KR20200071476A - Guide-wire handler for measuring blood-vessel pressure using optical pressure sensor - Google Patents

Abstract

The present invention relates to a guide wire handler for blood vessel pressure measurement using an optical pressure sensor. The handler includes: a case having an optical connection terminal inserted through a leading end, having a guide wire mounted with an optical pressure sensor inserted through an end to be connected to the optical connection terminal, and having one side on which a switch hole is formed; a connector rotatably installed in the case, penetrated by the guide wire, provided with a cap coupling portion on the outside surface of the part protruding through the end of the case at the end thereof, and provided with a switch binding portion on one side of the outside surface corresponding to the switch hole of the case; a gripper penetrated by the guide wire, having a leading end inserted into the connector through the end of the connector, and having a pair of tongs elastically foldable to bind the guide wire at the end thereof; a cap detachably coupled to the cap coupling portion of the connector, penetrated by the guide wire, and having an inner binding portion where the tongs of the gripper are inserted and folded; and a switch installed on the switch hole side of the case and bound to the switch binding portion of the connector so as to be capable of limiting the free rotation of the connector and the gripper and the cap bound thereto. According to the present invention, optical connection loss can be minimized to rotate the guide wire.

Description

Guide-wire handler for measuring blood-vessel pressure using optical pressure sensor

The present invention relates to a handler for handling a guide wire with an optical pressure sensor capable of measuring blood vessel pressure in order to find a site of vascular stenosis.

In general, a method of finding a coronary vascular stenosis site is a method using a formative agent. That is, a stenosis agent is injected into a blood vessel, and a stenosis site is identified through X-lay image reading. However, it has been pointed out that it is difficult to find an exact stenosis site because the determination of the vascular stenosis through a molding agent depends on the judgment of a doctor.

On the other hand, in the case of a method using a pressure sensor, the pressure change value can be confirmed with an accurate value by measuring the pressure of the stenosis in the blood vessel and comparing the measured pressure with a reference pressure (PA) to accurately determine the stenosis location within the blood vessel. .

Republic of Korea Patent Publication No. 10-2018-0020978 discloses an apparatus and method for intravascular measurement. Looking at the disclosed prior patent, the monitoring guide wire is coupled to the connector of the portable display unit, and when the monitoring guide wire enters the blood vessel, a signal from the sensor of the monitoring guide wire is transmitted to the portable display unit to measure blood vessel conditions such as intravascular pressure. Can be.

Accordingly, in the case of the prior art using a pressure sensor, including the prior patent, it is possible to accurately transmit a signal sensed by the sensor by minimizing structural connection loss and to move the guide wire flexibly along a complex blood vessel. Research is urgently needed.

Republic of Korea Patent Publication 10-2018-0020978 (published date: February 28, 2018)

The present invention has been devised to solve the above-described problems, and it is possible to minimize the structural loss of the connection between the guide wire and the optical connection terminal, and also a blood vessel using an optical pressure sensor capable of freely rotating the guide wire with respect to the optical connection terminal. The aim is to provide a guide wire handler for pressure measurement.

The guide wire handler for measuring blood vessel pressure using the optical pressure sensor according to the present invention for realizing the above-described problem is inserted into the optical connection terminal through the tip, and the guide wire equipped with the optical pressure sensor is inserted through the end. A case connected to the optical connection terminal and having a switch hole formed on one side; It is installed so as to be rotatable inside the case, the guide wire is penetrated therein, and a cap coupling portion is provided on an outer surface of a portion protruding through the end of the case at the end, and other corresponding to the switch hole of the case A connector provided with a switch binding portion on one side surface; A gripper through which the guide wire is penetrated, a distal end is inserted into the connector through an end of the connector, and a forceps part that is elastically retracted at the end to bind the guide wire is provided; A cap which is detachably coupled to the cap coupling portion of the connector, the guide wire is penetrated, and a gripping portion of the gripper is inserted therein to form a binding portion; It includes a switch that is installed on the switch hole side of the case so as to limit the free rotation of the connector and the gripper and the cap coupled thereto, and a switch engaged with the switch binding portion of the connector.

The switch engagement portion of the connector is in the form of a ring gear, and an engaging jaw that can be fitted into any one of the gaps between the teeth and the teeth of the ring gear may be formed on the inner surface of the switch by pressing the switch.

On the inner surface of the switch, a wedge toward the inside of the case is protrudingly formed by the pressing operation of the switch, and the connector is inclined to close the wedge of the switch so that the wedge of the switch can be linearly moved to the distal side. An elastic member may be interposed between the connector and the case to impart elastic force so as to return the connector linearly moved by the switch wedge when the switch is depressed.

A connection pin connected to the guide wire side is protruded at an end of the optical connection terminal, and a sleeve connecting a connection with the guide wire may be selectively detachably connected to the connection pin.

The guide wire handler for measuring blood vessel pressure using the optical pressure sensor according to the present invention can flexibly move along a complicated vessel because it can freely rotate the guide wire, and connects the guide wire with a gripper, connector, sleeve, etc. Since it is structurally connected to the optical connection terminal through, it is possible to accurately transmit the signal sensed by the sensor without noise by minimizing connection loss.

1 is a perspective view of a guide wire handler for measuring blood vessel pressure using an optical pressure sensor according to an embodiment of the present invention,
Figure 2 is an exploded perspective view of the handler shown in Figure 1,
3 is an exploded partial cross-sectional view of the handler illustrated in FIG. 1,
FIG. 4 is a cross-sectional view of the handler shown in FIG. 1, in which a switch is pressed and released,
Figure 5 is a cross-sectional view of the handler shown in Figure 1, a cross-sectional view of the switch pressed state,
6 is a block diagram of a pressure display device and a guide wire connected by a handler according to the present invention.

When explaining a preferred embodiment of the present invention with reference to the accompanying drawings as follows.

1 to 6, the guide wire handler for measuring blood vessel pressure using the optical pressure sensor 40 according to the present invention includes a guide wire 10 and an optical connection terminal on the pressure display device 30 side ( 20) by structurally connecting, the case (100,110,120), the switch (130,140), the connector 150, the gripper 160, and the cap 170.

The guide wire 10 is formed to be elongated so as to be movable along the blood vessel. The guide wire 10 has a hollow structure capable of accommodating an optical fiber therein, and an entry end portion of a spiral spring structure wound spirally along an extension direction may be provided at an end to increase the entry efficiency in the blood vessel. The guide wire 10 may be formed of a metal material.

The optical fiber 12 is penetrated inside the guide wire 10. The tip end of the guide wire 10 is structurally connected to the optical connection terminal 20. At the end of the guide wire 10, an optical pressure sensor 40 that is connected to the optical fiber 12 and capable of measuring the pressure in the blood vessel is embedded.

The optical pressure sensor 40 is formed such that the flexible diaphragm 42 installed to be spaced apart from the distal end of the optical fiber 12 by a pressure F in the blood vessel. The optical pressure sensor 40 changes the distance between the end of the optical fiber 12 and the flexible diaphragm 42 according to the degree of deformation of the flexible diaphragm 42, and the end of the optical fiber 12 and the flexible diaphragm 42 The peak wavelength detected by the photodetector 34 is moved in response to the change in the distance between them. The shift of the peak wavelength detected from the photodetector 34 is calculated by pressure in the calculation unit 36 and displayed through the display unit 38.

The connecting pin 22 to which the guide wire 10 is connected is configured at the end of the optical connecting terminal 20. The connecting pin 22 of the optical connection terminal 20 may be selectively coupled with a sleeve 24 capable of solving the difference in connection length and diameter. The sleeve 24 of the optical connection terminal 20 may be fitted so as to be detachably attached to the connection pin 22. For example, as shown, the sleeve 24 of the optical connection terminal 20 is formed longer than the connection pin 22 of the optical connection terminal 20, it may be made of a multi-stage structure in which the pipe diameter is changed. The connecting pin 22 and the sleeve 24 of the optical connection terminal 20 may be made of a hollow structure such that the guide wire 10 can be inserted.

An optical fiber (not shown) for transmitting a signal transmitted through the optical fiber 12 of the guide wire 10 is built in the front end of the optical connection terminal 20, and the end is coupled to the ferrule connected to the sleeve 24.

The pressure display device 30 receives the optical signal transmitted from the optical pressure sensor 40 through the circulator from the light source 32 supplying light to the optical fiber 12 through the optical connection terminal 20 and the electrical signal. A display unit such as a photodetector 34 outputting to, a calculation unit 36 for calculating the intravascular pressure from the signal received from the photodetector 34, and a monitor for visually viewing the calculated intravascular pressure (38) and the like.

The case (100,110,120) constitutes the appearance of the handler, and the optical connection terminal (20) is inserted through the tip and the tip of the guide wire (10) is inserted through the end, and the body (100) and the tip cover (110) , The end cover 120 may be included.

The main body 100 is open at both ends and ends, and may be formed in a hollow cylindrical structure. The main body 100 may be formed in a multi-stage structure in which the outer diameter changes. That is, the main body 100 may be formed of a small diameter portion 102 having a relatively small outer diameter at the tip, and a large diameter portion 104 having a larger outer diameter at the distal end.

Inside the main body 100, a partition wall 106 for partitioning the large-diameter portion 104 and the small-diameter portion 102 of the main body 100 may be configured. A through hole 106a may be formed in the center of the partition wall 106 so that the connection pin 22 or the sleeve 24 of the optical connection terminal 20 can be penetrated.

A switch hole 100a in which switches 130 and 140 are installed may be formed on one side of the outer surface of the main body 100. The switch hole 100a may be formed to have a predetermined length toward the large-diameter portion 104 and the small-diameter portion 102 of the main body 100 around the boundary of the large-diameter portion 104 and the small-diameter portion 102 of the main body 100, respectively. . A plurality of switch holes 100a may be formed along the circumferential direction of the main body 100. That is, the switch holes 100a may be formed of a pair formed at positions facing each other. In addition, a wall 108 that surrounds both side edges of the switch hole 100a may be protruded on the outer surface of the small diameter portion 102 of the main body 100.

The front cover front end of the main body 100 may be configured to be coupled to the front end cover 110 so as to be detachably attached. The front cover engaging portion may be formed of a protrusion 100b protruding in a radially outer direction of the main body 100. The projections 100b for the front end cover coupling portion may be made of a pair positioned opposite each other. The projections 100b for the front end cover coupling portion may be respectively formed in the rotational angular position such as the switch hole 100a along the circumferential direction of the main body 100.

The end cover coupling portion may be configured to be detachably attached to the end cover 120 at the outer surface end of the main body 100. The end cover coupling portion may be formed of a protrusion 100c protruding in a radially outer direction of the main body 100. The protrusions 100c for the end cover coupling portion may be made of a pair positioned opposite each other. The protrusions 100c for the end cover coupling portions may be formed at positions in the angular direction, such as the switch hole 100a, along the circumferential direction of the body 100, respectively.

The front cover 110 may be formed in a cap structure with one side underside open so that it can be fitted to the outside of the front end of the main body 100. The underside of the other side of the front end cover 110 is not opened to cover the front end of the main body 100, but a through hole 110a may be formed in the center so that the optical connection terminal 20 can be penetrated. The through-hole 110a of the tip cover 110 may have a size, shape, and the like so that the distal end of the optical connection terminal 20 is not detached.

A coupling portion may be configured on the side surface of the tip cover 110 so as to be detachably coupled with the main body 100. The coupling portion of the tip cover 110 may be formed of a coupling hole 112 into which the protrusion 100b for the tip cover coupling portion of the main body 100 can be fitted. The coupling hole 112 of the tip cover 110 may be formed to be long such that the protrusion 100b for the tip cover coupling portion of the main body 100 can move a predetermined distance along the circumference. The coupling hole 112 of the tip cover 110 may also be formed in a pair formed at positions facing each other. In addition, a guide passage (not shown) may be formed on the side surface of the front cover 110 to guide the protrusion 100b for the front cover attachment portion of the main body 100 to the coupling hole 112 of the front cover 110. . The guide passage of the front end cover 110 may be formed in a straight shape from one end of the coupling hole 112 of the front end cover 110 to the end of the front end cover 110. The guide passage of the tip cover 110 may also be made of a pair.

The end cover 120 may also be formed of the same structure as the tip cover 110. That is, the end cover 120 may be formed of a cylindrical cap with one bottom surface open, and a through hole 120a may be formed at the other bottom surface not opened. A pair of coupling holes 122 and a pair of guide passages 124 may be formed on a side surface of the end cover 120. The through hole 120a of the end cover 120 may be formed to have a size that can penetrate to the large diameter portion 152 of the connector 150 to be described later.

Meanwhile, a ring-shaped flange 126 that protrudes toward the inside of the end cover 120 and surrounds the through hole 120a of the end cover 120 may be configured on the side of the through hole 120a of the end cover 120. The ring 180 of the end cover 120 may support the spring 180 by fitting the end of the spring 180.

A cap insertion groove 120b into which a part of the cap 170 can be inserted may be formed on the bottom side of the end cover 120 that is not opened.

The switches 130 and 140 may be variously implemented according to an operation method or the like.

Preferably, the switches 130 and 140 may be configured in a button manner. That is, the switches 130 and 140 include a support unit 130 for supporting a switch engaging portion 158 of the connector 150 to be described later and a locking jaw 132 that can be mechanically engaged, and the support unit 130 for the main body 100 of the case It may include a fixing portion 140 for fixing to.

The locking jaw 132 of the switch may be formed to protrude a predetermined length in the front-rear direction at the end of the support 130 of the switch.

The support portion 130 of the switch may be made of a material having elasticity such as plastic so that it is elastically pressed into the interior of the main body 100 through the switch hole 100a of the main body 100, and can be returned when the external force disappears. The support 130 of the switch can be coupled to the body 100 like a cantilever beam. That is, the support part 130 of the switch is a fixed end 130a that is partially fixed to the small-diameter portion 102 of the main body 100, and the other part is located in the switch hole 100a of the main body 100 to be freely depressed. It may be made of a column (130b). The fixed end 130a of the support part 130 of the switch may be wider than the free end 130b of the support part 130 of the switch with respect to the circumferential direction so as to be hung on the wall 108 of the main body 100. The fixed end 130a of the support 130 of the switch is formed at a relatively thicker end at the free end 130b side of the support 130 of the switch, and its tip is formed relatively thinner, so that the fixed part of the switch ( A step 130c that takes 140) may be configured.

The fixing part 140 of the switch is a ring-shaped member that fits into the small diameter part 102 of the main body 100 of the case and allows the tip end of the fixed end 130a of the support part 130 of the switch to be closely adhered to the body 100 of the case. It can be done. The fixing part 140 of the switch may be fixed by being interposed between the step 130c of the support part 130 of the switch and the front end cover 110 of the case. The fixing part 140 of the switch is formed such that its inner diameter is approximately the same as the outer diameter of the small diameter part 102 of the main body 100, so that the small diameter part 102 of the main body 100 can be interviewed. At this time, the inner peripheral surface of the fixing part 140 of the switch is inserted into the small diameter portion of the main body 100 through the front end of the main body 100 so that the protrusion 100b for the front end cover coupling portion of the main body 100 can be penetrated without being caught. The through groove 142 may be formed. A fitting groove 144 may be formed on the inner circumferential surface of the fixing part 140 of the switch so as to be fitted to the front end of the fixing end 130a of the support part 130 of the switch. The through groove 142 and the fitting groove 144 of the fixing part 140 of the switch may be formed at different positions along the circumferential direction.

A slit 134 such as a hemispherical shape may be protruded on the outer surface of the support 130 of the switch for ease of operation and convenience.

Meanwhile, a wedge 136 protruding into the interior of the main body 100 through the switch hole 100a of the main body 100 may be formed on the inner surface of the support 130 of the switch. The wedge 136 of the switches 130 and 140 may be positioned to correspond to the front end side of the connector 150, whereby the connector 150 can be more easily and smoothly moved in a straight line. The wedge 136 of the switches 130 and 140 may be located under the chin 134 of the switches 130 and 140 so as to sufficiently receive external force. The wedge 136 of the switches 130 and 140 may be formed of an inclined surface 136a whose end surface becomes narrower toward the inside of the main body 100, whereby the connector 150 can be easily moved by the force pressing the switch 130 or 140. Can be moved in a straight line.

In addition, when the force pressing the switch 130, 140 is released and the switch 130, 140 is returned, the connector 150, the gripper 160, and the cap 170 also move linearly toward the front ends of the cases 100, 110, 120, so that the elastic member can be returned to its original shape. Can be installed. The elastic member can be implemented in various ways. That is, the elastic member is interposed between the connector 150 and the main body 100 of the case by being fitted to the outside of the connector 150, and may be formed of a spring 180 elastically deformed along the linear movement direction of the connector 150. The tip of the spring 180 is in close contact with the bearing 190 to be described later, and the end of the spring 180 can be fitted to the ring-shaped flange 126 of the end cover 120.

Meanwhile, a spring seat 185 may be fitted to the front end side of the connector 150 to support the front end of the spring 180.

The connector 150 is inserted so as to be freely rotatable in the large-diameter portion 104 of the main body 100 so that the guide wire 10 can be rotated.

The connector 150 is such that the connecting pin 22 or the sleeve 24 of the optical connection terminal 20 is inserted through the tip, the gripper 160 is inserted through the end, and the guide wire 10 can be penetrated. It can be formed into a hollow pipe structure.

The connector 150 may be formed in a multi-stage structure in which the outer diameter changes. Preferably, the outer diameter of the connector 150 may gradually decrease as it goes from the tip to the end. For example, the connector 150 includes a large diameter portion 152 having a relatively large outer diameter, an intermediate portion 154 having a smaller outer diameter than the large diameter portion 152, and a small diameter portion 156 having a smaller outer diameter than the intermediate portion 154. Can be. The small diameter portion 156 and the middle portion 154 of the connector 150 may be formed to be insertable in the cap 170.

The cap coupling portion 156a may be configured to be detachably coupled to the cap 170 at the outer surface end of the connector 150, that is, the small diameter portion 156 of the connector 150. Preferably, the cap coupling portion 156a of the connector 150 may be formed of a spiral portion so that the connector 150 and the cap 170 can be screwed.

On the outer surface of the connector 150, a locking jaw 156b may be protruded from the tip of the cap coupling portion 156a of the connector 150. The locking jaw 156b of the connector 150 may be formed in a ring shape. The locking jaw 156b of the connector 150 may be formed at the boundary between the small diameter portion 156 and the middle portion 154 of the connector 150.

The locking jaw 156b of the connector 150 is structurally caught by the cap 170, but when a certain force is applied, it is inserted into the inside of the cap 170 or detachable from the cap 170, so that the inner diameter of the tip of the cap 170 And may be formed to have approximately the same diameter.

On the outer side of the connector 150, a switch binding portion 158 that can be engaged with the switches 130 and 140 is configured. The switch binding portion 158 may be configured in the large-diameter portion 152 of the connector 150 to be positioned corresponding to the switch hole 100a of the cases 100, 110, and 120. The switch binding unit 158 may be variously implemented according to the binding method with the switches 130 and 140. Preferably, the switch binding portion 158 may be formed in a ring gear shape having a larger diameter than the large diameter portion 152 of the connector 150. That is, the switch binding portion 158 may be formed by maintaining a certain gap in the entire circumference of the connector 150 so that the locking jaws 132 of the switches can be sandwiched between a plurality of teeth. Therefore, regardless of the rotation angle direction/position of the connector 150 with respect to the cases 100, 110, and 120, the locking jaw 132 of the switch is inserted into the switch binding portion 158 of the connector 150 to bind the connector 150. have. The switch binding portion 158 of the connector 150 may be configured on the outer front end side of the connector 150 so as to face the switches 130 and 140 when engaged.

On the other hand, the connector 150 is extended from the large diameter portion 152 of the connector 150 to the tip side, and may further include an inclined portion 159 whose outer diameter gradually decreases toward the tip. The inclined portion 159 of the connector 150 is inclined to correspond to the inclined surface 136a of the inclined surface 136a of the switches 130 and 140 so that the inclined surface 136a of the wedge 136 of the switches 130 and 140 can be interviewed. Lose. Accordingly, even when the wedge 136 of the switches 130 and 140 is pressed in the vertical direction and the linear movement direction of the connector 150, the connector 150 can be easily linearly moved.

A bearing 190 may be interposed between the connector 150 and the cases 100, 110, and 120 to facilitate free rotation of the connector 150 relative to the cases 100, 110, and 120. The bearing 190 may be fitted to the large diameter portion 152 of the connector 150.

The gripper 160 is coupled to the connector 150 to bind the guide wire 10. The gripper 160 may be formed in the form of a hollow tube through which the guide wire 10 passes. The gripper 160 may be composed of a connector coupling portion 162 and a forceps portion 164. The connector coupling portion 162 of the gripper 160 is inserted into the connector 150 through the end of the connector 150. The connector coupling portion 162 of the gripper 160 may be formed to have a size corresponding to the inner diameter of the small diameter portion 156 of the connector 150 so as to be integrally rotated or rotationally restricted with the connector 150. The forceps 164 of the gripper 160 is configured at the end of the connector coupling portion 162 of the gripper 160. The forceps 164 of the gripper 160 are formed with a larger diameter than the connector coupling portion 162 of the gripper 160. The tongs 164 of the gripper 160 are composed of a plurality of tongs 164a that can be radially arranged to open or close. The forceps 164 of the gripper 160 may be formed in the form of a truncated cone that gradually decreases in outer diameter toward the end. In addition, an end line of the connector coupling portion 162 of the gripper 160 may be formed with an incision line 162a which is an extension line of the incision line between the forceps and the forceps of the gripper 160.

The cap 170 is fastened to the connector 150 to close the clamps of the gripper 160 so that the clamps of the gripper 160 hold one side of the guide wire 10 to bind the guide wire 10.

The cap 170 may be formed in a hollow pipe shape so that the guide wire 10 is penetrated and the connector 150 and the gripper 164 of the gripper 160 can be inserted.

The cap 170 may be formed of a cylindrical portion 172 and a truncated cone shape 174 according to the outer shape. The cylindrical portion 172 of the cap 170 is a place where the connector 164 of the connector 150 and the gripper 160 are inserted, and may be formed of a cylindrical outer diameter. The cone-shaped portion 174 of the cap 170 may be formed in a cone-shaped shape that gradually decreases in outer diameter toward the end. Accordingly, the penetration of the guide wire 10 through the end of the cap 170 may be easy and convenient.

Looking inside the cylindrical portion 172 of the cap 170 in order from the distal end of the cap 170, the middle portion 154 of the connector 150 corresponds to the outer diameter of the middle portion 154 of the connector 150 The large-diameter portion 172a to be inserted, the small-diameter portion 156 of the connector 150 corresponds to the outer diameter, and the coupling portion 172b formed with a screw so as to be screwable and the forceps 164 of the gripper 160 It may be made of a binding portion (172c). The binding portion 172c of the cap 170 is formed into a truncated cone shape corresponding to the fully closed shape of the forceps 164 of the gripper 160 so that the guide wire 10 penetrated into the gripper 160 can be bound. Can be. At this time, since the side of the binding portion 172c of the cap 170 and the side of the forceps 164 of the gripper 160 are inclined with respect to the coupling direction of the cap 170 and the gripper 160, the cap 170 is gradually As the forceps 164 of the gripper 160 are inserted into the binding portion 172c, the clamping portion 164 may be opened or closed while being separated.

On the other hand, the inside of the conical shape 174 of the cap 170 may be a conical shape that gradually increases in diameter toward the end. Accordingly, the guide wire 10 can be easily penetrated into the cap 170.

When explaining the effect of the guide wire handler for measuring blood vessel pressure using the optical pressure sensor according to an embodiment of the present invention configured as described above in detail as follows.

The assembly process of the handler of the present invention is as follows.

In the state where the support part 130 of the switch is placed in the switch hole 100a of the main body 100 of the case, the fixed part 140 of the switch is inserted into the front end of the main body 100 of the case, and then the fixed part 140 of the switch ) After rotating the fixing part 140 of the switch by a certain angle so that the fitting groove 144 of the switch is arranged in line with the support 130 of the switch, the supporting part of the switch in the fitting groove 144 of the fixing part 140 of the switch Push the fixing part 140 of the switch toward the support part 130 of the switch so that the tip of the fixing end 130a of 130 is fitted.

Next, insert the front cover 110 into the optical connection terminal 20 through the front end of the optical connection terminal 20, and then protrude for the front end cover coupling portion of the main body 100 in the guide passage (not shown) of the front end cover 110. Positioning the (100b) so that the front end cover 110 is in close contact with the front end of the main body 100 to position the protrusion 100b for the front end cover coupling portion of the main body 100 in the coupling hole 112 of the front end cover 110. In this state, the tip cover 110 is rotated at an angle.

Then, after inserting the bearing 190 and the spring 180 in order to the connector 150, the connector 150 is inserted through the end of the body 100 of the case, and the gripper 160 is inserted into the connector 150. .

Next, like the front end cover 110, the end cover 120 is inserted into the end of the main body 100 of the case, and then rotated.

Next, in a state in which the cap 170 is fitted to the front end of the guide wire 10, the guide wire 10 is inserted into the gripper 160 and the connector 150 to connect the pin 22 or sleeve of the optical connection terminal 20. (24) can be structurally connected.

Next, by pressing the switches 130 and 140 and restraining the free rotation of the connector 150 and the gripper 160, the cap 170 is screwed into the small diameter portion 156 of the connector 150 to turn the cap 170 by screwing. ) Is fixed to the connector 150. In addition, since the forceps 164 of the gripper 160 are closed by the cap 170, the guide wire 10 is bound to the forceps 164 of the gripper 160 to be fixed without being separated from the handler. Can be.

On the other hand, the handler of the present invention can be disassembled through the opposite process.

When the handler of the present invention is assembled in this way, as shown in FIG. 4, in the state in which the switches 130 and 140 are not pressed, the locking jaw 132 of the switch and the switch binding part 158 of the connector 150 are structurally separated from each other. When in the state, holding the cap 170 and turning it, the connector 150, the gripper 160 and the cap 170, and the cap 170 can be freely rotated with respect to the cases 100, 110, and 120, and accordingly to the gripper 160. The bound guide wire 10 can be rotated.

On the other hand, as shown in FIG. 5, when the chin portion 134 of the switches 130 and 140 is pressed, the wedge 136 of the switches 130 and 140 moves inside the casings 100, 110 and 120 along the inclined portions 159 of the connector 150. When it is pushed against the wedge 136 of the switches 130 and 140, the connector 150 and the gripper 160 and the cap 170 bound thereto are linearly moved to the distal side. In addition, the connector 150 is coupled to the switches 130 and 140 by fitting the locking jaw 132 of the switch to the switch binding portion 158 of the connector 150, so that the connector 150 is bound to the cases 100, 110 and 120. The relative rotation of the gripper 160 and the cap 170 is limited.

Accordingly, by pressing and holding the switches 130 and 140 while holding the cap 170 while rotating the connector 150, the gripper 160, and the rotation of the cap 170, the small diameter portions of the cap 170 and the connector 150 are rotated. The screw 170 of 156 is released so that the cap 170 can be removed. When the cap 170 is detached, the binding of the guide wire 10 by the gripper 160 is also released, and the guide wire 10 can be pulled out to be intruded or replaced again.

On the other hand, when the switches 130 and 140 are no longer pressed, the wedge 136 of the switches 130 and 140 no longer pushes the tip of the connector 150 to the distal side as the support 130 of the switch is returned by the elastic force. Accordingly, the connector 150, the gripper 160, and the cap 170 bound to the connector 150 may be linearly moved to the position and returned by the elastic force of the spring 180. In addition, the locking jaw 132 of the switch is detached from the switch binding part 158 of the connector 150, so that the free rotation of the connector 150, the gripper 160, and the cap 170 becomes possible, and the guide wire 10 is connected. Can be rotated.

The guide wire handler for measuring blood vessel pressure using the optical pressure sensor according to the present invention described above, when the guide wire 10 enters into the blood vessel, the guide wire 10 is connected to the blood vessel without rotating the handler. It provides the advantage that the entry is smooth because the entry resistance is freely rotated in the direction of decreasing contact.

10; Guide wire 20; Optical connection terminal
100; Body 110; Tip cover
120; End cover 130; Switch support
140; Switch fixture 150; connector
160; Gripper 170; cap
180; Spring 190; bearing

Claims (4)

A case in which an optical connection terminal is inserted through the front end, a guide wire equipped with an optical pressure sensor is inserted through the end to be connected to the optical connection terminal, and a switch hole is formed on one side;
It is installed so as to be rotatable inside the case, the guide wire is penetrated therein, and a cap coupling portion is provided on an outer surface of a portion protruding through the end of the case at the end, and other corresponding to the switch hole of the case A connector provided with a switch binding portion on one side surface;
A gripper through which the guide wire is penetrated, a front end side is inserted into the connector through the end of the connector, and a forceps part is elastically retracted to the end to bind the guide wire;
A cap that is detachably coupled to the cap coupling portion of the connector, the guide wire is penetrated, and a gripping portion of the gripper is inserted therein to form a binding portion;
Vascular pressure using an optical pressure sensor, characterized in that it includes a switch installed on the switch hole side of the case and engaged with the switch engagement portion of the connector so as to limit the free rotation of the connector and the gripper and the cap bound thereto. Guide wire handler for measurement. According to claim 1,
The switch engagement portion of the connector is in the form of a ring gear,
A guide wire handler for measuring blood vessel pressure using an optical pressure sensor, characterized in that a locking jaw that can be fitted into any one of the gaps between the teeth of the ring gear and the teeth of the ring gear is formed on the inner surface of the switch by pressing the switch. . According to claim 1,
On the inner surface of the switch, a wedge toward the inside of the case is protruded by pressing the switch.
The connector has an inclined portion in which the wedge of the switch is in close contact so as to be linearly moved to the distal side by the wedge of the switch,
A guide for measuring blood vessel pressure using an optical pressure sensor, characterized in that an elastic member is provided between the connector and the case to provide an elastic force to return the connector linearly moved by the switch wedge when the switch is depressed. Wire handler. According to claim 1,
An optical pressure sensor characterized in that a connecting pin connected to the guide wire side is protruded at an end of the optical connection terminal, and a sleeve connecting a connection with the guide wire is selectively detachably attached to the connecting pin. Guide wire handler for blood vessel pressure measurement using a.

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