KR20220166435A - Catheter unit for cerebro spinal fluid test - Google Patents

Abstract

The present invention relates to a catheter unit for a cerebrospinal fluid examination. The catheter unit for a cerebrospinal fluid examination comprises: an outer catheter; and an inner catheter. The outer catheter is intrathecally introduced by a lumbar puncture to collect the cerebrospinal fluid for cerebrospinal fluid examination, has a front end acutely formed to enable a lumbar puncture, has a long passage along a one-way axis therein, and has outer slits, communicating with the passage, formed at regular intervals in a circumferential direction. The inner catheter is inserted into the passage of the outer catheter, and includes: a conduit main body part which has a flow path through which the cerebrospinal fluid can move and is provided with inner slits enabling the flow path and the outer slits to communicate with each other; a connection part communicatively connected to the conduit main body part so as to inject liquid treatment substances such as drugs or saline into the flow path of the conduit main body part; and an identification part which has a communication space formed to communicate with the flow path of the conduit main body part and enables the confirmation of whether the outer catheter is properly positioned in a cerebrospinal fluid space according to whether the substances are introduced into the communication space. According to the present invention, the catheter unit for a cerebrospinal fluid examination is effective in preventing the generation of hematoma caused by bleeding during a lumbar puncture.

Description

Catheter unit for cerebro spinal fluid test}

The present invention relates to a catheter unit for examining cerebrospinal fluid, and more particularly, when a catheter needs to enter the spinal canal in order to examine the cerebrospinal fluid, it is possible to easily check whether the catheter has entered the spinal canal for cerebrospinal fluid testing with an improved structure. It relates to a catheter unit.

Spinal tapping or lumbar puncture is a frequently used procedure for measuring cerebrospinal fluid pressure or examining cerebrospinal fluid. As shown in FIGS. 1 and 2, the lumbar puncture is a test method and treatment method in which a catheter is inserted into the subarachnoid space between the lumbar vertebrae to obtain cerebrospinal fluid or inject drugs into the spinal cavity necessary for diagnosing neurological diseases.

When a conventional catheter is inserted into the spinal canal for lumbar puncture, in order to check whether the catheter has entered the spinal canal, it is necessary to take out the inner needle from the outer needle and check whether the spinal cord flows out. , If the spinal cord does not flow out, the process of entering or retracting the needle into the spinal canal must be repeated. At this time, since the needle is occluded by a blood clot when the venous blood around the spinal canal flows into the needle, it is necessary to repeat the process of removing the entire needle from the human body, flushing, and entering or retracting the spinal canal again.

Therefore, conventional catheters used in lumbar puncture may increase procedure (procedure) time, damage the dura mater of the patient, cause complications such as intracranial hypotension, and puncture the veins around the spinal canal. It has a problem of forming a hematoma by bleeding.

As a prior art, there is Korean Patent Publication No. 10-2017-0096447.

The present invention has been made to solve the above problems, and an object of the present invention is to shorten the treatment (procedure) time during lumbar puncture, prevent damage to the dura mater of the patient's spinal cord, and cause complications such as intracranial hypotension. It is an object of the present invention to provide a catheter unit for cerebrospinal fluid examination that can prevent the occurrence of hematoma due to bleeding during lumbar puncture.

The problems of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the description below.

The catheter unit for cerebrospinal fluid examination according to the present invention for achieving the above object is entered into the spinal cavity by lumbar puncture method to collect cerebrospinal fluid for cerebrospinal fluid examination, and the tip is formed sharp to enable lumbar puncture, and inside an outer catheter in which a passage is formed along a one-way axis, and outer slits communicating with the passage are formed at equal intervals around the circumferential direction; And a conduit main body portion, which is inserted into the passage of the outer catheter, has a passage through which cerebrospinal fluid can move, and has inner slits communicating with the passage and the outer slits, and a liquid treatment substance such as a drug or saline solution. A connection portion communicatively connected to the conduit body portion so as to be injected into the flow path of the conduit body portion, and a communication space communicating with the conduit body portion flow path are formed, and the cerebrospinal fluid space is transferred to the cerebrospinal fluid space depending on whether a substance is introduced into the communication space. An inner catheter including an identification unit that allows checking whether the outer catheter is properly positioned;

Preferably, the identification unit includes a balloon-shaped catheter that is selectively inflated by the pressure of the material introduced into the communication space.

The present invention may include a valve rotatably installed in the inner catheter so that the conduit body of the inner catheter can be selectively fluidly communicated with at least one of the connection part and the identification part.

Preferably, the outer catheter includes a flange portion formed in an annular shape at a rear end and having at least one anti-rotation groove formed along the circumferential direction.

The inner catheter may include a positioning protrusion formed at a position corresponding to the anti-rotation groove of the flange portion and inserted into the anti-rotation groove.

A plurality of anti-rotation grooves of the flange portion may be formed at intervals along the circumferential direction. It is preferable that the flange portion includes a separation suppressing means for suppressing any separation of the positioning protrusion inserted into any one of the anti-rotation grooves.

The separation restraining means may include an embossed stopper formed on one surface defining the anti-rotation groove.

In the catheter unit for examining cerebrospinal fluid according to the present invention having the configuration as described above, the outer catheter enters the spinal cavity in a lumbar puncture method, forms a passage therein, and forms outer slits communicating with the passage, and the inner catheter The conduit body portion has a flow path for moving cerebrospinal fluid and inner slits communicating with the outer slits, the connection portion is connected to the conduit body portion to inject liquid treatment material into the flow path, and the identification unit connects to the flow path of the conduit body portion. It has a communication space and it is possible to confirm whether the outer catheter is located in the cerebrospinal fluid space according to the inflow of substances, thereby reducing the treatment (procedure) time during lumbar puncture, without damaging the patient's spinal cord dura, and reducing intracranial hypotension and It prevents the occurrence of the same complications and has the effect of not generating hematoma due to bleeding during the lumbar puncture process.

The effects of the present invention are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the description below.

1 and 2 are views for explaining a catheter unit according to the prior art.
Figure 3 is a perspective view for explaining a catheter unit for cerebrospinal fluid examination according to an embodiment of the present invention.
Figure 4 shows a separated state of one embodiment of the present invention.
5 is a cross-sectional view of one embodiment of the present invention.
6 is a VI-VI sectional view of FIG. 5;
7 is a cross-sectional view illustrating a connection unit employed in an embodiment of the present invention.
8 and 9 are views for explaining an identification unit employed in one embodiment of the present invention.
10 is a view for explaining a catheter unit for cerebrospinal fluid examination according to another embodiment of the present invention.
11 is a cross-sectional view XI-XI of FIG. 10 for explaining an embossed stopper employed in another embodiment of the present invention.
Figure 12 is a cross-sectional view XII-XII of Figure 10 for explaining a position fixing protrusion employed in another embodiment of the present invention.
13 is a view for explaining outer side slits and inner slits during rotation of an inner catheter in an outer catheter employed in another embodiment of the present invention.

Hereinafter, a catheter unit for cerebrospinal fluid examination according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a perspective view for explaining a catheter unit for cerebrospinal fluid examination according to an embodiment of the present invention, Figure 4 is a view showing a separated state of one embodiment of the present invention, Figure 5 is a cross-sectional view of one embodiment of the present invention 6 is a VI-VI cross-sectional view of FIG. 5, FIG. 7 is a cross-sectional view for explaining a connection unit employed in an embodiment of the present invention, and FIGS. 8 and 9 are a cross-sectional view for explaining an identification unit employed in an embodiment of the present invention. It is a drawing for

As shown in these figures, the catheter unit for cerebrospinal fluid examination according to an embodiment of the present invention is entered into the spinal canal in a lumbar puncture method to collect cerebrospinal fluid for cerebrospinal fluid examination, and includes an outer catheter 100 and an inner catheter ( 200) is included.

The outer catheter 100 has a sharp tip and has a long passage formed therein along a one-way axis, and outer slits 110 communicating with the passage are formed at equal intervals around the circumferential direction This enables lumbar puncture to the patient.

The outer catheter 100 allows the inner catheter 200 to be inserted into the passage formed therein, and enters the spinal canal during lumbar puncture, allowing cerebrospinal fluid to flow into the outer slits 110, thereby allowing the inner catheter to Through (200), the fluid movement of the cerebrospinal fluid can be achieved.

The inner catheter 200 is inserted into the passage of the outer catheter 100 and communicates with the outer slits 110 to enable fluid movement of the cerebrospinal fluid flowing into the outer slits, or to allows fluid movement. The inner catheter 100 includes a conduit body portion 210, a connection portion 220, and an identification portion 230.

The conduit main body 210 of the inner catheter 200 is inserted into the passage of the outer catheter 100 and forms a flow path 211 therein to enable movement of cerebrospinal fluid, and the flow path 211 and the outer slit forming inner slits 212 that communicate the slit 110. Here, the inner slits 212 allow the cerebrospinal fluid flowing into the outer slits 110 to flow into the flow path, and the liquid treatment substance injected into the inner catheter 200 is passed through the outer slits 110. can also be injected into the spinal canal.

The connection part 220 of the inner catheter 200 is communicatively connected to the conduit body 210 of the inner catheter 200, so that liquid treatment substances such as drugs or saline are injected into the passage of the conduit main body. make it possible The connection part 220 has a port part 221 on the opposite side of the part connected to the conduit body part 210, thereby blocking the flow path 211 of the conduit body part 210 from the outside and using a syringe to the flow path ( 211) to inject liquid treatment substances.

At this time, since the ends of the outer catheter 100 and the inner catheter 200 have entered the patient's skin S, the flow path 211 of the conduit body 210 is blocked from the outside, and the flow path 211 ), the injected saline solution is accepted without leaking out.

The identification part 230 of the inner catheter 200 forms a communication space 231 communicating with the passage 211 of the conduit main body 210 and the end of the conduit main body opposite to the inner slits 221. is provided, and it is possible to check whether the outer catheter 100 is properly positioned in the cerebrospinal fluid space according to whether or not a substance is introduced into the communication space 231.

In the catheter unit for cerebrospinal fluid examination according to an embodiment of the present invention having such a configuration, the outer catheter 100 enters the spinal cavity in a lumbar puncture method, forms a passage therein, and has outer slits communicating with the passage ( 110) is formed, and the conduit body portion 210 of the inner catheter 200 has inner slits 212 communicating with the passage 211 for moving cerebrospinal fluid and the outer slits 110, and the connection portion ( 220) is connected to the conduit body portion 210 to inject a liquid treatment substance into the flow path, and the identification unit 230 has a communication space communicating with the flow path 211 of the conduit body portion 210 and introduces the substance. By making it possible to confirm whether the outer catheter is located in the cerebrospinal fluid space according to whether or not it exists, the treatment (procedure) time during lumbar puncture is shortened, the patient's spinal cord dura is not damaged, and complications such as intracranial hypotension are prevented from occurring, It has the effect of not generating a hematoma due to bleeding during the lumbar puncture process.

Meanwhile, the identification unit 230 includes a balloon catheter 232 that is selectively inflated by the pressure of the material introduced into the communication space.

In the balloon catheter 232 of the identification unit 230, the outer catheter 100 is connected to the inner catheter 200 in a state in which saline is filled in the channel 211 of the inner catheter 200 through the connection unit 220. When inserted into the spinal cord space together, when the cerebrospinal fluid is introduced into the channel 211 side of the inner catheter 200 via the outer slits 110 and the inner slits 212, the pressure according to the inflow It expands as the saline moves toward the communication space.

Therefore, the balloon catheter 232 of the identification unit 230 expands by the pressure according to the inflow of the cerebrospinal fluid when the cerebrospinal fluid flows into the inner catheter 200, thereby confirming whether the catheter unit enters the spinal cavity. In order to do this, after the inner catheter 200 is pulled out of the outer catheter 100, the entry can be easily checked immediately without the need to check that the cerebrospinal fluid is flowing out, and the inner catheter 200 is inserted into the outer catheter 100. Since entry into the spinal canal is checked directly from the state, the operation time during lumbar puncture is shortened, the patient's discomfort is minimized, spinal cord dura mater damage caused by repeated insertion of the catheter unit into the body is prevented, and hematoma caused by bleeding during the lumbar puncture process is prevented. It has the advantage of not being created.

In addition, it is preferable that this embodiment includes a valve 240. The valve 240 allows the conduit body 210 of the inner catheter 200 to selectively communicate with at least one of the connection part 220 and the identification part 230 so that fluid flow is possible. It is rotatably installed in the inner catheter 200.

For example, when the valve 240 communicates the conduit main body 210 and the connection part 220, the saline solution is filled in the conduit main body 210. Meanwhile, when the valve 240 allows the conduit body 210 and the identification unit 230 to communicate, the saline solution flows into the inner catheter 200 when the outer catheter 100 and the inner catheter 200 enter the spinal cavity. The fluid moves to the identification unit by the cerebrospinal fluid to inflate the balloon catheter 232.

On the other hand, it is preferable that the outer catheter 100 includes a flange portion 120. The flange portion 120 of the outer catheter 100 is formed in an annular shape at the rear end of the outer catheter 100 and forms at least one anti-rotation groove 121 along the circumferential direction.

Preferably, the inner catheter 200 includes a positioning protrusion 250. The positioning protrusion 250 is formed at a position corresponding to the anti-rotation groove 121 formed in the flange portion 120 of the outer catheter 100 and is inserted into the anti-rotation groove 121, so that the inner catheter 200 ) suppresses arbitrary rotation in the state inserted into the passage of the outer catheter 100, and enables the inner slits 212 to be positioned in a state of communication with the outer slits 110, so that cerebrospinal fluid flows smoothly or intracerebrospinal fluid injection of liquid therapeutic substances is possible.

An embodiment of the present invention has been described above. Hereinafter, a catheter unit for examining cerebrospinal fluid according to another embodiment of the present invention will be described with reference to FIGS. 10 to 13 .

10 is a view for explaining a catheter unit for cerebrospinal fluid examination according to another embodiment of the present invention, and FIG. 11 is a cross-sectional view XI-XI of FIG. 10 for explaining an embossed stopper employed in another embodiment of the present invention. 12 is a XII-XII cross-sectional view of FIG. 10 for explaining a position fixing protrusion employed in another embodiment of the present invention, and FIG. 13 is an outer slit during rotation of the inner catheter in an outer catheter employed in another embodiment of the present invention. It is a drawing for explaining the fields and inner slits.

As shown in these drawings, this embodiment is similar in most configurations to the previously described embodiments, but there are differences in the structure of the flange portion 120 formed on the outer catheter 100 and the positioning protrusion 250 of the inner catheter. there is

That is, the flange portion 120 may form a plurality of anti-rotation grooves 121 at intervals in the circumferential direction or may be formed long, and may include a breakaway restraining means. The release suppressing means includes an embossed stopper 122 formed on one surface defining the rotation prevention groove 121 to suppress arbitrary departure of the positioning protrusion 250 inserted into any one of the rotation prevention grooves do.

The embossed stopper 122, when the inner catheter 200 is inserted into the passage of the outer catheter 100, the positioning protrusion 250 of the inner catheter 200 slides on the surface and prevents the rotation To be inserted into the groove 121, it is located on the inlet side of the anti-rotation groove 121 and forms an elliptical surface (see FIG. 11).

On the other hand, in this embodiment, the anti-rotation groove 121 may be formed long along the inner circumferential direction of the outer catheter (100). The rotational range of the anti-rotation groove 121 can be determined so that the inner catheter 200 can be rotated for accommodating saline when the outer catheter 100 enters the spinal canal and for inflow of cerebrospinal fluid when the outer catheter 100 enters the spinal canal (Fig. see 12).

In addition, the positioning protrusion 250 of the inner catheter 200 employed in this embodiment is made of an elastic ball structure, so that when the inner catheter rotates, it slides and protrudes from the anti-rotation groove 121, so that the anti-rotation groove It is inserted into the insertion groove (reference numeral not shown), enabling rotation and position fixing of the inner catheter 200 (see FIG. 12(c)).

In addition, the positioning protrusion 250 has a protrusion (reference numeral not shown) on an end surface contacting the anti-rotation groove 121 and is inserted into an insertion groove (reference numeral not shown) formed in the anti-rotation groove 121. As the protrusion is inserted, the position of the inner catheter 200 is fixed (see FIG. 12 (b)).

In this embodiment having such a configuration, the inner catheter 200 is rotated in the outer catheter 100 after the valve 240 is rotated to communicate the conduit body 210 and the connecting portion 220 to each other before insertion of the spinal canal. so that the outer slits 110 and the inner slits 212 are not communicated with each other. At this time, since the conduit body 210 and the connection part 220 do not communicate with the outside, the saline solution injected through the connection part can be accommodated in the flow path 211 (see FIG. 13(a)).

Then, in this embodiment, when entering the cerebrospinal fluid, the outer catheter into which the inner catheter 200 is inserted after rotating the valve 240 to communicate the conduit main body part 210 and the identification part 230 with each other. 100 enters the cerebrospinal cavity, and the inner catheter 200 is rotated to communicate the outer slits 110 and the inner slits 212 (see (b) of FIG. 13).

In this process, the cerebrospinal fluid flows into the conduit main body 210 via the outer slits 110 and the inner slits 212, and the saline solution moves to the identification unit due to the pressure of the inflow to open the balloon catheter 232. inflate At this time, the operator checks the inflated balloon catheter, easily determines whether the catheter unit has entered the spinal canal, and can perform lumbar puncture in a short time without damaging the dura mater of the spinal cord.

In the above, preferred embodiments of the present invention have been described, but the present invention is not limited to the embodiments described above, but is defined by what is described in the claims, and various modifications and developments can be made in the technical field to which the present invention belongs. self-explanatory

100: outer catheter 110: outer side slits
120: flange portion 121: anti-rotation groove
122: embossed stopper 200: inner catheter
210: conduit body portion 211: flow path
212: inner slits 220: connection
221: port unit 230: identification unit
231: communication space 232: balloon catheter
240: valve 250: positioning protrusion

Claims (6)

It is entered into the spinal canal by lumbar puncture method to collect cerebrospinal fluid for cerebrospinal fluid examination, and the tip is formed sharp to enable lumbar puncture, and a long passage is formed along a one-way axis inside, and the outer side communicates with the passage An outer catheter in which slits are formed at equal intervals around the circumferential direction; and
It is inserted into the passage of the outer catheter, and a conduit body portion having a passage through which cerebrospinal fluid can move and inner slits communicating with the passage and the outer slits are formed, and a liquid treatment substance such as a drug or saline solution is passed through the conduit. A connection part communicatively connected to the conduit main body so as to be injected into the passage of the main body, and a communication space communicating with the passage of the conduit main body are formed, and depending on whether a substance is introduced into the communication space, the outer A catheter unit for examining cerebrospinal fluid, characterized in that it comprises: an inner catheter including an identification unit for confirming whether the catheter is properly positioned.
According to claim 1,
The catheter unit characterized in that the identification unit comprises a balloon catheter that is selectively inflated by the pressure of the material introduced into the communication space.
According to claim 1,
A valve rotatably installed in the inner catheter so that the conduit body of the inner catheter can be selectively fluidly communicated with at least one of the connection part and the identification part; a cerebrospinal fluid test comprising: catheter unit for
According to claim 1,
The outer catheter includes a flange portion formed in an annular shape at the rear end and having at least one anti-rotation groove formed along the circumferential direction,
The catheter unit for cerebrospinal fluid examination, characterized in that the inner catheter comprises a positioning protrusion formed at a position corresponding to the anti-rotation groove of the flange portion and inserted into the anti-rotation groove.
According to claim 4,
A plurality of anti-rotation grooves of the flange portion are formed at intervals along the circumferential direction,
The catheter unit for examining cerebrospinal fluid, characterized in that the flange portion comprises a breakaway suppression means for suppressing any breakaway of the positioning protrusion inserted into any one of the anti-rotation grooves.
According to claim 5,
The catheter unit for cerebrospinal fluid examination, characterized in that the separation restraining means comprises an embossed stopper formed on one surface defining the anti-rotation groove.

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