CN112169137A

CN112169137A - Adjustable microcatheter for cerebrovascular intervention and method of use

Info

Publication number: CN112169137A
Application number: CN202011187412.2A
Authority: CN
Inventors: 万海伟
Original assignee: Individual
Current assignee: Individual
Priority date: 2018-10-08
Filing date: 2018-10-08
Publication date: 2021-01-05
Also published as: CN112169136A; CN112169135A; CN109303963B; CN109303963A

Abstract

The invention discloses an adjustable microcatheter for cerebrovascular intervention and a use method thereof, the adjustable microcatheter comprises a guide wire, and further comprises a catheter body, an avoiding hole, a plaster, a cushion, a clamping sleeve, a clamping plate, a threaded sleeve, a handle, an insulating sleeve, a push plate, a spring, a conductive block and an electromagnet.

Description

Adjustable microcatheter for cerebrovascular intervention and method of use

The application has the following application numbers: 2018111673268, the name is: the divisional application of the invention patent application of 'an adjustable microcatheter for cerebrovascular intervention' is as follows: year 2018, month 10, and day 08.

Technical Field

The invention relates to the technical field of medical instruments, in particular to an adjustable microcatheter for cerebrovascular intervention.

Background

Cerebral hemorrhage refers to the condition of cerebral hemorrhage caused by non-traumatic brain parenchyma, and the cause of the cerebral hemorrhage is mainly related to the pathological changes of cerebral vessels, namely, hyperlipidemia, diabetes, hypertension, aging of blood vessels and the like. The traditional treatment after cerebral hemorrhage is medicine, but the medicine has slow hemostasis, and sequela is often left after the craniotomy after the blood coagulation. The interventional therapy operations (arterial micro-guide wire expansion operations and stent implantation operations) are diagnosis and treatment operations performed by adopting a series of interventional instruments and materials and modern digital diagnosis and treatment equipment; compared with the traditional surgical operation, the method only needs local anesthesia and a small opening of 1-2mm, so that the method has the advantages of less bleeding, small wound, less complication, quick postoperative recovery, safety, reliability and the like, thereby greatly relieving the pain born by the patient.

According to the above, the cranial nerve interventional therapy refers to minimally invasive intracavity surgical treatment of cerebrovascular diseases by forming a small hole at the femoral artery blood vessel part of a human body and then penetrating a micro guide wire into the blood vessel of a patient. Wherein the little pipe is after deep into the assigned position, in order to improve the stability and the accuracy of treatment, the fastness and the stability of little pipe are crucial, but current little pipe, because of simple structure, function singleness lack fine fixed, consequently not only improved the risk of operation, also increased medical personnel's operation burden, in view of above defect, it is necessary in fact to design the little pipe of regulation formula that is used for cerebrovascular intervention.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: an adjustable microcatheter for cerebrovascular intervention is provided to solve the problems set forth in the background.

In order to solve the technical problems, the technical scheme of the invention is as follows: an adjustable microcatheter for cerebrovascular intervention comprises a guide wire, a catheter body, an avoiding hole, a patch, a cushion, a cutting sleeve, a clamping plate, a thread sleeve, a handle, an insulating sleeve, a push plate, a spring, a conductive block and an electromagnet, wherein the avoiding hole is positioned inside the catheter body, the avoiding hole is a circular through hole and is connected with the guide wire in a sliding way, the patch penetrates through the outer wall of the catheter body and is connected with the catheter body in a sliding way, the cushion is connected with the catheter body in a sliding way and is connected with the patch by adopting an adhesive, the cutting sleeve penetrates through the outer wall of the catheter body, the cutting sleeve is connected with the catheter body in a sliding way, the cutting sleeve is connected with the cushion by adopting the adhesive, the clamping plate is positioned at the upper end and the lower end of the right side inside the cutting sleeve, the utility model discloses a pipe, including pipe body, insulating cover, conducting block, electromagnet, cutting ferrule outer wall, insulating cover, conducting block and push pedal, the threaded sleeve run through in cutting ferrule outer wall right side, threaded sleeve and cutting ferrule screw thread link to each other, the handle be located pipe body right side lower extreme, handle and pipe body an organic whole link to each other, insulating cover be located the handle left side, insulating cover and handle adopt the adhesive to link to each other, just insulating cover and pipe body adopt the adhesive to link to each other, the push pedal run through in insulating cover inside upper end, the spring run through in push pedal outer wall upper end, spring and push pedal adopt the welding to link to each other, the conducting block be located push pedal bottom, conducting block and push pedal adopt the adhesive to link to each other, just conducting block and insulating cover slide to link.

Further, the right side in the catheter body is also provided with a guide hole, and the guide hole is a conical through hole.

Furthermore, clearance holes are further formed in the upper end and the lower end of the interior of the clamping sleeve and are through holes.

Further, the handle inside still be equipped with the battery, battery and handle adopt the bolt to link to each other.

Further, the lower end of the left side in the handle is further provided with a switch, the switch is connected with the handle through bolts, and the switch is respectively connected with the electromagnet and the storage battery lead.

Furthermore, the front end of the catheter body is also provided with a dial gauge, and the dial gauge is integrally connected with the catheter body.

Compared with the prior art, the adjustable microcatheter for cerebrovascular intervention has the advantages that during operation, medical personnel firstly put the catheter body into the microcatheter from a minimally invasive opening of a patient, then paste the application on the skin of the patient to fix the cutting sleeve, then move the catheter body through the existing medical science to realize that the catheter body is positioned at a cerebrovascular treatment part, then rotate the threaded sleeve to realize that the threaded sleeve rotates from right to left along the outer wall of the cutting sleeve, after the threaded sleeve contacts the clamping plate, the clamping plate moves inwards through the driving force action of the threaded sleeve, namely the clamping plate contacts the catheter body to realize clamping of the catheter body, at the moment, through the operation, the effective fixation of the catheter body and the cutting sleeve is ensured, namely the positioning effect on the catheter body is realized, then when the medical personnel operates a guide wire, the switch can be opened in advance to realize the electrification of the storage battery and the electromagnet, the electromagnet is started to attract the conductive block, the conductive block drives the push plate to overcome the resilience force of the spring to move from top to bottom, the push plate moves downwards to cancel clamping of the guide wire, the moving state of the guide wire and the catheter body is realized, then the guide wire can be operated, the guide wire slides along the avoidance hole, the guide wire stops moving after reaching a treatment area, in order to ensure the positioning and fixing effect of the guide wire, medical personnel can close a switch, namely the power is cut off between the storage battery and the electromagnet, the stopping work of the electromagnet is realized, namely the electromagnet cancels attraction of the conductive block, under the effect of the resilience force of the spring, the push plate moves from bottom to top along the insulating sleeve, namely the push plate moves upwards, so that the guide wire can be clamped, the effective fixation of the guide wire is realized, the operation of subsequent medical personnel is convenient, and the adjustable microcatheter for cerebrovascular intervention is provided, easy operation, powerful, at first through the fixed design of pipe, can reach the location fixed to the pipe, stable and safety in the follow-up operation process has been ensured, secondly through centre gripping formula seal wire mechanism's cooperation effect, also can fix a position the inside seal wire of pipe, the accurate nature of treatment operation has been improved, the burden of medical personnel's operation has been alleviateed, finally reach fine clinical popularization and application purpose, and simultaneously, the guiding hole is for the ease of the seal wire inserts, it is in order to dodge splint to keep away the vacancy hole, insulating cover plays insulating protection effect, the graduation apparatus is for the convenience medical personnel master the degree of depth size of pipe body implantation.

Drawings

FIG. 1 is a front view of an adjustable microcatheter for cerebrovascular intervention;

FIG. 2 is a cross-sectional view of an adjustable microcatheter for cerebrovascular intervention;

FIG. 3 is an enlarged sectional view of the insulating sleeve portion;

fig. 4 is an enlarged cross-sectional view of the ferrule portion.

The medical catheter comprises a guide wire 1, a catheter body 2, an avoidance hole 3, an application 4, a cushion 5, a clamping sleeve 6, a clamping plate 7, a threaded sleeve 8, a handle 9, an insulating sleeve 10, a push plate 11, a spring 12, a conductive block 13, an electromagnet 14, a guide hole 201, a dial gauge 202, an avoidance hole 601, a storage battery 901 and a switch 902.

The following detailed description will be further described in conjunction with the above-identified drawings.

Detailed Description

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the concepts underlying the described embodiments, however, it will be apparent to one skilled in the art that the described embodiments may be practiced without some or all of these specific details, and in other cases well-known process steps have not been described in detail.

As shown in figures 1, 2, 3 and 4, the adjustable microcatheter for cerebrovascular intervention comprises a guide wire 1, a catheter body 2, an avoidance hole 3, an application 4, a cushion 5, a clamping sleeve 6, a clamping plate 7, a threaded sleeve 8, a handle 9, an insulating sleeve 10, a push plate 11, a spring 12, a conductive block 13 and an electromagnet 14, wherein the avoidance hole 2 is positioned inside the catheter body 2, the avoidance hole 3 is a circular through hole, the avoidance hole 3 is connected with the guide wire 1 in a sliding manner, the application 4 penetrates through the outer wall of the catheter body 2, the application 4 is connected with the catheter body 2 in a sliding manner, the cushion 5 penetrates through the outer wall of the catheter body 2, the cushion 5 is connected with the catheter body 2 in a sliding manner, the cushion 5 is connected with the application 4 by an adhesive, the clamping sleeve 6 penetrates through the outer wall of the catheter body 2, the clamping sleeve 6 is connected with the catheter body 2 in a sliding manner, the cutting sleeve 6 is connected with the cushion 5 by adopting an adhesive, the clamping plate 7 is positioned at the upper end and the lower end of the right side in the cutting sleeve 6, the right side of the clamping plate 7 is integrally connected with the cutting sleeve 6, the thread sleeve 8 runs through the right side of the outer wall of the cutting sleeve 6, the thread sleeve 8 is in thread connection with the cutting sleeve 6, the handle 9 is positioned at the lower end of the right side of the catheter body 2, the handle 9 is integrally connected with the catheter body 2, the insulating sleeve 10 is positioned at the left side of the handle 9, the insulating sleeve 10 is connected with the handle 9 by adopting the adhesive, the insulating sleeve 10 is connected with the catheter body 2 by adopting the adhesive, the push plate 11 runs through the upper end in the insulating sleeve 10, the push plate 11 is connected with the insulating sleeve 10 in a sliding manner, the spring 12 runs through the upper end of the outer wall of the push plate 11, the spring 12 is connected with the push plate, the conductive block 13 is connected with the push plate 11 by adopting an adhesive, the conductive block 13 is connected with the insulating sleeve 10 in a sliding way, the electromagnet 14 is positioned at the lower end of the inside of the insulating sleeve 10, the electromagnet 14 is connected with the insulating sleeve 10 by bolts, the right side in the catheter body 2 is also provided with a guide hole 201, the guide hole 201 is a conical through hole, the upper and lower ends of the interior of the cutting sleeve 6 are also provided with clearance holes 601, the clearance holes 601 are through holes, a storage battery 901 is also arranged inside the handle 9, the storage battery 901 is connected with the handle 9 by bolts, the lower end of the left side in the handle 9 is also provided with a switch 902, the switch 902 is connected with the handle 9 by bolts, the switch 902 is respectively connected with the electromagnet 14 and the storage battery 901 through wires, the front end of the catheter body 2 is further provided with a dial gauge 202, and the dial gauge 202 is integrally connected with the catheter body 2.

The invention also relates to a method of the adjustable microcatheter for cerebrovascular intervention, which comprises the following steps:

step one, placing and fixing the ferrule

During operation, medical staff puts the catheter body into the minimally invasive opening of the patient and then pastes the application patch on the skin of the patient to realize the fixation of the cutting sleeve;

step two, positioning the catheter body

After the cutting sleeve is fixed in the first step, the catheter body is moved to be positioned at a cerebrovascular treatment part, the threaded sleeve is rotated to enable the threaded sleeve to rotate from right to left along the outer wall of the cutting sleeve, when the threaded sleeve is rotated to be contacted with the clamping plate, the clamping plate is moved inwards under the action of the pushing force of the threaded sleeve, the clamping plate is contacted with the catheter body, the catheter body is clamped and positioned, and therefore the catheter body and the cutting sleeve are effectively fixed;

step three, fixing the guide wire

After the catheter body and the clamping sleeve are effectively fixed through the second step, the switch is turned on, the storage battery and the electromagnet are powered on, the conductive block is attracted, the push plate is driven to move from top to bottom, the push plate moves downwards to eliminate clamping of the guide wire, the guide wire and the catheter body are in a movable state, the guide wire is moved to slide along the avoidance hole, the guide wire stops moving after reaching a treatment area, the switch is turned off, the storage battery and the electromagnet are powered off, the electromagnet eliminates attraction of the conductive block, the push plate moves from bottom to top along the insulating sleeve under the action of resilience force of the spring, and the guide wire 1 is effectively fixed through upward movement of the push plate and clamping of the guide wire; after the catheter body and the guide wire are stably and accurately positioned, medical workers carry out minimally invasive intracavity surgery treatment on cerebrovascular diseases.

Specifically, the method comprises the following steps: when the adjustable microcatheter for cerebrovascular intervention is used for surgery, medical staff firstly puts the catheter body 2 into the minimally invasive opening of a patient, then pastes the application patch 4 on the skin of the patient, namely, the clamping sleeve 6 is fixed, then the medical staff moves the catheter body 2 through the existing medical knowledge, namely, the catheter body 2 is positioned at the part for treating the cerebrovascular disease, then the threaded sleeve 8 is rotated, the threaded sleeve 8 rotates from right to left along the outer wall of the clamping sleeve 6, after the threaded sleeve 8 contacts the clamping plate 7, the clamping plate 7 moves inwards under the action of the pushing force of the threaded sleeve 8, namely, the clamping plate 7 contacts the catheter body 2, namely, the clamping of the catheter body 2 is realized, at the moment, through the operation, the effective fixation of the catheter body 2 and the clamping sleeve 6 is ensured, namely, the positioning effect on the catheter body 2 is realized, then when the medical staff operates the guide wire 1, the switch 902 can be turned on in advance to realize the electrification of the storage battery 901 and the electromagnet 14, namely, the electromagnet 14 can attract the conducting block 13 after being turned on, the conducting block 13 can drive the push plate 11 to overcome the resilience force of the spring 12 to move from top to bottom, namely, the push plate 11 moves downwards so as to cancel the clamping of the guide wire 1, the moving state of the guide wire 1 and the catheter body 2 is realized, then the guide wire 1 can be operated, namely, the guide wire 1 slides along the avoidance hole 3, the guide wire 1 stops moving after reaching a treatment area, in order to ensure the positioning and fixing effect of the guide wire 1, medical personnel can turn off the switch 902, namely, the power is cut between the storage battery 901 and the electromagnet 14, the stop work of the electromagnet 14 is realized, namely, the electromagnet 14 cancels the attraction of the conducting block 13, under the resilience force of the spring 12, the push plate 11 insulating sleeve 10 moves from bottom to top, namely, thereby can the centre gripping seal wire 1, realize seal wire 1's effective fixed, make things convenient for follow-up medical personnel's operation, simultaneously, guiding hole 201 is for the convenience of seal wire 1 inserts, keeps away empty hole 601 and is for dodging splint 7, and insulating cover 10 plays insulating protection effect, and graduation apparatus 202 is for the convenience of medical personnel to master the degree of depth size that pipe body 2 put into.

The present invention is not limited to the above-described embodiments, and those skilled in the art will be able to make various modifications without creative efforts from the above-described conception, and fall within the scope of the present invention.

Claims

1. An adjustable microcatheter for cerebrovascular intervention comprises a guide wire, and is characterized by further comprising a catheter body, an avoiding hole, a patch, a cushion, a clamping sleeve, a clamping plate, a threaded sleeve, a handle, an insulating sleeve, a push plate, a spring, a conductive block and an electromagnet, wherein the avoiding hole is positioned inside the catheter body, the avoiding hole is a circular through hole, the avoiding hole is connected with the guide wire in a sliding manner, the patch penetrates through the outer wall of the catheter body and is connected with the catheter body in a sliding manner, the cushion is connected with the patch by adopting an adhesive, the clamping sleeve penetrates through the outer wall of the catheter body, the clamping sleeve is connected with the catheter body in a sliding manner, the clamping sleeve is connected with the cushion by adopting an adhesive, and the clamping plate, the upper end and the lower end of the interior of the cutting sleeve are also provided with clearance holes which are through holes, the free end on the left side of the clamping plate is positioned in the through hole, the right side of the clamping plate is integrally connected with the cutting sleeve, the threaded sleeve penetrates through the right side of the outer wall of the cutting sleeve, the threaded sleeve is in threaded connection with the cutting sleeve, the handle is positioned at the lower end on the right side of the catheter body, the handle is integrally connected with the catheter body, the insulating sleeve is positioned on the left side of the handle, the insulating sleeve is connected with the handle by adopting an adhesive, the insulating sleeve is connected with the catheter body by adopting an adhesive, the push plate penetrates through the upper end of the inner part of the insulating sleeve, the push plate is in sliding connection with the insulating sleeve, the spring penetrates through the upper end of the outer wall of the push plate, the spring is connected with the push plate by welding, the conductive block, and the conducting block slide with insulating cover and link to each other, the electro-magnet be located insulating cover inside lower extreme, electro-magnet and insulating cover adopt the bolt to link to each other, the inside battery that still is equipped with of handle, the battery with the handle adopts the bolt to link to each other, the inside left side lower extreme of handle still be equipped with the switch, switch and handle adopt the bolt to link to each other, just the switch link to each other with electro-magnet and battery wire respectively.

2. An adjustable microcatheter for cerebrovascular intervention according to claim 1, wherein the catheter body is further provided at a front end thereof with a scale, the scale being integrally connected to the catheter body.

3. Method of using a regulated microcatheter for cerebrovascular interventions according to claim 1 or 2, characterised in that: it comprises the following steps:

step one, placing and fixing the ferrule

step two, positioning the catheter body

step three, fixing the guide wire

After the catheter body and the clamping sleeve are effectively fixed through the second step, the switch is turned on, the storage battery and the electromagnet are powered on, the conductive block is attracted, the push plate is driven to move from top to bottom, the push plate moves downwards to eliminate clamping of the guide wire, the guide wire and the catheter body are in a movable state, the guide wire is moved to slide along the avoidance hole, the guide wire stops moving after reaching a treatment area, the switch is turned off, the storage battery and the electromagnet are powered off, the electromagnet eliminates attraction of the conductive block, the push plate moves from bottom to top along the insulating sleeve under the action of resilience force of the spring, and effective fixing of the guide wire is achieved through upward movement of the push plate and clamping of the guide wire; after the catheter body and the guide wire are stably and accurately positioned, medical workers carry out minimally invasive intracavity surgery treatment on cerebrovascular diseases.