CN113331880A

CN113331880A - Miniature full alimentary canal multi-position clamp type biopsy sampling device

Info

Publication number: CN113331880A
Application number: CN202110571415.4A
Authority: CN
Inventors: 马进; 颜国正; 赵凯; 刘大生; 王志武
Original assignee: Shanghai Jiaotong University
Current assignee: Shanghai Jiaotong University
Priority date: 2021-05-25
Filing date: 2021-05-25
Publication date: 2021-09-03
Anticipated expiration: 2041-05-25
Also published as: CN113331880B

Abstract

A miniature full alimentary canal multi-position forceps-type biopsy sampling device, comprising: the shell and a driving mechanism, a transmission mechanism and an operating mechanism which are arranged in the shell in sequence; the drive device includes: miniature step motor, reduction gear, piston that link to each other in proper order and set up in transmission lead screw wherein: the transmission screw rod and the piston are matched through threads to convert the rotation of the micro stepping motor into the linear motion of the piston; the device can realize high-reliability multi-position biopsy sampling of the whole digestive tract, and can realize the action of the sequential action mechanism and pull the elastic clamp to realize the clamping operation of gastrointestinal tract tissues at the designated position under the driving of the micro motor.

Description

Miniature full alimentary canal multi-position clamp type biopsy sampling device

Technical Field

The invention relates to the technology in the field of medical equipment, in particular to a miniature full-digestive tract multi-position clamp type biopsy sampling device.

Background

The existing endoscopic biopsy sampling usually realizes sampling operation through a slender catheter with a guide needle, is limited by factors such as a towline and the like, so that the detection range is usually limited to the digestive tract part which is easy to enter from the outside of the body, such as the stomach or the large intestine, and the acquisition operation of pathological tissues, such as the small intestine and the like, is more complicated, and unnecessary psychological pressure and pain are brought to a patient when open biopsy sampling or percutaneous puncture biopsy sampling is performed during sampling or by adopting an operation. The capsule endoscopy technology avoids the problems, has the characteristics of no towline, small volume, no wound and the like, but the prior related research usually focuses on image acquisition and transmission or single-position biopsy sample acquisition in the alimentary tract, and is limited by the volume of the capsule endoscopy, so an effective multi-position tissue biopsy sampling device module is not available.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides the miniature full-alimentary-tract multi-position clamp type biopsy sampling device, which can prevent a sampling sample from being polluted by driving the biopsy sampling device to act through an in-vitro control instruction so as to ensure the effectiveness of the alimentary-tract biopsy sampling sample.

The invention is realized by the following technical scheme:

the invention relates to a miniature full digestive tract multi-position clamp type biopsy sampling device, which is arranged in a capsule endoscope robot and comprises: the shell, and a driving mechanism, a transmission mechanism and an operating mechanism which are arranged in the shell in sequence.

The driving device comprises: miniature step motor, reduction gear, piston that link to each other in proper order and set up in transmission lead screw wherein: the transmission screw rod and the piston are matched through threads to convert the rotation of the micro stepping motor into the linear motion of the piston.

The transmission mechanism comprises: go up the ejector sleeve, push down pipe, spring holder, push rod disk seat and main spring, wherein: the spring seat sets up in the device front end position and links to each other with the device shell, and the push rod disk seat sets up in the device intermediate position and contacts with the device shell, and main spring sets up between push tube and the spring seat down and links to each other with the two, and push tube constitute cockscomb structure and inlay the combination down, and the piston promotes cockscomb structure and inlays the combination and move down, because on the push tube protruding and push tube cover card slot restraint relation make the push tube can only follow the draw-in groove downstream.

The operating mechanism comprises: consecutive push rod valve, elasticity core bar and elasticity clamp, wherein: the outside of the elastic core rod is provided with a push rod spring which pushes a push rod valve together with a push rod of the lower push pipe to act on the elastic core rod to push the elastic clamp out, so that the elastic clamp is opened and is close to the part to be sampled in the alimentary canal.

The rear end of the device is provided with a push pipe sleeve, the push pipe sleeve, an upper push pipe and a lower push pipe form a sequential rotating structure, and the upper push pipe rotates for an angle and is opposite to a next push rod valve every time the micro stepping motor rotates forwards and backwards to prepare for the next sequential action.

Technical effects

The invention integrally solves the defect that the existing capsule endoscope robot technology can not realize multi-position tissue biopsy sampling; compared with the prior art, the capsule endoscope robot has the advantages that the capsule endoscope robot is supported to realize the full digestive tract multi-position biopsy sampling function, and the function of preventing the sample collected by the capsule endoscope robot from being polluted can be realized.

Drawings

FIG. 1 is a schematic view of a capsule endoscopic robotic system with a full alimentary canal multi-position clamp biopsy sampling device;

in the figure: the capsule endoscope biopsy sampling device comprises a capsule endoscope robot shell, a capsule endoscope robot transmitting and receiving antenna, a capsule endoscope biopsy sampling device, a capsule endoscope robot receiving device, a capsule endoscope biopsy sampling device and a capsule endoscope biopsy sampling device, wherein the capsule endoscope robot receiving device comprises a capsule endoscope robot shell, a capsule endoscope transmitting and receiving antenna, a capsule endoscope robot transmitting and receiving antenna, a capsule endoscope receiving module, a capsule receiving module, a rectifying and control circuit, a capsule endoscope sampling device, a capsule endoscope biopsy sampling device, a capsule endoscope robot receiving antenna, a capsule endoscope receiving module, a capsule endoscope receiving antenna, a capsule endoscope receiving module, a capsule endoscope robot receiving antenna, a capsule endoscope robot receiving module, a capsule receiving antenna, a capsule endoscope robot receiving antenna, a capsule endoscope robot receiving antenna, a capsule endoscope receiving antenna, a capsule receiving antenna;

FIG. 2 is a cross-sectional view of the apparatus of the present invention;

FIG. 3 is an external view of the apparatus of the present invention;

in the figure: 12 device shells, 13 micro stepping motors, 14 reducers, 15 pistons, 16 pushing pipes, 17 pushing pipe sleeves, 18 pushing rod valves, 19 pushing rod springs, 20 spring seats, 21 elastic core rods, 22 elastic clamps, 23 device front ends, 24 pushing rod valve seats, 25 main springs, 26 pushing pipes and 27 transmission lead screws;

fig. 4 is a structural diagram of a sequential action mechanism of a capsule endoscope robot.

Detailed Description

As shown in fig. 1, the present embodiment relates to a capsule endoscopic robotic system with a biopsy sampling device of the whole digestive tract multi-position forceps-taking type, comprising: set up and be used for realizing the order sampling and take the sampling to the multiposition pincers that supply pathological analysis usefulness in vitro biopsy sampling device 8 on capsule endoscope robot shell 1, this capsule endoscope robot shell 1 outside is equipped with wireless energy emission module 11 that is used for producing alternating magnetic field, and inside is equipped with to be used for producing wireless energy receiving module 4 of induced electromotive force.

The capsule endoscope robot shell 1 in further be equipped with rectification and control circuit 5 and the transmitting and receiving antenna 2, radio frequency transceiver 3, miniature light filling lamp 6 and the image sensor 7 that link to each other with it, wherein: the rectification and control circuit 5 rectifies and filters the induced potential and supplies the rectified and filtered induced potential to functional modules embedded in the capsule endoscope robot for use, and the transmitting and receiving antenna 3 receives external signals or transmits acquired sensor data such as vision and the like to the outside of the body. The radio frequency transceiver 3 realizes the synthesis of the transmitted signal, and receives, demodulates and modulates the received signal; the miniature light supplement lamp 6 provides illumination for the image sensor when moving in the alimentary canal.

The capsule endoscope robot shell 1 comprises a transparent cover 9 and a silica gel protection cover 10, and has the functions of protecting and fixing all modules in the capsule endoscope robot.

As shown in fig. 2, the multi-position clamp biopsy sampling device 8 includes: a housing 12 and a drive mechanism, a transmission mechanism and an operating mechanism arranged in sequence inside the housing.

The driving device comprises: the miniature step motor 13, reduction gear 14, piston 15 that link to each other in proper order and set up drive screw 27 wherein: the drive screw 27 and the piston 15 are in threaded engagement to convert the rotation of the micro stepper motor 13 into linear motion of the piston 15.

The transmission mechanism comprises: push-up tube 26, push-down tube 16, spring seat 20, push-rod valve seat 24, and main spring 25, wherein: the spring seat 20 is arranged at the front end of the device and connected with the device shell 12, the push rod valve seat 24 is arranged at the middle position of the biopsy sampling device and contacted with the device shell 12, the main spring is arranged between the lower push tube 16 and the spring seat 20 and connected with the lower push tube and the spring seat, the upper push tube 26 and the lower push tube 16 form a zigzag insertion combination, the piston 15 pushes the zigzag insertion combination to move downwards, and the lower push tube 16 can only move downwards along the clamping groove due to the constraint relation between the upper protrusion of the upper push tube 26 and the clamping groove of the push tube sleeve 17.

As shown in fig. 4, the back end of the biopsy sampling device is provided with a push pipe sleeve 17, the push pipe sleeve 17, an upper push pipe 26 and a lower push pipe 16 form a sequential rotation structure, and the upper push pipe 26 rotates for an angle and faces the next push rod valve 18 every time the micro stepping motor 13 rotates forwards and backwards to prepare for the next sequential action.

The operating mechanism comprises: the push rod valve 18, the elastic core rod 21 and the elastic clamp 22 are connected in sequence, wherein: the outside of the elastic core rod 21 is provided with a push rod spring 19, the push rod part fixed with the lower push pipe 16 pushes the push rod valve 18, and the push rod spring acts on the elastic core rod 21 to push the elastic clamp 22 out, so that the elastic clamp 22 is opened and is close to the part to be sampled in the alimentary canal.

When the piston 15 runs to the top end of the clamping groove of the push pipe sleeve 17, the micro stepping motor 13 rotates reversely, under the combined action of the slide block structure on the surface of the upper push pipe 26, the sawtooth-shaped groove at the end part and the main spring 25, the lower push pipe 16 rotates for a certain angle and is pushed into the next sliding groove of the push pipe sleeve 17, the push rod part fixed by the lower push pipe 16 is opposite to the next push rod valve 18, wherein the push rod valves 18 are uniformly distributed along the circumferential direction and keep the same with the sampling number, and each push rod valve 18 drives one elastic core rod 21. When the micro stepping motor 13 reaches the top end of the clamping groove of the push pipe sleeve 17 and rotates reversely, under the action of the elastic core rod, the push rod valve 18 resets and drives the elastic core rod 21 to rebound, and the elastic clamp 22 is pulled to clamp and take the gastrointestinal tract tissues.

Through specific practical experiments, under the condition of simulating the full digestive tract environment, the capsule endoscope robot biopsy sampling device is operated, so that the tissue samples on the inner wall of the digestive tract can be smoothly clamped, the biopsy sampling is effectively prevented from being polluted, and the multi-position biopsy sampling is realized. Compared with the prior art, the device provides driving force through the micro stepping motor 13, the upper push tube 26, the lower push tube 16, the push tube sleeve 17 and the main spring 25 are matched with each other, and can sequentially drive the elastic core rods 21 and the elastic clamp 22 to finish clamping action, so that the multi-position tissue biopsy sampling of the capsule endoscope robot in a narrow environment in the alimentary canal is realized; after the clamping action is finished, under the action of the push rod spring 19, the elastic core rod 21 resets, the elastic clamp 22 is pulled, the front end 23 of the device retracts, the silica gel protective cover 10 is closed, the device is isolated from the outside, and the sampling is prevented from being polluted.

The foregoing embodiments may be modified in many different ways by those skilled in the art without departing from the spirit and scope of the invention, which is defined by the appended claims and all changes that come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein.

Claims

1. The utility model provides a miniature full alimentary canal multiposition pincers formula biopsy sampling device, places in capsule scope robot inside which characterized in that includes: the shell and a driving mechanism, a transmission mechanism and an operating mechanism which are arranged in the shell in sequence;

the driving device comprises: miniature step motor, reduction gear, piston that link to each other in proper order and set up in transmission lead screw wherein: the transmission screw rod and the piston are matched through threads to convert the rotation of the micro stepping motor into the linear motion of the piston;

2. The micro full alimentary canal multi-position clamp-on biopsy sampling device according to claim 1, wherein said operating mechanism comprises: consecutive push rod valve, elasticity core bar and elasticity clamp, wherein: the outside of the elastic core rod is provided with a push rod spring which pushes a push rod valve together with a push rod of the lower push pipe to act on the elastic core rod to push the elastic clamp out, so that the elastic clamp is opened and is close to the part to be sampled in the alimentary canal.

3. The micro whole digestive tract multi-position clamp type biopsy sampling device according to claim 1, wherein a push tube sleeve is arranged at the rear end of the device, the push tube sleeve and the push tube sleeve form a sequential rotating structure, the micro stepping motor rotates one angle per positive and negative rotation of the push tube sleeve and faces the next push rod valve to prepare for the next sequential action.

4. The micro total digestive tract multi-position clamp-on biopsy sampling device according to any one of claims 1 to 3, wherein the capsule endoscopic robot comprises: the multi-position clamping type biopsy sampling device is arranged on a capsule endoscope robot shell and used for realizing sequential sampling and bringing the sampling to the outside of a body for pathological analysis, a wireless energy transmitting module used for generating an alternating magnetic field is arranged outside the capsule endoscope robot shell, and a wireless energy receiving module used for generating induced potential is arranged inside the capsule endoscope robot shell.

5. The micro full alimentary canal multi-position clamp-on biopsy sampling device according to claim 4, wherein said capsule endoscopic robot housing further comprises a rectifying and control circuit and a transmitting and receiving antenna, a radio frequency transceiver, a micro fill-in light and an image sensor connected thereto, wherein: the rectification and control circuit rectifies and filters the induced potential and supplies the rectified and filtered induced potential to each functional module embedded in the capsule endoscope robot for use, the transmitting and receiving antenna receives external signals or transmits acquired sensor data such as vision and the like to the outside of the body, and the radio frequency transceiver synthesizes the transmitted signals, receives, demodulates and modulates the received signals; the miniature light supplement lamp provides illumination for the image sensor when moving in the alimentary canal.

6. The micro full alimentary canal multi-position clamp-on biopsy sampling device according to claim 4, wherein said capsule-endoscopic robot housing includes a transparent cover and a silicone protective cover, functioning to protect and secure the modules within the capsule-endoscopic robot.