CN216754729U - Trans-femoral valve repair transporter delivery system - Google Patents

Abstract

The utility model belongs to the technical field of medical instruments, and particularly relates to a conveyor. A delivery system for a transfemoral valve repair transporter, comprising: the adjustable bending structure is provided with an adjustable bending pipe with adjustable bending degree; the delivery structure is provided with a delivery pipe which penetrates through the adjustable bent pipe, is detachably connected with the transfemoral valve restorer and is used for delivering the transfemoral valve restorer to a target position; and the release structure is detachably connected with the transfemoral valve restorer and can control the connection or the separation of the conveying structure and the transfemoral valve restorer. When the device is matched with a transfemoral valve restorer for use, the transfemoral valve restorer can be conveniently conveyed to a target position through the adjustable bending structure, multiple clamping of valve leaflets can be better realized through the conveying structure, and when the valve leaflets are captured improperly, the transfemoral valve restorer can be used for releasing the clamping sheets so as to realize recapturing of the valve leaflets.

Description

Trans-femoral valve repair transporter delivery system

Technical Field

The utility model belongs to the technical field of medical instruments, and particularly relates to a conveying system.

Background

The mitral valve is located between the left atrium and the left ventricle, and acts as a one-way valve to ensure blood flow from the left atrium to the left ventricle. When the normal mitral valve is closed, the two valve leaflets are in the same plane and closely involuted, and ventricular blood can be completely prevented from flowing back to the atrium. However, when the mitral valve complex structure is damaged or the heart is damaged, mitral regurgitation is caused.

At present, the mode of treating mitral regurgitation through operations mainly comprises two types of surgical open chest operations and medical minimally invasive operations. The surgical thoracotomy operation causes a large amount of patients to be reluctant to accept the treatment mode due to large operation trauma, high risk and long-term and expensive postoperative rehabilitation treatment, and the internal minimally invasive operation of the femoral artery transcatheter aortic valve treatment provides a novel treatment method which has smaller trauma, less complications and fast postoperative rehabilitation for doctors.

In the process of valve treatment, a transfemoral valve prosthesis is needed to be adopted, the transfemoral valve prosthesis clamps valve leaflets through a clamping structure of the transfemoral valve prosthesis, and a conveyor matched with the transfemoral valve prosthesis is needed to convey, control the form and release the transfemoral valve prosthesis, but the existing conveyor is usually complex in structure, so that the probability of misoperation of a doctor is increased. Some conveying devices are long in structure, and doctors need to stand at a higher position during operation, so that the operation is inconvenient.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that the conveyor matched with a transfemoral valve repair device is inconvenient to operate due to complex or long structure, and aims to provide a conveying system of the conveyor for transfemoral valve repair.

A delivery system for a transfemoral valve repair transporter, comprising:

a delivery structure having a delivery tube removably connected to the clip of the transfemoral valve prosthesis for delivering the transfemoral valve prosthesis to a target site;

and the release structure is provided with a middle core rod, the distal end of the middle core rod penetrates through the delivery pipe and then is detachably connected with the transfemoral valve prosthesis, and the connection or the separation of the delivery structure and the transfemoral valve prosthesis can be controlled.

The delivery structure includes a delivery handle, the delivery handle including:

the far end of the conveying shell is connected with the near end of the conveying pipe;

the pulling wire control assembly can slide on the conveying shell along the axial direction of the conveying pipe and is connected with the clamping piece of the transfemoral valve prosthesis, and the pulling wire control assembly controls the clamping piece to be opened and closed when sliding along the axial direction;

the number of the pull line control components is the same as that of the clamping pieces.

The pull wire control assembly comprises:

the pull wire control end can slide on the conveying shell along the axial direction of the conveying pipe;

the conveying pull wire extends along the axial direction of the conveying pipe and is detachably connected with the clamping piece of the transfemoral valve restorer;

and the stay wire locking end is arranged on the stay wire control end and locks the two ends of the conveying stay wire on the stay wire control end.

The pull line control assembly further comprises:

the axial clamping piece is arranged on the conveying shell and is detachably clamped and connected with the stay wire control end;

when the axial clamping piece is clamped and connected with the stay wire control end, the length of the conveying stay wire is locked, and when the conveying stay wire needs to be pulled or conveyed, the stay wire control end is separated from the axial clamping piece, and the stay wire control end is axially slid to pull or convey the conveying stay wire.

The conveying shell is internally provided with a guide piece, the guide piece is in sliding connection with the stay wire control end, and the guide piece guides the stay wire control end to slide along the axial direction of the conveying pipe.

The proximal end of the middle core rod is provided with a release control end, and the middle core rod is connected with or separated from the transfemoral valve prosthesis through the release control end.

The connection mode of the central core rod and the transfemoral valve prosthesis is one of threaded connection or clamping connection.

The release structure further comprises a prosthesis control assembly for controlling the operational state of the transfemoral valve prosthesis;

the prosthetic control assembly includes:

the proximal end and the distal end of the rotating sleeve are of an open structure, the rotating sleeve is hollow inside and is connected to the conveying shell;

the spiral pipe is provided with an open structure at the near end and the far end, the interior of the spiral pipe is hollow, at least part of the spiral pipe is positioned in the rotary sleeve, the near end extends out of the rotary sleeve, and the outer wall of the spiral pipe is provided with external threads;

the central core rod fixing piece is detachably connected with the central core rod and detachably connected with the near end of the spiral tube;

one end of the pushing nut is in threaded connection with the external thread of the spiral pipe, and the other end of the pushing nut can move along the circumferential direction of the rotary sleeve;

the far end of the middle core rod sequentially penetrates through the middle core rod fixing piece, the spiral pipe and the conveying pipe and then is connected with the transfemoral valve repair device, when the push nut is rotated, the spiral pipe axially extends out or extends into the rotary sleeve to drive the middle core rod fixing piece, and then the middle core rod is driven to push or pull back to the far end so as to control the working state of the transfemoral valve repair device.

A pin clamping groove is formed in the outer wall of the rotary sleeve along the circumferential direction;

be provided with the internal thread on the near-end inner wall of propulsion nut, through the internal thread with the external screw thread threaded connection of spiral pipe, the distal end of propulsion nut is equipped with the pin mounting hole along radially digging, the propulsion nut passes through one in proper order through the propulsion pin the pin mounting hole with the pin draw-in groove with the rotating sleeve connects, in order to realize the propulsion nut can be followed rotating sleeve's circumferential motion.

A sleeve flange is arranged on the outer wall of the near end of the rotating sleeve;

be provided with the internal thread on the near-end inner wall of propulsion nut, through the internal thread with the external screw thread threaded connection of spiral pipe, the distal end of propulsion nut is provided with the nut throat, the propulsion nut passes through the nut throat cover is established outside the sleeve pipe flange with the rotating sleeve connects, in order to realize the propulsion nut can be followed rotating sleeve's circumferential motion.

The positive progress effects of the utility model are as follows: the utility model adopts the conveying system of the conveyor for repairing the femoral valve, and has the following advantages:

1. multiple clamping of the valve leaflets can be well realized through the conveying system, and when the valve leaflets are captured in improper positions, the clamping sheets can be released through the femoral valve repair device again to realize recapture of the valve leaflets;

2. all parts are organically combined, and the operation can be finished by one person, so that the operation is simple and convenient.

Drawings

FIG. 1 is a schematic view of an overall structure of the present invention;

FIG. 2 is a schematic view of one configuration of the delivery and release structures of the present invention;

FIG. 3 is an exploded view of FIG. 2;

FIG. 4 is a schematic view of a pull line control assembly of the present invention;

FIG. 5 is a schematic diagram of a prosthetic control assembly according to the present invention;

FIG. 6 is an internal cross-sectional view of FIG. 5;

FIG. 7 is a schematic view of another construction of the prosthetic control assembly of the present invention;

FIG. 8 is an internal cross-sectional view of FIG. 7;

FIG. 9 is a schematic view of a portion of the bend adjustment handle of the present invention;

FIG. 10 is a schematic view of a bend adjustment guide of the present invention;

FIG. 11 is a schematic diagram of one embodiment of the loader configuration of the present invention;

FIG. 12 is an exploded view of FIG. 11;

FIG. 13(a) is a schematic view of a construction of the gasket seal of FIG. 12;

FIG. 13(b) is another side schematic view of FIG. 13 (a);

FIG. 14 is a structural cross-sectional view of a seal end structure of the present invention;

FIG. 15(a) is a schematic view of a construction of the closure nut of FIG. 14;

FIG. 15(b) is a cross-sectional view of FIG. 15 (a);

FIG. 16(a) is a schematic view of a gasket seal of FIG. 14;

FIG. 16(b) is a cross-sectional view of FIG. 16 (a);

FIG. 17 is a schematic view of an alternative embodiment of the cartridge of the present invention;

fig. 18 is a schematic view of the seal end structure of fig. 17.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the utility model easy to understand, the utility model is further described with the specific drawings.

Referring to fig. 1-18, a delivery system for a transfemoral valve repair transporter may be used as part of a transfemoral valve repair transporter for delivery and control of the transfemoral valve prosthesis. A delivery apparatus for a transfemoral valve repair may comprise, in order from a proximal end to a distal end, a delivery structure 100 of the present invention, a delivery structure 200 of the present invention, an adjustable bending structure 300, a loader structure 400, and an outer sheath structure 500.

Referring to fig. 1-3, a delivery structure 200 is removably attachable to a transfemoral valve prosthesis, the delivery structure 200 being for delivering the transfemoral valve prosthesis to a target site. The delivery structure 200 includes a delivery tube 210 and a delivery handle 220. The delivery tube 210 may pass through and extend out of the adjustable elbow 310. Delivery handle 220 includes a delivery housing 221 and a pull-cord control assembly. The distal end of the delivery housing 221 is connected to the proximal end of the delivery tube 210, and a delivery end 2211 is removably disposed at the distal end of the delivery housing 221. The pulling-wire control assembly can slide on the conveying shell 221 along the axial direction of the conveying pipe 210, the pulling-wire control assembly is connected with the clamping pieces of the transfemoral valve prosthesis, the pulling-wire control assembly controls the opening and closing of the clamping pieces when sliding along the axial direction, and the number of the pulling-wire control assemblies is the same as that of the clamping pieces, so that one group of the pulling-wire control assemblies can control the opening and closing of one clamping piece.

Referring to fig. 4, the wire control assembly includes a wire control end 222, a delivery wire, a wire locking end 223, and an axial catch 224.

The wire control end 222 is slidable on the delivery housing 221 in the axial direction of the delivery tube 210. The pulling wire control end 222 is detachably engaged with the axial engaging member 224, the axial engaging member 224 is disposed on the conveying casing 221, when the axial engaging member 224 is engaged with the pulling wire control end 222, the length of the conveying pulling wire is locked, and when the conveying pulling wire needs to be pulled or conveyed, the pulling wire control end 222 is separated from the axial engaging member 224, and the pulling wire control end is axially slid to pull or convey the conveying pulling wire. When the wire control end 222 is engaged with the axial engaging member 224, the wire control end 222 is provided with a rotatable engaging head, the wire control end 222 is axially slid to the side of the axial engaging member 224, the engaging head is rotated and the wire control end 222 is continuously slid, and when the engaging head is located above the axial engaging member 224, the engaging head is released and engaged with the axial engaging member 224. Preferably, a guide 225 is disposed in the delivery housing 221, the guide 225 is slidably connected to the pull wire control end 222, and the guide 225 guides the pull wire control end 222 to slide along the axial direction of the delivery tube 210.

The delivery pull-wires extend axially of the delivery tube 210 and are removably attached to the clip of the transfemoral valve prosthesis. The pull wire locking end 223 is arranged on the pull wire control end 222, the pull wire locking end 223 slides along the axial direction of the conveying pipe 210 along with the pull wire control end 222, and the pull wire locking end 223 locks the two ends of the conveying pull wire on the pull wire control end 222. When the conveying stay wire is used, one end of the conveying stay wire is locked on the stay wire locking end 223, the other end of the conveying stay wire extends to the femoral valve restorer along the inside of the conveying pipe 210, can be detachably connected with a clamping piece of the femoral valve restorer, extends back to the stay wire locking end 223 and is locked by the stay wire locking end 223, and therefore the conveying stay wire forms a U-shaped structure. When the conveying stay wire is connected with the clamping piece of the transfemoral valve restorer, the stay wire through hole is arranged on the clamping piece of the transfemoral valve restorer, and the conveying stay wire bypasses the stay wire through hole to realize the detachable connection with the clamping piece of the transfemoral valve restorer. When it is desired to separate the delivery construct 200 from the transfemoral valve prosthesis, the locked delivery pull-wire is released and one end of the delivery pull-wire is continuously pulled until the entire pull-wire is pulled out.

Referring to fig. 1-3, the release structure 100 is removably attachable to a transfemoral valve prosthesis, the release structure 100 controlling attachment or detachment of the delivery structure 200 to the transfemoral valve prosthesis. The release structure 100 includes a mandrel 110, a release control end 120, and a prosthesis control assembly.

The distal end of the central core rod 110 passes through the delivery pipe 210 and then is detachably connected with the transfemoral valve prosthesis, and the connection mode of the central core rod 110 and the transfemoral valve prosthesis is one of threaded connection or clamping connection. The proximal end of the central core rod 110 is provided with a release control end 120, and the central core rod 110 is connected with or separated from the transfemoral valve prosthesis through the release control end 120. Preferably, the release control end 120 may be a release knob fixed to the proximal end of the central core rod 110, and the central core rod 110 is rotated by rotating the release knob to detachably connect or disconnect the femoral valve prosthesis.

Referring to fig. 5 to 8, the prosthetic device control assembly is configured to control the working states of the transfemoral valve prosthetic device, the working states of the transfemoral valve prosthetic device mainly include an open state, an umbrella-opening state and a closed state, the various states are realized by pushing or pulling back the transfemoral valve prosthetic device by the central core rod 110, and the prosthetic device control assembly can realize pushing or pulling back of the central core rod 110. The prosthesis control assembly includes a rotating sleeve 131, a coil 132, a central mandrel holder 133, and a push nut 134.

The proximal and distal ends of the rotating sleeve 131 are open, the rotating sleeve 131 is hollow, and the rotating sleeve 131 is attached to the delivery housing 221. When the delivery housing 221 is provided with the rotating sleeve 131, it is preferable that a plurality of auxiliary guide members, such as the first guide member 1311, the second guide member 1312, and the third guide member 1313 of fig. 4, are provided on the rotating sleeve 131, and the wire control assembly may be provided on the rotating sleeve 131, and guided by the auxiliary guide members to move in the axial direction.

The proximal end and the distal end of the spiral tube 132 are open structures, the spiral tube 132 is hollow, at least a portion of the spiral tube 132 is located inside the rotary sleeve 131, external threads are arranged on the outer wall of the spiral tube 132, the proximal end of the spiral tube 132 extends out of the rotary sleeve 131 and is detachably connected with the central core rod fixing element 133, and the spiral tube 132 and the rotary sleeve 131 can be connected in a threaded mode. The center core rod holder 133 is also detachably coupled to the center core rod 110. One end of the push nut 134 is threadedly coupled to the external thread of the spiral pipe 132, and the other end of the push nut 134 is movable in the circumferential direction of the rotary sleeve 131. The distal end of the middle core rod 110 sequentially passes through the middle core rod fixing piece 133, the spiral tube 132 and the delivery pipe 210 and then is connected with the transfemoral valve prosthesis, when the pushing nut 134 is rotated, the spiral tube 132 can axially extend out or extend into the rotary sleeve 131 to drive the middle core rod fixing piece 133 because the rotary sleeve 131 is not moved, and further drive the middle core rod 110 to push or pull back towards the distal end so as to control the working state of the transfemoral valve prosthesis.

Referring to fig. 5 and 6, a pin catching groove 1314 is circumferentially provided on an outer wall of the rotary sleeve 131. The inner wall of the proximal end of the pushing nut 134 is provided with an internal thread, the pushing nut 134 is in threaded connection with the external thread of the spiral tube 132 through the internal thread, the distal end of the pushing nut 134 is radially dug with a pin mounting hole 1341, the pushing nut 134 sequentially passes through the pin mounting hole 1341 and the pin clamping groove 1314 through a pushing pin to be connected with the rotating sleeve 131, and therefore the pushing nut 134 can move along the circumferential direction of the rotating sleeve 131.

Referring to fig. 7 and 8, a sleeve flange 1315 is provided on the proximal outer wall of the rotating sleeve 131. The inner wall of the proximal end of the pushing nut 134 is provided with an internal thread, the pushing nut 134 is in threaded connection with the external thread of the spiral tube 132 through the internal thread, the distal end of the pushing nut 134 is provided with a nut throat, and the pushing nut 134 is sleeved outside the sleeve flange 1315 through the nut throat and is connected with the rotating sleeve 131, so that the pushing nut 134 can move along the circumferential direction of the rotating sleeve 131.

Referring to fig. 1, 9 and 10, the adjustable bending structure 300 includes an adjustable bending tube 310 and a bending handle 320. The adjustable elbow 310 may be curved, the adjustable elbow 310 may be traversed by the delivery tube 210, and the delivery tube 210 within the adjustable elbow 310 curves with the central core within the delivery tube 210 as the adjustable elbow is bent. The bend adjustment handle 320 is in communication with the adjustable elbow 310, and the bend adjustment handle 320 controls the degree of bending of the adjustable elbow 310. The bending adjusting handle 320 comprises a bending adjusting threaded pipe 321, a bending adjusting guide 322 and at least one bending adjusting pull wire.

The near-end and the distal end of transferring curved screwed pipe 321 are for opening the structure, transfer the inside cavity of curved screwed pipe 321, and the inner wall of transferring curved screwed pipe 321 is provided with the screwed pipe internal thread that can drive and transfer curved stay wire, and the one end outer wall cover of transferring curved screwed pipe 321 is equipped with transfers curved knob 3211, rotates and transfers curved knob 3211, and transfer curved screwed pipe 321 then rotates.

The bending adjustment guide member 322 has a bending adjustment guide rod 3221 and a pulling wire fixing ring 3222 arranged in the bending adjustment threaded tube 321, a distal end of the bending adjustment guide rod 3221 is of an open structure and is hollow inside, the pulling wire fixing ring 3222 is sleeved outside the bending adjustment guide rod 3221 and can axially move along the bending adjustment guide rod 3221, the bending adjustment guide rod 3221 is further provided with a limiting part 3223, the limiting part 3223 is a limiting ring or a limiting plate, and the limiting part 3223 is arranged at two ends of the pulling wire fixing ring 3222 to limit an axial moving distance of the pulling wire fixing ring 3222. The stay wire fixing ring 3222 is provided with a fixing ring external thread, the fixing ring external thread is in threaded connection with the threaded pipe internal thread, and the stay wire fixing ring 3222 is provided with a stay wire fixing end 3224. One end of the bending-adjusting pull wire is connected with the adjustable bent pipe 310, and the other end of the bending-adjusting pull wire passes through the adjustable bent pipe 310, the bending-adjusting threaded pipe 321 and the bending-adjusting guide rod 3221 in sequence and then is connected with the pull wire fixing end 3224. A wire hole 3225 may be provided on the bending adjustment guide rod 3221 to extend the bending adjustment wire from the bending adjustment guide rod 3221.

When the bending adjustment knob 3211 is rotated to rotate the bending adjustment threaded pipe 321, the pulling wire fixing ring 3222 moves axially along the bending adjustment guide rod 3221, and drives the bending adjustment pulling wire at the pulling wire fixing end 3224 to move, so as to adjust the bending degree of the adjustable bent pipe 310. Preferably, a fixing ring guide groove or a fixing ring guide strip 3226 is axially disposed on the bending guide rod 3221, and a corresponding fixing ring guide strip or fixing ring guide groove is disposed on an inner wall of the pull wire fixing ring 3222, so that the pull wire fixing ring 3222 is more stable when axially moving along the bending guide rod 3221.

Bend adjustment handle 320 also includes bend adjustment housing 323 and bend adjustment indicator 324. The bending adjusting shell 323 can contain a bending adjusting threaded pipe 321, the bending adjusting threaded pipe 321 is limited in the bending adjusting shell 323, the bending adjusting knob 3211 extends out of the near end or the far end of the bending adjusting shell 323, and the far end of the bending adjusting shell 323 is detachably provided with a bending adjusting sealing end 3231. The side wall of the outer peripheral surface of the bend adjusting shell 323 is provided with a shell through hole and a bending form indicator, the bending form indicator is axially arranged on the side of the shell through hole, and the bending form indicator can indicate the bending degree of the adjustable bent pipe 310. Bend adjusting indicator 324 has the instruction end towards crooked form indicator, is provided with the screwed pipe external screw thread on the outer wall of bend adjusting screwed pipe 321, and bend adjusting indicator 324 and screwed pipe external screw thread threaded connection, when bend adjusting indicator 324 can be driven down along the casing through-hole and slide at bend adjusting screwed pipe 321, crooked form indicator is instructed to the instruction end to instruct the crookedness of adjustable return bend 310.

Referring to fig. 1 and 11, the loader structure 400 includes a loading chamber 410, a loading head 420, and a seal end structure 430. The proximal and distal ends of loading lumen 410 are open structures, loading lumen 410 is hollow, and loading lumen 410 can accommodate a transfemoral valve prosthesis and adjustable elbow 310, both of which can exit loading lumen 410. The loading chamber 410 is made of one or more of PEBAX, PTFE, polymer material, stainless steel, and the like. The distal end of the loading chamber 410 is preferably fitted with a visualization ring, both of which are fixed by one or more of PEBAX, PTFE, polymer materials, stainless steel, or a combination thereof. The developing ring can be formed by mixing any one or more of nickel-titanium wires, platinum-iridium wires and platinum-tungsten wires.

Loading head 420 is in communication with the proximal end of loading chamber 410, and the proximal end of loading head 420 has a loading connection 421. The sealing end structure 430 is detachably connected to the loading connection portion 421, and the connection manner of the sealing end structure and the loading connection portion may be a threaded connection or a snap connection. The sealing end structure 430 may allow the adjustable elbow 310 to pass through and sealingly connect with the adjustable elbow 310.

Referring to fig. 12-18, the sealing end structure 430 includes a gland nut 431 and a sealing gasket 432. The end face of the proximal end of the sealing nut 431 is provided with a nut through hole 4311 which is communicated with the inside and the outside, the sealing nut 431 is detachably connected with the loading connecting part 421 and encloses a sealing gasket accommodating cavity with a nut through hole 4311 at one end, and the nut through hole 4311 can be penetrated by the adjustable bent pipe 310. A sealing gasket 432 is disposed within the sealing gasket receiving cavity, the sealing gasket 432 being adapted to be penetrated by and sealingly coupled to the adjustable elbow 310.

In the present invention, the sealing nut 431 and the sealing gasket 432 of the sealing end structure 430 may be implemented by various structures, for example:

referring to fig. 12 to 13(b), the sealing gasket 432 is an elastic variable diameter tube body with a contracted middle portion and two expanded ends, the sealing gasket 432 sequentially includes a first expanding portion 4321, a contracted portion 4322 and a second expanding portion 4323 from a proximal end to a distal end, the proximal end of the first expanding portion 4321 abuts against the proximal end surface of the sealing nut 431, and the outer wall of the second expanding portion 4323 is attached to the inner wall of the loading connection portion 421. The first expanding portion 4321 is further sleeved with a groove ring 4324, and the outer wall of the groove ring 4324 is attached to the circumferential inner wall of the proximal end of the seal nut 431. The groove ring 4324 employs a sealing ring body, and a proximal end of the sealing ring body is connected to a circumferential outer wall of the first expanded portion 4321, so that a buffer groove is formed between a distal end of the sealing ring body and the circumferential direction of the first expanded portion 4321.

Referring to fig. 14 to 16(b), a sealing gasket mounting groove 4312 is dug on the proximal end surface of the gland nut 431, and the sealing gasket mounting groove 4312 is located outside the nut through hole 4311. Gasket seal 432 includes a seal elastomer 4325 and a seal engagement end 4326. The sealing elastomer 4325 is a disc-shaped structure protruding from the middle to the distal end, and the middle part of the sealing elastomer 4325 has an elastomer through hole 4327 that can be penetrated by the adjustable bent tube 310. The sealing elastomer 4325 is designed to be a disc-shaped structure protruding from the middle, so that the contact area between the sealing elastomer 4325 and the adjustable elbow 310 can be increased, and the sealing performance can be improved. In order to avoid the negative effects that the sealing elastic body 4325 is bonded to the surface of the adjustable bent pipe 310 due to too good sealing performance when the adjustable bent pipe 310 passes through the sealing elastic body 4325, so that the conveying resistance is increased and even the conveying fails, the utility model provides a plurality of anti-adhesion devices 4328 on the outer wall of the sealing elastic body 4325, wherein the anti-adhesion devices 4328 are convex pieces or concave groove pieces, so as to reduce the adsorption resistance between the sealing gasket 432 and the outer wall of the adjustable bent pipe 310. The anti-adhesion device 4328 may be designed as one or a combination of a plurality of spherical or hemispherical protrusions, triangular pyramid protrusions, or square protrusions, or as one or a combination of a plurality of spherical or hemispherical grooves, triangular pyramid grooves, or square grooves. The distance between the anti-adhesion means 4328 and the elastomer through hole 4327 is not less than 1mm to 5mm, preferably not less than 1.5mm to 3 mm. That is, the adhesion prevention means 4328 is not provided near the outer periphery of the elastomer through hole 4327 to ensure sufficient sealability when the adjustable elbow 310 passes through the elastomer through hole 4327.

The distal end of the seal engaging end 4326 is connected to the outer edge of the proximal end of the seal elastic body 4325, and the proximal end of the seal engaging end 4326 is engaged in the seal gasket mounting groove 4312. The seal engaging end 4326 preferably includes a first ring member and a second ring member, wherein the inner side of the first ring member is connected to the outer edge of the proximal end of the seal elastic body 4325, the distal end of the second ring member is vertically connected to the outer side of the first ring member, and the proximal end of the second ring member is engaged in the seal gasket mounting groove 4312. A compressing end is arranged on the inner wall of the loading head 420, and the compressing end is of a hollow cylinder structure. When the sealing nut 431 is connected to the loading connection portion 421, the pressing end presses against the sidewall of the first annular member to press the second annular member into the gasket mounting groove 4312. The design of the gasket mounting groove 4312 can prevent the sealing elastomer 4325 from falling off from the seal head nut 431 to cause sealing failure due to too large thrust when the adjustable bent pipe 310 passes through the sealing elastomer 4325. And the inner side wall of the sealing gasket mounting groove 4312 can be used for applying pressure to the second annular part of the sealing elastic body 4325 to prevent the outer edge of the sealing elastic body 4325 from tilting.

Referring to fig. 17 and 18, sealing gasket 432 may also be implemented as a resilient tube 4331, the distal end of resilient tube 4331 abutting against loading connection 421 via gasket 4332 and communicating with loading head 420. The two ends of the elastic tube 4331 are open, the outer surface of the elastic tube 4331 is concave along the axial direction, and the elastic tube 4331 is made of rubber and is pressed by the pressing tube 4333 to seal the adjustable bent tube 310.

The gland nut 431 may adopt a pressing tube 4333, and a distal end of an inner half portion of the pressing tube 4333 abuts against a proximal end of the elastic tube 4331 by another gasket 4332 and is communicated with the elastic tube 4331, so as to reduce abrasion of the loading connection portion 421 and the pressing tube 4333 to two ends of the elastic tube 4331 in the rotating and pressing process. The far end of the outer half of the pressing tube 4333 is movably locked to the loading connection portion 421, and the outer portion of the pressing tube 4333 is locked to the loading connection portion 421 so as to press the elastic tube 4331 to deform and further press the adjustable bent tube 310 to seal the adjustable bent tube 310.

Specifically, the pressing tube 4333 has an inner transition tube 4334 and an outer pressing tube 4335, and the outer half of the pressing tube 4333, i.e. the outer pressing tube 4335, is sleeved outside the inner transition tube 4334 and fixedly connected to the inner transition tube 4334, and movably locked outside the proximal end of the loading connection portion 421. The transition inner tube 4334 does not extend beyond the distal end of the extruded outer tube 4335 to facilitate the passage of other components into and/or out of the extruded tube 4333. The extruded tube 4333 has a connection ring, a transition inner tube 4334 is connected inside the connection ring, and an extruded outer tube 4335 is connected outside the connection ring. The transition inner tube 4334, the connection ring and the extrusion outer tube 4335 are integrally formed. The extrusion tube 4333 is formed by combining one or more of PP, silica gel and high polymer materials, and can achieve a completely sealed sealing effect by rotating the extrusion tube 4333 and the elastic tube 4331 inside the extrusion tube 4333, thereby simplifying the product design.

The inner surface of the pressing outer tube 4335 has at least one internal thread, such as two internal threads 4335a, 4335b, and the corresponding position outside the proximal end of the loading connection portion 421 has at least one external thread, such as two external threads 421a, 421b, and the internal thread of the pressing outer tube 4335 presses the outer tube 4335a to be screwed on the external thread 421a of the loading connection portion 421, and the internal thread 4335b of the pressing outer tube 4335 is screwed on the external thread 421b of the loading connection portion 421, so that the pressing elastic tube 4331 is deformed to form an end seal. The proximal outer portion of loading connection 421 is latched by squeeze tube 4335 such that squeeze tube 4331 deforms, thereby further sealing the proximal end of loading connection 421 and indirectly sealing adjustable elbow 310 with the distal end of squeeze tube 4331.

Referring to FIG. 1, an outer sheath tube structure 500 is used to provide a channel for an adjustable bending structure 300 and a delivery structure 200; the outer sheath tube structure 500 includes an outer sheath tube 510 and a sheath handle 520. The outer sheath 510 serves as an access passage for the adjustable elbow 310 of the adjustable elbow structure 300, and the outer sheath 510 can be bent. The sheath handle 520 is in communication with the outer sheath 510, the sheath handle 520 controlling the curvature of the outer sheath 510. The sheath handle 520 has the same structure as the bending handle 320, and will not be described in detail.

The conveyor for the transfemoral valve repair is matched with the transfemoral valve repair device for use, when in use, the conveying pull wire of the conveying structure 200 is detachably connected with the clamping piece of the transfemoral valve repair device, and the central core rod 110 of the release structure 100 is detachably connected with the transfemoral valve repair device.

When the device is used for repairing valves, a hole with the diameter of 4-5mm is firstly opened on the right femoral vein, a guide wire is penetrated along the opening, the interatrial septum is punctured, each emptying pipe of the conveyor is connected with a high-pressure extension pipe, and the high-pressure extension pipe is exhausted by high-pressure flowing normal saline. The dilator is sleeved into the sheath tube 510, enters the blood vessel along the guide wire and reaches the interatrial septum through the right atrium, the dilator is used for reaming the interatrial septum, the dilator drives the sheath tube 510 to penetrate the interatrial septum to enter the left atrium, and the guide wire and the dilator are withdrawn. The dilator and guidewire are then withdrawn while the blood pressure is being withdrawn from the tee on the sheath handle 520 to prevent gas from entering the body. Clockwise turning sheath pipe handle 520's handle knob can control outer sheath pipe 510 head end accuse curved, and anticlockwise turning handle knob can reduce outer sheath pipe 510 head end crookedness. The adjustable bending structure 300, delivery structure 200, and release structure 100 are delivered while the distal end of the outer sheath 510 is positioned in the middle of the mitral valve leaflets.

The adjustable bending structure 300, the delivery structure 200 and the release structure 100 are inserted into the sheath 510, and then slowly enter the left atrium through the right atrium and the interatrial septum in sequence, and when the transfemoral prosthetic device is fully extended out of the distal end of the sheath 510, the pushing nut 134 is rotated clockwise to adjust the shape of the transfemoral prosthetic device to the fully closed state.

According to the bending form indicators on the bending adjusting handle 320 and the sheath handle 520, the bending angle of the adjustable bent tube 310 is not larger than 45 ° of the outer sheath 510. When the bending adjusting handle 320 and the bending adjusting indicator of the sheath tube handle 520 are simultaneously bent to the bottom, the head end of the whole bending adjusting structure 300 is bent by 180 degrees. The pushing nut 134 on the bending adjusting handle 320 is rotated anticlockwise, the shape of the transfemoral valve restorer is adjusted to be in an umbrella-opening state under the observation of X-rays, the pulling wire control end 222 on the conveying structure 200 is respectively slid, the conveying pulling wire is pulled back, and the two clamping pieces of the transfemoral valve restorer are opened. The bend adjustment handle 320 is pushed, and the adjustable bend 310 and the transfemoral valve prosthesis are delivered into the left ventricle across the valve during ventricular diastole, ready to capture the valve. The slow retraction bend-adjusting structure 300, the delivery structure 200 and the release structure 100, when the anterior and posterior mitral valve are all attached to the two side clamp arms of the transfemoral valve prosthesis, the two side pull wire control ends 222 are rapidly put down, the delivery pull wire is pushed, and the two mitral valve leaflets are captured at the same time. If the anterior valve needs to be recaptured, the clip corresponding to the posterior valve can be kept down, the clip corresponding to the anterior valve can be pulled up, the sheath handle 520 can be integrally rotated slightly counterclockwise, and the anterior valve can be attempted to be recaptured. After confirming secure capture of the two leaflets, the transfemoral prosthetic is adjusted to the fully closed state by rotating the push nut 134 clockwise.

The ultrasonic observation is carried out to see whether the femoral valve prosthesis is well fixed and fully captured or not and whether the mitral regurgitation is reduced or not. If the effect is satisfactory, the valve is ready to be released. Luer connectors on two sides of the bending adjusting handle 320 are respectively unlocked, the pull wire locking end 223 is loosened, and one end of the conveying pull wire is pulled to be completely pulled out. After the conveying pull wires are all drawn out, the luer connector is locked, and the bending adjusting knob 3211 of the bending adjusting handle 320 is screwed down counterclockwise. The release knob may now be rotated counterclockwise, completing the release of the transfemoral valve prosthesis when the central core rod 110 may be withdrawn.

The foregoing shows and describes the general principles, essential features, and advantages of the utility model. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (10)

1. A delivery system for a transfemoral delivery device for prosthetic valves, comprising:

the conveying structure is provided with a conveying pipe and is detachably connected with the clamping piece of the transfemoral valve restorer;

and the release structure is provided with a central core rod, and the distal end of the central core rod passes through the delivery pipe and then is detachably connected with the transfemoral valve prosthesis.

2. The delivery system of a trans-femoral valve repair transporter of claim 1, wherein the delivery structure comprises a delivery handle comprising:

the far end of the conveying shell is connected with the near end of the conveying pipe;

and the pull wire control assembly can slide on the conveying shell along the axial direction of the conveying pipe and is connected with the clamping piece of the transfemoral valve prosthesis, and the pull wire control assembly controls the clamping piece to open and close when sliding along the axial direction.

3. The delivery system of a transfemoral valve repair transporter of claim 2, wherein the number of pull line control assemblies is the same as the number of clips.

4. The delivery system of a transfemoral valve repair transporter of claim 2, wherein the pull line control assembly comprises:

the pull wire control end can slide on the conveying shell along the axial direction of the conveying pipe;

the conveying pull wire extends along the axial direction of the conveying pipe and is detachably connected with the clamping piece of the transfemoral valve restorer;

and the stay wire locking end is arranged on the stay wire control end and locks the two ends of the conveying stay wire on the stay wire control end.

5. The delivery system of a transfemoral valve repair transporter of claim 4, wherein the pull line control assembly further comprises:

and the axial clamping piece is arranged on the conveying shell and is detachably clamped and connected with the stay wire control end.

6. The delivery system of a trans-femoral valve repair transporter of claim 2, wherein a guide member is disposed within the delivery housing, the guide member being slidably coupled to the pull wire control end, the guide member guiding the pull wire control end to slide along an axial direction of the delivery tube.

7. The delivery system of a delivery device for a transfemoral valve repair as in claim 1, wherein the proximal end of the mandrel is provided with a release control end through which the mandrel is connected or disconnected from the transfemoral valve repair device.

8. The delivery system of a transfemoral valve repair transporter of claim 2, wherein the release structure further comprises a prosthetic control assembly comprising:

the proximal end and the distal end of the rotating sleeve are of an open structure, the rotating sleeve is hollow inside and is connected to the conveying shell;

the spiral pipe has a hollow inner part and is at least partially positioned in the rotary sleeve, the near end extends out of the rotary sleeve, and the outer wall of the spiral pipe is provided with external threads;

the central core rod fixing part is detachably connected with the central core rod and detachably connected with the near end of the spiral tube;

one end of the pushing nut is in threaded connection with the external thread of the spiral pipe, and the other end of the pushing nut can move along the circumferential direction of the rotary sleeve;

the far end of the middle core rod penetrates through the middle core rod fixing piece, the spiral pipe and the conveying pipe in sequence and then is connected with the transfemoral valve repair device.

9. The delivery system of a transfemoral valve repair transporter according to claim 8, wherein the outer wall of the rotating sleeve is circumferentially provided with a pin slot;

be provided with the internal thread on the near-end inner wall of propulsion nut, through the internal thread with the external screw thread threaded connection of spiral pipe, the distal end of propulsion nut is equipped with the pin mounting hole along radially digging, the propulsion nut passes in proper order through a propulsion pin the pin mounting hole with the pin draw-in groove with the rotating sleeve connects.

10. The delivery system of a transfemoral valve repair transporter according to claim 8, wherein a cannula flange is provided on a proximal outer wall of the rotating cannula;

be provided with the internal thread on the near-end inner wall of propulsion nut, through the internal thread with the external screw thread threaded connection of spiral pipe, the distal end of propulsion nut is provided with the nut throat, the propulsion nut passes through the nut throat cover is established outside the sleeve pipe flange with the rotating sleeve connects.

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