CN221083759U - Multifunctional preoperative precise positioner suitable for multiple organs - Google Patents

Abstract

The utility model provides a multifunctional preoperative precise positioner suitable for multiple organs, which comprises a guide system and a positioning system, wherein the guide system comprises a guide needle, a guide needle handle, a scale mark, a rubber limiter, a sharp needle core and a blunt needle core, the tail end of the guide needle is connected with the guide needle handle, the positioning system comprises a microcoil tube, a push rod buckle, a push rod handle, a microcoil, a tail wire and a semi-push mark, and the interior of the guide needle can be matched with the microcoil tube; the utility model improves the safety and the operability of positioning before the excision of the small nodules of each organ in the body, and widens the guiding equipment for positioning before the operation: the ultrasonic, CT, PET/CT and MRI can be used for positioning before operation, so that the positioning accuracy is obviously improved, the surgical scope can be accurately guided, and the maximization of the residual anatomical structure and function of the resected organ of the patient is improved.

Description

Multifunctional preoperative precise positioner suitable for multiple organs

Technical Field

The utility model belongs to the technical field of medicine, and particularly relates to a multifunctional preoperative precise positioner suitable for multiple organs.

Background

With the popularization of physical examination of the whole population, more and more tiny lesions in the human body are detected, such as lung nodules, liver nodules, early lesions of the gastrointestinal tract and the like, so that the early diagnosis and early treatment of the lesions are greatly improved, and more tiny lesions are accompanied with incapacitation or need early surgical intervention; moreover, the accurate surgery ensures the integrity of the residual anatomical structure and the maximization of the functional volume while pursuing the complete elimination of the target focus for the surgical excision scope; so that the accurate positioning requirements before the operation of the micro-nodules are also increasing. The existing preoperative positioning methods and means for lung nodules, liver nodules, kidney nodules, gastrointestinal tracts, intracranial tumors, breast tumors and the like are various, and mainly comprise the steps of percutaneous, tube cavity, alimentary canal and the like under the guidance of CT, ultrasonic imaging or endoscopic imaging, and the like, and have certain advantages and disadvantages respectively by using puncture positioning needles, hookwire needles, microcoils, indocyanine green fluorescent agents or indian ink, indigo, methylene blue and other coloring agents. For example, the positioning needle before the pulmonary nodule operation can not avoid the damage to blood vessels, and the indocyanine green fluorescent agent is used for the preoperative positioning of the lung, the liver and the gastrointestinal tract, and is required to be matched with special expensive detection equipment, the sterility of ultrasonic positioning in the hepatic nodule operation and the higher requirement of matching in operation; or the coloring agent has anaphylactic reaction, low time latitude (less than or equal to 24h/48 h), easy pollution and the like;

The tower-shaped microcoil for the conventional medical vascular embolism has better compatibility with human tissues, is generally not easy to fall off, has no clear stimulation symptom, can exist in the human tissues for a long time, and has no worry and risk of surgical scheduling time. Due to its high safety, stability, comfort, and latitude in surgical time, there has been an increasing use in recent years prior to thoracoscopic lung nodule resections. However, the microcoil used at present is in a tower shape, and can be used for lung tissue positioning identification, but is not suitable for fixation or identification in liver tissue and gastrointestinal tract walls, and the ex-factory indication is limited to vascular embolism, so that legal risks of super-indication use exist in lung tissue. In addition, the needle point of the percutaneous puncture guiding needle is sharp under the guidance of the image, and the vascular injury and the complication of the needle point approach cannot be avoided-!

In summary, no medical apparatus capable of being widely applied to percutaneous puncture positioning under the guidance of multi-organ nodule pre-operation images of lung, liver, kidney, gastrointestinal tract and the like exists at present, so the utility model provides a multifunctional pre-operation accurate positioner applicable to multiple organs to solve the problems.

Disclosure of utility model

In order to solve the technical problems, the utility model provides a multifunctional preoperative precise positioner suitable for multiple organs, which aims to solve the problems that the microcoil shape used in the prior art is tower-shaped, and can be used for positioning and identifying lung tissues, but is not very suitable for fixation or identification in liver tissues and gastrointestinal tract walls, and the adaptation diseases of delivery are limited to vascular embolism, so that legal risks of super-adaptation diseases exist in the lung tissues. In addition, the needle point of the percutaneous puncture guiding needle is sharp under the guidance of the image, and the problems of vascular injury, complications and the like of the needle point approach cannot be avoided.

The utility model provides a multi-functional accurate locator before operation suitable for multi-organ, includes guide system and positioning system, guide system includes guide needle, guide needle handle, scale mark, rubber stopper, sharp needle core and blunt needle core, the tail end connection of guide needle has the guide needle handle, the lateral wall of guide needle is provided with the scale mark, the rubber stopper has been cup jointed on the surface of guide needle, the inside of guide needle is worn through there is sharp needle core, the tail end connection of sharp needle core has sharp needle core handle, the inside of guide needle is worn through there is blunt needle core, the tail end connection of blunt needle core has blunt needle core handle;

The positioning system is divided into a hollow pushing positioning micro-spring ring system and a solid pushing positioning micro-spring ring system, the hollow pushing positioning micro-spring ring system comprises a first micro-spring ring pipe, a first pushing rod buckle, a hollow pushing rod handle, a first micro-spring ring, a tail wire and a hollow semi-pushing mark, the inside of the guide needle can be adaptively connected with the first micro-spring ring pipe, the tail end of the first micro-spring ring pipe is connected with the first pushing rod buckle, the inside of the first micro-spring ring pipe is connected with the hollow pushing rod, the tail end of the hollow pushing rod is connected with the hollow pushing rod handle, the head end of the first micro-spring ring pipe is internally connected with the first micro-spring ring, the tail end of the first micro-spring ring is connected with the tail wire, the surface connection of hollow push rod has hollow half propelling movement sign, the little spring coil system of solid propelling movement location is including second little spring coil pipe, second push rod buckle, solid push rod handle, second little spring coil and the half propelling movement sign of solid, but the inside adaptation of guide pin is connected with second little spring coil pipe, the tail end connection of second little spring coil pipe has the second push rod buckle, the internally connected of second little spring coil pipe has the solid push rod, the tail end connection of solid push rod has the solid push rod handle, the inside implantation of second little spring coil pipe has the second little spring coil, the surface connection of solid push rod has the half propelling movement sign of solid.

Preferably, the outer sheath head end of the guide needle is of a blunt frosted structure, the guide needle is of a hollow structure, and the surface sizes of the sharp-tipped needle core and the blunt-tipped needle core are matched with the inner size of the guide needle.

Preferably, the guide needle handle, the sharp-tipped needle core handle and the blunt-tipped needle core handle are all made of plastic materials, and the rubber limiter can be used for marking the needle penetration depth.

Preferably, the guiding needle is internally connected with a second micro-spring ring pipe, the tail end of the second micro-spring ring pipe is connected with a second push rod buckle, the second micro-spring ring pipe is internally connected with a solid push rod, the tail end of the solid push rod is connected with a solid push rod handle, the second micro-spring ring is implanted in the second micro-spring ring pipe, and the surface of the solid push rod is connected with a solid semi-push mark.

Preferably, the first micro-spring coil pipe and the second micro-spring coil pipe are hollow structures, the lengths of the first micro-spring coil pipe and the second micro-spring coil pipe are the lengths of the head end of the inserted guide needle and the end of the guide needle, and the outer diameter sizes of the first micro-spring coil pipe and the second micro-spring coil pipe are smaller than the inner diameter size of the guide needle.

Preferably, the first micro-spring coil pipe and the second micro-spring coil pipe are respectively formed into a linear structure with the first micro-spring coil and the second micro-spring coil.

Preferably, the tail wire is medical sterile, the tail wire is positioned in the hollow pushing rod, and the length of the hollow pushing rod is equal to the length of the tail end of the tail wire which is completely inserted into the first microcoil tube and is flush with the head end of the first microcoil tube.

Preferably, the first pushing rod buckle and the second pushing rod buckle respectively form an elastic clamping structure with the hollow pushing rod and the solid pushing rod.

Preferably, spindle-shaped microcoils can be respectively implanted in the head ends of the first microcoil tube and the second microcoil tube.

Preferably, the first double-tower type micro-spring coil and the second double-tower type micro-spring coil can be respectively implanted in the head end of the first micro-spring coil pipe and the head end of the second micro-spring coil pipe, and the tail end of the first double-tower type micro-spring coil is connected with a tail wire.

Compared with the prior art, the utility model has the following beneficial effects:

The innovative preoperative accurate positioner aims at improving the safety and the operability of preoperative positioning of the nodule of each organ in the body, and widens the guiding equipment of preoperative positioning: the ultrasonic, CT, PET/CT and MRI can be used for preoperative positioning, can be applied to lung, liver, kidney, gastrointestinal tract, brain, mammary gland and the like, obviously improves the positioning accuracy, can be used for wedge-shaped excision of lung nodules, can also be used for positioning before excision of lung subsections and lung sections, can be used for accurately guiding the surgical excision scope, can also be used for preoperative puncture positioning of liver, kidney and gastrointestinal tract and intracranial small lesions, can be used for accurately guiding the surgical excision scope, improves the maximization of residual anatomical structures and functions of excised organs of patients, can obviously improve the success rate and safety of preoperative positioning, and simultaneously lightens the economic burden of patients and improves the comfort of the patients; the method is also beneficial to promoting and popularizing the application of accurate positioning of preoperative image guidance and further improving the accuracy of the operation.

Drawings

FIG. 1 is a schematic view of the structure of the guide needle of the present utility model;

FIG. 2 is a schematic view of the structure of the sharp-tipped needle of the present utility model;

FIG. 3 is a schematic view of the blunt tip core structure of the present utility model;

FIG. 4 is a schematic diagram of the hollow push rod structure of the present utility model;

FIG. 5 is a schematic view of the structure of a first microcoil tube of the present utility model;

FIG. 6 is a schematic diagram of the hollow half push sign structure of the present utility model;

FIG. 7 is a schematic illustration of the spindle-shaped microcoil structure of the present utility model;

FIG. 8 is a schematic view of a first dual-turret microcoil construction of the present utility model;

FIG. 9 is a schematic diagram of a solid push rod structure of the present utility model;

FIG. 10 is a schematic view of the structure of a second microcoil tube of the present utility model;

FIG. 11 is a schematic diagram of a solid core half push sign structure of the present utility model;

FIG. 12 is a schematic view of a second dual-turret microcoil construction of the present utility model;

fig. 13 is a schematic view of a snap connection structure of a push rod according to the present utility model.

In the figure:

1. A guide needle; 2. a guide needle handle; 3. scale marks; 4. a rubber stopper; 5. a sharp-tipped needle core; 501. a blunt tip stylet; 6. a sharp-tipped needle core handle; 601. a blunt tip core handle; 7. a first microcoil tube; 701. a second microcoil tube; 8. the first pushing rod is buckled; 801. the second push rod is buckled; 9. a hollow push rod; 901. a solid push rod; 10. a hollow push rod handle; 1001. a solid push rod handle; 11. a first microcoil; 1101. a second microcoil; 12. a tail wire; 13. hollow semi-pushing mark; 1301. solid core semi-pushing mark; 14. spindle-shaped microcoil; 15. a first double-tower microcoil; 1501. and a second double-tower microcoil.

Detailed Description

Embodiments of the present utility model are described in further detail below with reference to the accompanying drawings and examples. The following examples are illustrative of the utility model but are not intended to limit the scope of the utility model.

As shown in fig. 1-13, the utility model provides a multifunctional preoperative precise positioner suitable for multiple organs, which comprises a guide system and a positioning system, wherein the guide system comprises a guide needle 1, a guide needle handle 2, graduation marks 3, a rubber limiter 4, a sharp needle core 5 and a blunt needle core 501, the tail end of the guide needle 1 is connected with the guide needle handle 2, graduation marks 3 are arranged on the outer side wall of the guide needle 1, the surface of the guide needle 1 is sheathed with the rubber limiter 4, the sharp needle core 5 is penetrated in the guide needle 1, the tail end of the sharp needle core 5 is connected with the sharp needle core handle 6, the blunt needle core 501 is penetrated in the guide needle 1, and the blunt needle core 601 is connected with the blunt needle core handle 601;

The positioning system is divided into a hollow pushing positioning microcoil system and a solid pushing positioning microcoil system, the hollow pushing positioning microcoil system comprises a first microcoil pipe 7, a first pushing rod buckle 8, a hollow pushing rod 9, a hollow pushing rod handle 10, a first microcoil 11, a tail coil 12 and a hollow semi-pushing mark 13, the inside of the guide needle 1 is connected with the first microcoil pipe 7 in an adaptive manner, the tail end of the first microcoil pipe 7 is connected with the first pushing rod buckle 8, the tail end of the first microcoil pipe 7 is connected with the hollow pushing rod 9, the tail end of the hollow pushing rod 9 is connected with the hollow pushing rod handle 10, the tail end of the first microcoil pipe 7 is connected with a tail wire 12, the surface of the hollow pushing rod 9 is connected with the core semi-pushing mark 13, the solid pushing positioning ring system comprises a second microcoil pipe 901, the tail end of the second microcoil pipe 901 is connected with the hollow pushing rod 801, the hollow pushing rod is connected with the hollow pushing rod 801, and the hollow pushing rod is connected with the hollow pushing rod 801 of the hollow pushing rod 801.

Referring to fig. 1, the sheath tip of the guide needle 1 is a blunt ground structure, the guide needle 1 is a hollow structure, and the surface dimensions of the sharp-tipped needle core 5 and the blunt-tipped needle core 501 are adapted to the internal dimensions of the guide needle 1.

Referring to fig. 1-3, the guide needle handle 2, the sharp-tipped needle handle 6 and the blunt-tipped needle handle 601 are all made of plastic, and the rubber stopper 4 can be used to mark the needle penetration depth.

Referring to fig. 9, a second micro spring coil 701 is connected to the inside of the guide needle 1, a second push rod buckle 801 is connected to the tail end of the second micro spring coil 701, a solid push rod 901 is connected to the inside of the second micro spring coil 701, a solid push rod handle 1001 is connected to the tail end of the solid push rod 901, a second micro spring coil 1101 is implanted in the inside of the second micro spring coil 701, and a solid half push mark 1301 is connected to the surface of the solid push rod 901.

Referring to fig. 9, the first micro-spring coil tube 7 and the second micro-spring coil tube 701 are hollow, the lengths of the first micro-spring coil tube 7 and the second micro-spring coil tube 701 are the lengths of the head end of the guide needle 1 after the guide needle 1 is inserted and the head end of the guide needle 1 is flush, and the outer diameter sizes of the first micro-spring coil tube 7 and the second micro-spring coil tube 701 are smaller than the inner diameter size of the guide needle 1.

Referring to fig. 9, the first microcoil tube 7 and the second microcoil tube 701 are respectively formed into a linear structure with the first microcoil 11 and the second microcoil 1101.

Referring to fig. 4-8, the tail wire 12 is medical sterile, the tail wire 12 is located in the hollow pushing rod 9, and the length of the hollow pushing rod 9 is equal to the length of the tail end of the tail wire which is completely inserted into the first microcoil tube 7 and is flush with the head end of the first microcoil tube 7.

Referring to fig. 4-13, the first push rod buckle 8 and the second push rod buckle 801 respectively form an elastic clamping structure with the hollow push rod 9 and the solid push rod 901, when the hollow push rod 9 needs to be fixed, the first push rod buckle 8 is rotated to the hollow push rod 9, at this time, the first push rod buckle 8 is elastically deformed and is in extrusion contact with the hollow push rod 9, the hollow push rod 9 is prevented from automatically sliding, when the hollow push rod 9 needs to be pushed, the first push rod buckle 8 is rotated aside, and in the process, the first push rod buckle 8 is in friction contact with the tail end of the first microcoil tube 7 through the rotating rod, so that the phenomenon that the first push rod buckle 8 freely rotates is avoided.

Referring to fig. 4-11, spindle-shaped microcoil 14 may be implanted within the head end of the first microcoil tube 7 and the second microcoil tube 701, respectively.

Referring to fig. 7-12, a first dual-tower type microcoil 15 and a second dual-tower type microcoil 1501 may be respectively implanted in the head end of the first microcoil tube 7 and the second microcoil tube 701, and a tail wire 12 is connected to the tail end of the first dual-tower type microcoil 15.

Example 1:

Positioning of percutaneous intracranial small tumors under the guidance of skull MRI: after the operation path is determined by a brain MRI three-dimensional scanning and brain surgeon, a bone marrow biopsy needle is used for local drilling of a skull passageway along the operation path, then a special positioning coaxial puncture guide needle 1 is used for breaking through the meninges of each layer, gradually entering the brain parenchyma, encountering the separation of a blood vessel part replacement blunt needle 501 until the position near the intracranial tumor is reached, then the needle core is withdrawn, a first micro spring ring tube 7 is replaced and inserted, which is a fusiform micro spring ring 14 with a tail wire 12, the head end is flush with the head end of the guide needle 1, a first push rod buckle 8 is loosened, the positioning fusiform micro spring ring 14 is pushed out, the positioning coaxial puncture guide needle 1 is used for scanning again to confirm that the first micro spring ring 11 is positioned around the tumor, the first micro spring ring tube 7 and the guide needle 1 are pulled out, and finally, the positions of the positioning first micro spring ring 11 and the tail wire 12 are confirmed to be correct, and the operation is completed.

Example 2:

Percutaneous breast nodule localization under molybdenum target guidance: after the breast molybdenum target axis position and the oblique position are used for determining the breast nodule position through breast MRI, and a breast surgeon discusses and decides the operation path, the special coaxial puncture guide needle 1 with the sharp head needle core 5 breaks through the skin of the breast, subcutaneous fat is used for gradually inserting the needle into the breast parenchyma, the blunt needle core 501 is replaced by encountering a vascular part and separated until the breast nodule is approached, the needle core is withdrawn, the inserted first microcoil tube 7 is replaced, the spindle-shaped microcoil 14 with the tail wire 12 is scanned again to confirm that the head end position of the guide needle 1 is correct, the first push rod buckle 8 is loosened, the spindle-shaped microcoil 14 is pushed out, the first microcoil 11 is repeatedly scanned to be positioned around the tumor, the first microcoil tube 7 and the guide needle 1 are pulled out, and finally the positions of the first microcoil 11 and the tail wire 12 are scanned and confirmed.

Example 3:

Pulmonary CT scan localization of lung nodules: firstly, performing CT scanning of the whole lung to define the position of a lung nodule, according to the requirements of a chest surgeon, dividing two positioning methods, namely single-line positioning or multi-line positioning, wherein single-tail positioning is mainly used for partial wedge excision, positioning marks of the skin of a body surface, determining specific positioning targets of a first microcoil 11, designing needle insertion paths and depths, using a positioning special coaxial puncture guide needle 1 to break through the skin, subcutaneous fat, muscle gaps, pleura and gradually insert into lung parenchyma, acutely inserting the needle and performing blunt separation until the head end of the guide needle 1 is positioned beside the lung nodule, withdrawing the needle core, replacing an inserted first microcoil tube 7, namely a fusiform microcoil 14 with a tail wire 12, scanning again to confirm that the head end of the guide needle 1 is correct, loosening a first push rod buckle 8, pushing out the fusiform microcoil 14, repeatedly scanning to confirm that the first microcoil 11 is positioned around the tumor, extracting the first microcoil tube 7 and the guide needle 1, and finally scanning to confirm the positions of the first microcoil 11 and the tail wire 12; multiple tail positioning can be used for subsection and lung segment excision, and the range of the surgical excision is determined by first discussing with a chest surgeon, and the range of the surgical excision subsection or lung segment is accurately delineated by positioning the multiple first microcoil 11.

Example 4:

Percutaneous intrahepatic nodule localization under liver MRI guidance: after the liver MR scan is firstly carried out to determine the position of the liver nodule, and the liver and gall surgeon discuss and determine the operation path, the special coaxial puncture guide needle 1 with the sharp head needle core 5 breaks through the skin, subcutaneous fat and peritoneum, gradually enters the liver parenchyma, and is separated by the blunt head needle core 501 with partial replacement of blood vessels until the liver nodule is near, then the needle core is withdrawn, the inserted first microcoil tube 7 is replaced, which is a spindle-shaped microcoil 14 with a tail wire 12, the correct position of the head end of the guide needle 1 is confirmed by scanning again, the first push rod buckle 8 is loosened, the spindle-shaped microcoil 14 is pushed out, the first microcoil 11 is confirmed to be positioned around the tumor by scanning repeatedly, the first microcoil tube 7 and the guide needle 1 are pulled out, and finally the positions of the first microcoil 11 and the tail wire 12 are confirmed by scanning, and the similar positioning can be applied before the operation of the nodules of parenchymal organs such as kidney, spleen and the like.

Example 5:

Percutaneous sigmoid nodule localization under pelvic CT guidance: the CT scanning of the abdomen and the pelvis is firstly carried out, the position of the colon nodule is clarified, according to the operation route of a surgeon, local anesthesia is carried out, the coaxial puncture guide needle 1 is used for puncturing according to the operation route, breaking through the peritoneum and entering the abdominal cavity, the blunt needle core 501 is partially replaced by blood vessels and separated until the near colon nodule is reached, the guide needle 1 enters the intestinal cavity by the sharp needle core 5, the CT scanning confirms that the position is correct, the replacement insertion type first microcoil tube 7 is provided with a tail wire 12 for the first double-tower type microcoil 15, the first push rod buckle 8 is loosened, the push rod is pushed to a half push mark, the CT observation distal end first double-tower type microcoil 15 is popped up and positioned in the intestinal cavity, the guide needle 1 and the first microcoil tube 7 are withdrawn after the local area is about 3-8 mm, the thickness of the intestinal wall is confirmed, the needle tip is positioned outside the intestinal cavity wall, the near-end first double-tower type microcoil 15 is pushed out again, the first double-tower type microcoil 15 is confirmed to be embedded on the intestinal wall, then the first microcoil tube 7, the guide needle 1 and the guide needle 1 is finally, the first double-tower type microcoil 15 is confirmed, and the tail wire 12 is positioned after the positioning is completed.

Example 6:

The positioning of the upper and lower edges of the percutaneous ascending colon nodules under abdominal CT guidance defines the operative scope: when the positioning puncture guide needle 1 and the first micro-spring coil tube 7, which are the head ends of the second double-tower type micro-spring coils 1501, reach the proximal end of the positioning nodule and the inner part of the distal intestinal cavity, the solid pushing rod 901 is used for pushing to a half pushing scale mark: the mark of half length of the second double-tower micro-spring 1501 is scanned and observed, the second double-tower micro-spring 1501 at the far end pops up and is positioned in the intestinal lumen, the guide needle 1 and the first micro-spring 1501 are withdrawn after the mark is together with the thickness of the intestinal wall which is about 3-8 mm, the needle point is confirmed to be positioned outside the intestinal wall, the second double-tower micro-spring 1501 at the near end is pushed out again, the second double-tower micro-spring 1501 is confirmed to be inlaid at the upper edge and the lower edge of the gastrointestinal tract lesion again, and then the guide needle 1 and the first micro-spring 7 are withdrawn integrally, so that the upper and lower excision range of the gastrointestinal tract lesion is accurately defined.

The specific working principle is as follows: as shown in fig. 1-12, when the multifunctional accurate positioner suitable for multiple organs is used, the guiding system reaches the positioning nodule, the sharp needle core 5 and the blunt needle core 501 can be replaced in the process, after the guiding system reaches, the positioning system is used for accurately positioning the operation position, the process is that the needle is pulled out to replace the first microcoil tube 7, and then the pushing rod pushes the first microcoil 11 inside the first microcoil tube 7 to perform operation positioning, and the specific scheme is as follows: by pushing out the first microcoil 11 with the hollow pusher bar 9 to place it in a peri-nodal position when the guide needle 1 and the head end of the first microcoil tube 7 reach around the locating nodule, the guiding needle 1 and the first microcoil tube 7 are pulled out together, and the tail wire 12 is left outside the tissue so that the endoscope probe can find the marking position during the operation; when the guide needle 1 and the head end of the first micro-spring coil tube 7 reach the inner part of the intestinal cavity around the positioning nodule, the hollow pushing rod 9 is used for pushing a half-length mark of the length of the first micro-spring coil 11 with half pushing graduation, the first micro-spring coil 15 at the far end is ejected and positioned in the intestinal lumen after scanning and observing, and then the guide needle 1 and the first micro-spring coil tube 7 are withdrawn for about 3-8 mm of intestinal wall thickness together, the needle tip is confirmed to be positioned outside the intestinal lumen wall, the first double-tower micro-spring coil 15 is pushed out again, then the guide needle 1 and the first micro-spring coil tube 7 are withdrawn integrally, and the tail wire 12 is reserved under the outer abdominal wall of the intestinal wall so that the endoscope probe can find the marking position of the endoscope during operation; in addition, a solid pushing positioning microcoil system can be used for accurately positioning gastrointestinal lesions, a second double-tower microcoil 1501 is arranged in a second microcoil tube 701, when the leading needle 1 and the head end of the second microcoil tube 701 reach the proximal end of a positioning nodule and the inner part of a far-end intestinal cavity, a solid pushing rod 901 is used for pushing to a mark with half the length of the second double-tower microcoil 1501 with half pushing scales, the far-end second double-tower microcoil 1501 is ejected out of the intestinal cavity after being scanned and observed, the leading needle 1 and the second microcoil tube 701 are withdrawn for about 3-8 mm of intestinal wall thickness, the needle point is confirmed to be positioned outside the intestinal cavity wall, the proximal second double-tower microcoil 1501 is pushed out again, and then the guide needle 1 and the second microcoil tube 701 are withdrawn integrally, so that the upper and lower excision scope of gastrointestinal lesions is accurately defined, the guide needle of the utility model can avoid the damage of blood vessels in the lung by using the blunt needle core 501, is more favorable for more accurate positioning, can be used for wedge excision of lung nodules, can also be used for positioning before excision of lung subsections and lung sections, can be used for accurate guide definition surgical excision in the scope of lung, liver, kidney, gastrointestinal tract, brain, mammary gland and the like, can also be used for preoperative puncture positioning of liver and gastrointestinal tract lesions, the microcoil for positioning replaces the traditional metal positioning hooks or needles, the composition has better compatibility of human tissues, is generally not easy to fall off, has no clear stimulation symptoms, can exist in tissues of the lung, the liver and the gastrointestinal tract for a long time, and has no worry and risk of surgical scheduling time; the operation is simple and easy, the technical difficulty is avoided, the falling, shifting and the like do not need to be worried about, the foreign body sensation and the discomfort of a patient are reduced, and the high safety and the success rate are improved;

In addition, the accurate positioning device for preoperative puncture not only can be used for puncture positioning under imaging guidance such as ultrasound, CT, PET/CT and the like, for example, lung, liver, gastrointestinal tract and the like, but also can be used for preoperative puncture positioning under nuclear magnetic resonance imaging guidance after demagnetizing treatment, which greatly expands the application range of the accurate positioning device for preoperative puncture positioning under the imaging guidance of lung, liver, kidney, gastrointestinal tract, brain, mammary gland and the like, such as intracranial lesions and the like, and is the characteristic of the multifunctional accurate positioning device for multiple organs.

The embodiments of the present utility model have been shown and described for the purpose of illustration and description, it being understood that the above embodiments are illustrative and not to be construed as limiting the utility model, and that variations, modifications, alternatives and variations may be made therein by one of ordinary skill in the art without departing from the scope of the utility model.

Claims (9)

1. The utility model provides a accurate locator before multi-functional operation suitable for multi-organ, includes guide system and positioning system, its characterized in that: the guiding system comprises a guiding needle (1), a guiding needle handle (2), scale marks (3), a rubber limiter (4), a sharp needle core (5) and a blunt needle core (501), wherein the tail end of the guiding needle (1) is connected with the guiding needle handle (2), the outer side wall of the guiding needle (1) is provided with the scale marks (3), the rubber limiter (4) is sleeved on the surface of the guiding needle (1), the sharp needle core (5) is penetrated through the guiding needle (1), the sharp needle core handle (6) is connected with the tail end of the sharp needle core (5), the blunt needle core (501) is penetrated through the guiding needle (1), and the blunt needle core handle (601) is connected with the blunt needle core (501) through the tail end of the blunt needle core.

The positioning system is divided into a hollow pushing positioning micro-spring coil system and a solid pushing positioning micro-spring coil system, the hollow pushing positioning micro-spring coil system comprises a first micro-spring coil pipe (7), a first pushing rod buckle (8), a hollow pushing rod (9), a hollow pushing rod handle (10), a first micro-spring coil (11), a tail wire (12) and a hollow semi-pushing mark (13), the inside of the guide needle (1) is connected with the first micro-spring coil pipe (7) in an adaptive manner, the tail end of the first micro-spring coil pipe (7) is connected with the first pushing rod buckle (8), the inside of the first micro-spring coil pipe (7) is connected with the hollow pushing rod (9), the tail end of the hollow pushing rod (9) is connected with the hollow pushing rod handle (10), the head end of the first micro-spring coil pipe (7) is internally connected with the first micro-spring coil (11), the tail end of the first micro-spring coil (11) is connected with the tail wire (12), the tail end of the guide needle (1) is connected with the first pushing rod buckle (101), the solid pushing rod (1101) comprises a hollow pushing rod (801), the solid pushing rod (1101) and the solid pushing rod (1101) is connected with the solid pushing rod system, the inside adaptation of guide needle (1) is connected with second microcoil pipe (701), the tail end connection of second microcoil pipe (701) has second push rod buckle (801), the internal connection of second microcoil pipe (701) has solid push rod (901), the tail end connection of solid push rod (901) has solid push rod handle (1001), the inside implantation of second microcoil pipe (701) has second microcoil (1101), the surface connection of solid push rod (901) has solid half propelling movement sign (1301).

2. A multi-functional preoperative precision positioner for multiple organs as defined in claim 1, wherein: the outer sheath head end of the guide needle (1) is of a blunt grinding structure, the guide needle (1) is of a hollow structure, and the surface sizes of the sharp-tipped needle core (5) and the blunt-tipped needle core (501) are matched with the inner size of the guide needle (1).

3. A multi-functional preoperative precision positioner for multiple organs as defined in claim 1, wherein: the guiding needle handle (2), the sharp needle core handle (6) and the blunt needle core handle (601) are all made of plastic materials, and the rubber limiter (4) can be used for marking the needle inserting depth.

4. A multi-functional preoperative precision positioner for multiple organs as defined in claim 1, wherein: the first micro-spring coil pipe (7) and the second micro-spring coil pipe (701) are of hollow structures, the lengths of the first micro-spring coil pipe (7) and the second micro-spring coil pipe (701) are the lengths of the rear head end of the inserted guide needle (1) and the head end of the guide needle (1) which are flush, and the outer diameter sizes of the first micro-spring coil pipe (7) and the second micro-spring coil pipe (701) are smaller than the inner diameter size of the guide needle (1).

5. A multi-functional preoperative precision positioner for multiple organs as defined in claim 1, wherein: the first micro-spring coil pipe (7) and the second micro-spring coil pipe (701) are respectively formed into a linear structure with the first micro-spring coil (11) and the second micro-spring coil (1101).

6. A multi-functional preoperative precision positioner for multiple organs as defined in claim 1, wherein: the tail wire (12) is medical sterile, the tail wire (12) is located in the hollow pushing rod (9), and the length of the hollow pushing rod (9) is equal to the length of the tail end of the tail wire completely inserted into the first micro-spring coil tube (7) and the tail end of the tail wire completely flush with the first micro-spring coil tube (7).

7. A multi-functional preoperative precision positioner for multiple organs as defined in claim 1, wherein: the first pushing rod buckle (8) and the second pushing rod buckle (801) respectively form an elastic clamping structure with the hollow pushing rod (9) and the solid pushing rod (901).

8. A multi-functional preoperative precision positioner for multiple organs as defined in claim 1, wherein: spindle-shaped microcoils (14) can be respectively implanted into the head ends of the first microcoil tube (7) and the second microcoil tube (701).

9. A multi-functional preoperative precision positioner for multiple organs as defined in claim 1, wherein: the first double-tower type micro-spring coil (15) and the second double-tower type micro-spring coil (1501) can be respectively implanted in the head end of the first micro-spring coil pipe (7) and the head end of the second micro-spring coil pipe (701), and the tail end of the first double-tower type micro-spring coil (15) is connected with a tail wire (12).