inserted into the electrode holder and supplying electricity is coupled. have.

In the electrode support screw fastener of the miniature electrode system for cranial nerve stimulation of the present invention, the cover fastened to the electrode holder of the anchor member is formed to be insertable, and may further include an anchor member cover fastening part attached to the other end of the handle part. The anchor member cover fastening part may include an insertion part attached to the handle part and a hollow part which is bent at the insertion part to open the cover so that the cover is inserted.

A guide groove may be formed on an outer surface of the cover fastened to the electrode holder of the anchor member, and a guide protrusion may be formed at the hollow portion of the cover fastening portion to engage the guide groove of the cover.

According to an embodiment of the present invention, using the anchor member support portion attached to one side of the handle portion easily screwed the pole electrode support screw inserted into the anchor member, anchor using the anchor member cover fastening portion attached to the opposite side of the handle portion By coupling the cover to the member, it is easy to fix the anchor member into which the stimulation electrode is inserted during the electrode fixing operation. Also, the anchor member support part and the anchor member cover fastening part are bent, so that the collision with other structures during use may result. The operation is prevented from being uncomfortable, and since only a part of the flange portion of the anchor member is inserted into the anchor member support portion, the anchor member can be easily separated after the magnetic pole electrode support screw is fastened.

1 is a schematic view showing the configuration of a conventional deep brain stimulator,
FIG. 2 is a perspective view illustrating a fixing mechanism for attaching the stimulator to the test object of FIG. 1;
3 is a perspective view showing the configuration of a typical miniature electrode system for nerve stimulation,
4 is an exploded perspective view illustrating an electrode support screw fastener of a miniature electrode system for cranial nerve stimulation according to an embodiment of the present invention;
5 is a coupling state diagram of FIG. 4,
6 is a state diagram showing a state in which the anchor member is fastened to the anchor member support,
7 is a state diagram showing a state in which the cover of the anchor member is fastened to the anchor member cover.

Hereinafter, with reference to the accompanying drawings will be described in detail the operation of the embodiment according to the present invention. In the following description of the present invention, if it is determined that a detailed description of a known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. The following terms are defined in consideration of the functions of the present invention, and may be changed according to the intentions or customs of the user, the operator, and the like. Therefore, the definition should be based on the contents throughout this specification.

3 shows a configuration of a miniature electrode system for cranial nerve stimulation in which the anchor member 20 is fixed to the skull of a test subject. As shown in FIG. 3, the anchor member 20 of the small electrode system 100 for cranial nerve stimulation has a cube electrode holder 40 to which the stimulation electrode 50 is inserted and supported and a lower portion of the electrode holder 40. It consists of a flange portion 30 formed integrally on both sides. The flange portion 30 is provided with a pair of screw grooves 32 on both sides thereof, wherein the screw groove 32 is preferably inclined toward the electrode holder 40 to securely anchor the anchor member 20.

The electrode holder 40 made of a non-conductor such as Teflon has a slit groove 42 formed in a straight shape so that the pole electrode 50 is vertically inserted in the center thereof, and the screw groove so that the pole electrode support screw 60 is screwed together. A 44 is formed, and the pole electrode 50 is positioned between the pair of support plates 70 inserted into the slit groove 42, and the pole electrode support screw 60 is screwed into the screw groove 44. To support the magnetic pole electrodes 50 between the support plates 70.

Each of the pole electrode support screws 60 includes a screw part 62 screwed to a screw groove 44 formed in the electrode holder 40, and a head 64 protruding from the electrode holder 40. The head 64 of the support screw 60 is coupled to the connecting line 80 for supplying current to the pole electrode 50, the other side of the support screw 60, the pole electrode 50 is located in the center of the metal The washer 90 of the material is interposed.

The connecting line 80 is tin-plated and solderable, and is bent into a "-" shape so that the coupling portion 82 is coupled to the head 64 of the pole electrode support screw 60.

4 is an exploded perspective view illustrating an electrode support screw fastener of a miniature electrode system for cranial nerve stimulation according to an embodiment of the present invention, and FIG. 5 is a coupling state diagram of FIG. 4.

4 and 5, the electrode support screw fastener 200 according to an embodiment of the present invention is formed to be inserted into the handle portion 210, the anchor member 20, the handle portion 210 Anchor member support 230 attached to one end of the) and the cover 22 (FIG. 7) fastened to the electrode holder 40 of the anchor member 20 are formed to be insertable, Anchor member cover fastening portion 250 attached to the other end.

The handle portion 210 has long slits 212 formed at both sides thereof, and a pair of through holes 214 are formed in each slit 212.

Anchor member support 230 is an insertion portion 220 is inserted and attached to the slit 212 of the handle portion 210, the hollow portion 222 is bent from the insertion portion 220 is inserted into the anchor member 20 Includes, the anchor member cover fastening portion 250 is also inserted into the slit 212 of the handle portion 210, 240, and the cover 22 of the anchor member 20 is bent from the insertion portion 240 The hollow portion 242 is opened when the bottom surface is inserted. The cover 22 inserted into the hollow part 242 of the cover fastening part 250 is fastened to the electrode holder 40 of the anchor member 20 for insulation.

A pair of insertion holes 224 and 244 are respectively provided in the insertion portion 220 of the anchor member support 230 and the insertion portion 240 of the anchor member cover fastening portion 250. It is formed to correspond to the through hole 214 formed in the.

The insertion part 220 of the anchor member support part 230 and the insertion part 240 of the anchor member cover fastening part 250 are inserted into the slit 212 of the handle part 210, and the insertion holes 224 and 244 are inserted. The through-holes 214 communicate with each other by using a rivet 24 or the like. Although not specifically illustrated, of course, it can be fixed and attached by other bolting or welding.

At this time, the bending direction of the hollow part 222 of the anchor member support part 230 and the bending direction of the hollow part 242 of the anchor member cover fastening part 250 are opposite to each other and coupled to the handle 210. Even if the 210 is rotated 180 °, it is preferable because it is the same direction and is convenient to use.

In FIGS. 6 and 7, the hollow part 222 of the anchor member support part 230 has support screw fastening grooves 225 formed at both sides thereof, and the flange part 30 of one side of the anchor member 20 is inserted. Thus, one of the threaded grooves 32 of the opposite flange portion 30 is exposed. The fastener 200 of the present invention supports the magnetic pole electrode 50 inserted into the electrode holder 40 through the support screw coupling groove 225 and the magnetic pole electrode support screw coupled to the connection line 80 for supplying electricity ( 60) can be screwed in.

Meanwhile, the hollow part 242 of the anchor member cover fastening part 250 corresponds to the shape of the anchor member cover 22, and since the lower open surface 245 is formed, the electrode holder 40 of the cover 22 is formed. Can be easily attached and removed. That is, the guide groove 26 is formed on the outer surface of the cover 22 which is fastened to the electrode holder 40 of the anchor member 20, and the hollow part 242 of the cover fastening part 250 of the cover 22. Since the guide protrusion 248 engaging with the guide groove 26 may be formed, the cover 22 is fastened to the electrode holder 40 while being inserted into the hollow part 242 of the cover fastening part 250. The cover 22 is easily separated from the hollow part 242 by sliding the guide part 248 by pulling the handle part 210 in the easy and fastening state.

The electrode support screw fastener 200 of the small electrode system for cranial nerve stimulation according to the present invention configured as described above supports the stimulation electrode inserted into the anchor member 20 using the anchor member support 230 of one side of the handle 210. The screw 60 can be easily screwed, and the cover 22 is coupled to the electrode holder 40 of the anchor member 20 by using the anchor member cover fastening portion 250 of the other side of the handle portion 210. Accordingly, the small anchor member 20 into which the stimulation electrode 50 is inserted can be easily fixed during the electrode fixing operation.

What has been described above is just one preferred embodiment of the stimulating electrode support screw fastener of the small electrode system for brain stimulation according to the present invention, the present invention is not limited to the above-described embodiment, it is claimed in the following claims As will be apparent to those skilled in the art to which the present invention pertains without departing from the gist of the present invention, the technical spirit of the present invention will be described to the extent that various modifications can be made.

20: anchor member 22: cover
24: rivet 30: flange portion
32: screw groove 40: electrode holder
50: stimulation electrode 80: connecting line
200: fastener 210 of the present invention: handle portion
212: slit 214: through hole
220, 240: insertion part 222, 242: hollow part
224, 244: insertion hole 225: support screw tightening groove
230: anchor member support 245: open surface
250: anchor member cover fastening portion

Claims (5)

The stimulation electrode support screw fastener of the small electrode system for brain stimulation
With the handle,
The anchor member is formed to be insertable, and includes an anchor member support part attached to one end of the handle part,
The anchor member includes a flange portion in which a pair of screw grooves facing each other is formed, and an electrode holder protruding integrally with the flange portion to support a pole electrode inserted therein.
Electrode support screw fastener for small electrode system for cranial nerve stimulation.
The method of claim 1,
The anchor member support part includes an insertion part attached to the handle part and a hollow part bent at the insertion part to insert the anchor member.
The hollow part is a flange portion of one side of the anchor member is inserted and the flange portion of the other side is exposed so that one of the screw groove is exposed, the pole electrode support screw coupled to the connecting line for supporting the magnetic pole inserted into the electrode holder and supply electricity Support screw fastening grooves are formed on both side surfaces of the hollow part to enable screwing of the
Electrode support screw fastener for small electrode system for cranial nerve stimulation.
The method of claim 1,
A cover of the anchor member is formed to be insertable, and further includes an anchor member cover fastening part attached to the other end of the handle part.
Electrode support screw fastener for small electrode system for cranial nerve stimulation.
The method of claim 3, wherein
The anchor member cover fastening part includes an insertion part attached to the handle part and a hollow part which is bent at the insertion part to open the cover part which is fastened to the electrode holder of the anchor member.
Electrode support screw fastener for small electrode system for cranial nerve stimulation.
The method of claim 4, wherein
A guide groove is formed on an outer surface of the cover of the anchor member, and a guide protrusion for engaging the guide groove of the cover is formed in the hollow part of the cover fastening portion.
Electrode support screw fastener for small electrode system for cranial nerve stimulation.

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