CN206239387U - Pulp cavity mirror - Google Patents

Abstract

The utility model discloses a medullary cavity mirror, which belongs to the field of orthopedic diagnosis and treatment instruments, and is used for diagnosis and treatment of long tubular bone fractures or other diseases. The end face of the handle is provided with a working channel A and/or working channel B, and the handle is also provided with a water inlet pipe and a water outlet pipe; wherein the working channel A and/or working channel B run through the handle and the sleeve, and the water inlet pipe Form a circuit with the outlet pipe. In view of the above technical solution, the utility model can realize the visual operation of long tubular bone fracture reduction, and can reduce the wound area of the operation, improve the effect of wound healing and the influence on surrounding tissues.

Description

Endoscopy

technical field

The utility model belongs to the field of orthopedic diagnosis and treatment instruments, in particular to a medullary cavity scope for diagnosis and treatment of long tubular bone fractures or other diseases.

Background technique

Optical endoscopes and ultrasonic probes have small wounds in medical applications or enter the operating area through the natural cavity of the human body, which can perform minimally invasive diagnosis and treatment operations on target organs, and patients recover quickly after surgery.

With the development of medical level and social technology, fracture treatment has gradually changed from the early requirement of solid internal fixation to achieve primary healing to the emphasis on the protection of blood supply to the fracture end and biological fixation to achieve secondary bone healing. The treatment of long tubular fractures belongs to fracture treatment, but in the actual treatment process, in order to improve the clinical efficacy of limb trauma, promote fracture healing, and accelerate the recovery of limb function, more orthopedic surgeons tend to treat long tubular bone fractures In the use of closed reduction intramedullary nail.

However, due to the above-mentioned treatment methods using closed compound under non-direct vision, it is difficult to reset, and it is easy to damage soft tissues such as blood vessels and nerves. Once closed reduction fails, open reduction is required, which increases the probability of surgical infection and easily causes damage to periosteal blood supply. etc., affecting the healing time and effect of the body. Other orthopedic diseases are difficult to implement minimally invasive treatment under the existing medical conditions.

Utility model content

The purpose of this utility model is to provide a medullary endoscope for visual operation of closed reduction of long tubular bone fractures and minimally invasive diagnosis and treatment of other orthopedic diseases, which can reduce the trauma area of surgery, improve the effect of wound healing and the impact on surrounding tissues .

In order to achieve the above object, the utility model is achieved through the following technical solutions:

The intramedullary cavity mirror described in the utility model includes a handle and a sleeve, and the handle and the sleeve are fixedly or detachably connected; the end surface of the handle is provided with a working channel A and/or a working channel B, and the A water inlet pipe and a water outlet pipe are provided; wherein the working channel A and/or the working channel B run through the handle and the casing, and the water inlet pipe and the water outlet pipe form a circuit.

Furthermore, the casing described in the utility model is a straight pipe.

Furthermore, the casing described in the utility model is an arc-shaped tube or a bent tube with a bending angle of 0°-40°.

Furthermore, one end of the bent pipe described in the utility model is a pipe with an arc structure.

Furthermore, the handle described in the utility model is provided with a bypass channel, and the bypass channel communicates with the corresponding working channel A or working channel B.

Furthermore, the handle described in the utility model is detachably connected with a soft tissue puncture assembly.

Furthermore, the soft tissue puncture assembly described in the utility model is connected to the handle through a positioning rod and an adjusting rod; the adjusting rod is set on the positioning rod in a way that can slide left and right for positioning, and the positioning rod is provided with a scale.

Furthermore, the soft tissue puncture assembly described in the utility model includes a soft tissue puncture sleeve and a puncture movable sleeve. The soft tissue puncture sleeve is located in the puncture movable sleeve, and an arc-shaped elastic section is provided , an operation channel is provided inside the soft tissue puncture sleeve, and the operation channel is located in the middle of the arc-shaped elastic section.

Furthermore, the working channel A described in the present invention is a single or multiplexed channel for optical endoscopes, ultrasonic probes, and operating instruments.

Furthermore, the optical endoscope, ultrasonic probe, and operating instruments described in the utility model are made of hard and elastic materials.

Compared with the prior art, the beneficial effects of the utility model are:

The intramedullary endoscope described in this application can realize visualization and minimally invasive treatment in the treatment of long tubular bone fractures, reduce the chance of infection during surgery, reduce the damage to periosteal blood supply, and retain the osteogenic effect in the hematoma The growth factor is low, the incidence of refracture is low, the clinical curative effect of limb trauma is improved, the function recovery of affected limb is accelerated, and the quality of life of patients is improved.

Description of drawings

Fig. 1 is a structural representation of the utility model.

Fig. 2 is a schematic diagram of the connection between the working channel A, the working channel B and the bypass channel in the present invention.

Fig. 3 is a schematic structural view of the soft tissue puncture assembly.

Fig. 4 is a schematic diagram of the first structure of the casing.

Fig. 5 is a schematic diagram of the second structure of the casing.

Fig. 6 is a schematic diagram of the third structure of the casing.

In the figure: 1. handle; 2. working channel A; 3. working channel B; 4. optical endoscope; 5. ultrasonic probe; 6. bypass channel; 7. water inlet pipe; 8. water outlet pipe; 9. connection port ; 10, sleeve; 11, positioning rod; 12, adjustment rod; 13, operating equipment; 14, soft tissue puncture sleeve; 15, puncture movable sleeve;

detailed description

The technical solution described in the present application will be further described below in conjunction with the embodiments.

Embodiment 1: a medullary endoscope, including a handle 1, a sleeve 10, the handle 1 and the sleeve 10 are fixedly or detachably connected; the end surface of the handle 1 is provided with a working channel A2 and/or a working channel B3, The handle 1 is also provided with a water inlet pipe 7 and a water outlet pipe 8; wherein the working channel A2 and/or the working channel B3 run through the handle 1 and the casing 10, and the water inlet pipe 7 and the water outlet pipe 8 form a circuit. The casing 10 is a straight pipe.

Embodiment 2: a medullary endoscope, including a handle 1, a sleeve 10, the handle 1 and the sleeve 10 are fixedly or detachably connected; the end surface of the handle 1 is provided with a working channel A2 and/or a working channel B3, The handle 1 is also provided with a water inlet pipe 7 and a water outlet pipe 8; wherein the working channel A2 and/or the working channel B3 run through the handle 1 and the casing 10, and the water inlet pipe 7 and the water outlet pipe 8 form a circuit. The casing 10 is an arc tube or a bent tube with a bending angle of 0°-40°.

Embodiment 3: A endoscope, the handle 1 is provided with a bypass channel 6, and the bypass channel 6 communicates with the corresponding working channel A2 or working channel B3. The handle 1 is detachably connected with a soft tissue puncture assembly. The structure of the remaining parts is the same as that of Embodiment 1 or Embodiment 2.

Embodiment 4: A medullary endoscope, wherein the soft tissue puncture assembly is connected to the handle 1 through the positioning rod 11 and the adjusting rod 12; 11 is provided with a scale. The soft tissue puncture assembly includes a soft tissue puncture sleeve 14 and a puncture movable sleeve 15. The soft tissue puncture sleeve 14 is located in the puncture movable sleeve 15, and an arc-shaped elastic section 16 is provided at the front of the soft tissue puncture sleeve 14. An operation channel is provided inside the soft tissue puncture sleeve 14 , and the operation channel is located in the middle of the arc-shaped elastic section 16 . The structure of the remaining parts is the same as that in Embodiment 1 to Embodiment 3.

Embodiment 5: A endoscope, wherein the working channel A2 is a single or multiplexed channel of the optical endoscope 4 , the ultrasonic probe 5 , and the operating instrument 13 . The optical endoscope 4, ultrasonic probe 5, and operating instrument 13 are made of hard and elastic materials. The structure of the remaining parts is the same as that in Embodiment 1 to Embodiment 4.

In view of the above-mentioned technical scheme, the handle 1 of the present utility model is in the form of a straight handle or a curved handle. rotation; the utility model can be provided with the working channel A2 on the end face of the handle 1 for the optical endoscope 4, the ultrasonic probe 5, and the operating instrument 13. Congestion and other substances that affect the operation line of sight should be cleaned. Two channels can also be provided, for example, the working channel B3 is used for the optical endoscope 4 and the ultrasonic probe 5 respectively.

The casing 10 described in this application is a straight tube, an arc tube or a bent tube with a bending angle of 0° to 40°, and one end of the bent tube can be an arc-shaped structural pipe, as shown in Fig. 4 to Fig. 6. Because the function of the sleeve 10 is to guide each operating instrument into the medullary cavity of the fracture segment after cleaning. The cannula 10 is made of a material with a certain hardness and elastic bending suitable for the operation of the medullary cavity, or a hard tube with a certain amount of elasticity. The curvature formed by the elastic deformation is compatible with the curvature in the long tubular bone marrow cavity of the human body, so the casing 10 with curvature of different specifications and models can be provided to adapt to different fracture sites. The optical endoscope 4 and the ultrasonic probe 5 pass through the cannula 10 and enter the medullary cavity for observation while adjusting the entry length of the cannula 10 to make it close to the fracture end.

By adjusting the handle 1, leverage is used to adjust the direction close to the fracture end, the field of view of the optical endoscope 4 and the detection range of the ultrasonic probe 5, and at the same time moderately pull the distal end of the body to find the medullary cavity of the fracture end far away. And through the working channel A2 and/or the working channel B3, insert the guide wire into the medullary cavity of the distal fracture end to an appropriate length. The optical endoscope 4, the ultrasonic probe 5, and the cannula 10 are withdrawn, and the pulp is further reamed through the guide wire and the intramedullary nail is driven in.

Use the soft tissue puncture assembly included in this application, including the soft tissue puncture sleeve 14, the puncture movable sleeve 15, and the operating machine 13 to observe the reduction of the fracture end. If the fracture displacement is found, it can be reset under the microscope. Observe the locking nail hole in the inner cavity of the intramedullary nail, drill the hole through the instrument and screw in the locking nail. Complete the reduction and fixation of the fracture site.

The front end of the soft tissue puncture sleeve 14 in the soft tissue puncture assembly described in this application is provided with an arc-shaped elastic section 16. The arc-shaped elastic section 16 has a certain degree of elasticity and can shrink and expand under the action of the puncture movable sleeve 15 . When the arc-shaped elastic section 16 expands outward, it can stretch the soft tissue, thereby giving the operation machine 13 a certain space for operation and observation. The soft tissue puncture assembly is connected to the handle 1 through the positioning rod 11 and the adjustment rod 12, so that the operating position of the soft tissue puncture assembly can be judged and adjusted through the scale and image of the optical endoscope 4. The scale on the positioning rod 11 can well assist the accurate positioning of the position, and is adjusted and fixed by the adjusting rod 12 .

Claims (10)

1. a kind of pulp cavity mirror, including handle (1), it is characterised in that：Also include sleeve pipe (10), handle (1) and sleeve pipe (10) are solid Fixed or detachable connection；The end face of the handle (1) is provided with service aisle A (2) and/or service aisle B (3), in handle (1) On be additionally provided with water inlet pipe (7), outlet pipe (8)；Wherein described service aisle A (2) and/or service aisle B (3) are through handle (1) and sleeve pipe (10), the water inlet pipe (7) constitutes loop with outlet pipe (8).

2. pulp cavity mirror according to claim 1, it is characterised in that：Described sleeve pipe (10) is straight tube.

3. pulp cavity mirror according to claim 1, it is characterised in that：Described sleeve pipe (10) is 0 ° for curved pipe or bending angle ~40 ° of bending tube.

4. pulp cavity mirror according to claim 3, it is characterised in that：One end of the bending tube is arcuate structure pipe fitting.

5. the pulp cavity mirror according to any claim in Claims 1-4, it is characterised in that：The handle (1) is provided with Bypass channel (6), bypass channel (6) and corresponding service aisle A (2) or service aisle B (3) insertion.

6. the pulp cavity mirror according to any claim in Claims 1-4, it is characterised in that：The handle (1) is with removable The mode of unloading is connected with soft tissue piercing assembly.

7. pulp cavity mirror according to claim 6, it is characterised in that：The soft tissue piercing assembly by locating rod (11), Adjusting rod (12) is connected with handle (1)；The adjusting rod (12) is placed in locating rod (11) in the way of the positioning that can horizontally slip, Locating rod (11) is provided with scale.

8. pulp cavity mirror according to claim 6, it is characterised in that：The soft tissue piercing assembly includes that soft tissue punctures set Pipe (14), puncture moving casing (15), soft tissue puncture cannula (14) are interior positioned at moving casing (15) is punctured, and are worn in soft tissue The front portion of thorn sleeve pipe (14) is provided with arc elastic section (16), and operating walk way is provided with the inside of soft tissue puncture cannula (14), grasps Make passage positioned at the centre of arc elastic section (16).

9. pulp cavity mirror according to claim 1, it is characterised in that：The service aisle A (2) is optics scope (4), ultrasound Probe (5), the independent or multiplex channel of operation apparatus (13).

10. pulp cavity mirror according to claim 9, it is characterised in that：The optics scope (4), ultrasonic probe (5), operation Apparatus (13) is hard using matter and the resilient material of tool is made.