JP3941366B2 - Syringe device stopper - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention provides a syringe barrel device suitably used for suction.Stopper mounted onA syringe barrel device that can be fixedly held in a state in which a negative pressure suction force is applied to the inside without operating the operation force.StopperIt is about.
[0002]
[Prior art]
The syringe barrel generally has an outer cylinder having a cylinder tip to which a fluid passage such as a tube or a pipe is connected, and an inner cylinder inserted into the outer cylinder, and a piston portion is provided at the tip of the inner cylinder. Thus, the piston portion is slid along the inner surface of the outer cylinder by pushing the inner cylinder into the outer cylinder or pulling it out of the outer cylinder. Inside the outer cylinder, a fluid chamber is defined by the piston portion, and the fluid chamber is expanded and contracted by operating the inner cylinder, so that fluid can be pumped from the cylinder tip or sucked from the cylinder tip. it can. This syringe barrel is widely used in the medical field and the like in order to inject a chemical solution or to pump a cleaning solution.
[0003]
In order to operate the syringe barrel, a finger-hanging portion projecting in a flange shape is formed at the base end portion of the outer cylinder, and a finger contact portion is formed at the base end portion of the inner cylinder, and these are used to operate the syringe cylinder Are formed. Then, with the thumb resting against the finger rest, and with the index finger and middle finger sandwiching the outer cylinder, and with these two fingers resting against the finger rest, the finger rest is placed on the finger rest. When operated in the approaching direction, the inner cylinder is pushed into the outer cylinder. As a result, the volume of the fluid chamber partitioned by the piston portion is reduced, and the fluid in the fluid chamber is pumped to the fluid passage connected to the cylinder tip. The syringe barrel configured as described above is a syringe for fluid pumping, and is used for a wide range of applications such as injecting an injection solution or other chemicals into the body, spraying pigments, or washing the inner wall of a body cavity. .
[0004]
The syringe barrel is also used for sucking and removing body fluids or applying a suction force to the tissue when collecting the body tissue. The direction of operation of the suction syringe barrel is opposite to that of the fluid pressure syringe barrel. That is, in the syringe for fluid pressure feeding, the inner cylinder is pushed into the outer cylinder, but in the syringe for suction, the inner cylinder is operated to be pulled out from the outer cylinder. Therefore, in order to perform suction using the fluid pressure-feeding syringe, it is necessary to hold the outer cylinder with one hand and pull out the inner cylinder from the outer cylinder with the other hand.
[0005]
Whether the body fluid or the like is sucked or the body tissue is sucked, when the inner cylinder is operated to be pulled out from the outer cylinder, a force in the direction of being pulled back into the outer cylinder acts on the inner cylinder. It is necessary to keep this suction state only for the time. For this purpose, for example, as shown in Japanese Patent Application Laid-Open No. 62-284636, a syringe holding device is known.
[0006]
The configuration of this known syringe barrel holding device includes an outer cylinder fixing mechanism section that fixes the outer cylinder, and a saw-toothed stopper mechanism section that locks a finger pad at the tip of the inner cylinder. Then, the inner cylinder of the syringe barrel was held in a state where it was pulled out from the outer barrel by a predetermined amount, and a negative pressure suction force was applied to the syringe barrel by attaching the outer barrel and the stopper mechanism to the syringe barrel holding device. Can be fixed in a state.
[0007]
[Problems to be solved by the invention]
By the way, for example, when the body is punctured by the puncture member and a predetermined amount of the body tissue is sucked from the tissue suction port provided at the tip of the puncture member, the inner cylinder has a large force in the direction of being drawn into the outer cylinder. Will act. In order to fix the syringe barrel to the syringe barrel holding device, first, the outer cylinder is fixed at a predetermined position of the outer cylinder fixing mechanism portion, and then the finger contact portion at the tip of the inner cylinder is locked to the stopper mechanism portion. There is a risk that the force applied to the inner cylinder during the syringe barrel fixing operation may be distorted. The inner cylinder may be pulled into the outer cylinder, or the inner cylinder may be pulled too much, resulting in a larger negative pressure suction force. There is also a risk that the tissue cells are aspirated more than necessary to damage the tissue, and the operation of fixing the syringe barrel cannot always be performed accurately and smoothly, and the operability is poor There is.
[0008]
The present invention has been made in view of the above points. The object of the present invention is to automatically or easily perform the operation when the inner cylinder is pulled out from the outer cylinder to a predetermined position. The purpose is to enable the cylinder to be fixedly held at a position pulled out from the outer cylinder by a predetermined amount.
[0009]
[Means for Solving the Problems]
  In order to achieve the aforementioned objectives,FirstThe invention includes an outer cylinder formed of a cylindrical member having a cylindrical tip formed at the tip and a flange portion provided at an opening end opposite to the cylindrical tip, and a piston that slides in a tightly fitted state inside the outer cylinder. Provided at the tip, a finger rest is provided at the base end, a shaft is provided between the piston and the finger rest, and one or a plurality of circles are provided at an intermediate portion in the axial direction of the shaft. The inner cylinder is provided with a plate-like reinforcing portion, and is attached to an injection cylinder device in which a fluid chamber is formed between the cylinder tip of the outer cylinder and the piston of the inner cylinder, and the fluid chamber is in a negative pressure state. A stopper for holding the inner cylinder between the flange portion of the outer cylinder and the reinforcing portion provided on the inner cylinder when the inner cylinder is moved in a direction to be pulled out from the outer cylinder. In order to prevent the inner cylinder from being pulled into the outer cylinderAnd a hook body that is detachably fixed to the flange portion of the outer cylinder, and a hook that is rotatably attached to the hook body and is biased in a direction approaching the inner cylinder by a biasing means. When the shaft portion is pulled out and the reinforcing portion passes through the hook, the hook engages with the reinforcing portion and restricts the movement of the inner cylinder in the direction of being drawn into the outer cylinder.It is characterized by the construction of the stopper means.
  The second aspect of the present invention has a cylindrical tip formed at the tip, an outer cylinder made of a cylindrical member having a flange portion at the opening end opposite to the cylindrical tip, and a tight fit inside the outer cylinder. A sliding piston is provided at the tip, a finger rest is provided at the base end, a shaft is continuously provided between the piston and the finger rest, and an axial middle portion of the shaft is provided. An inner cylinder provided with a plurality of disc-shaped reinforcing portions, and is mounted on an injection cylinder device in which a fluid chamber is formed between the cylinder tip of the outer cylinder and the piston of the inner cylinder; A stopper for holding in a negative pressure state between the flange portion of the outer cylinder and the reinforcing portion provided on the inner cylinder when the inner cylinder is moved in a direction to be pulled out from the outer cylinder. To prevent the inner cylinder from being pulled into the outer cylinder. It is composed of an elastic stopper composed of a V-shaped spring that is always outwardly exerted with an elastic force, and this elastic stopper is mounted in a state of expanding toward the piston side of the shaft portion, and in a free state The front end of the outer cylinder is wider than the inner diameter of the outer cylinder and is expanded to a position in contact with the surface of the flange portion.
[0010]
Here, as a specific configuration of the stopper means, a hook body that is detachably fixed to the flange portion of the outer cylinder, and a direction that is rotatably attached to the hook body and is close to the inner cylinder by the biasing means. The hook that is biased to be configured to be rotatable, and when the shaft portion is pulled out and the reinforcing portion passes through the hook, the hook engages with the reinforcing portion and enters the outer cylinder of the inner cylinder. It can be set as the structure which controls the motion of the direction pulled in. In addition, as another configuration example, it is arranged between the front and rear reinforcing portions provided on the shaft portion of the inner cylinder, between the reinforcing portion and the finger rest portion, etc., and a V-shape in which elastic force always acts outwardly. It is composed of an elastic stopper consisting of a spring, and this elastic stopper is mounted so as to expand toward the piston side of the shaft portion. In the free state, its tip is outside the inner diameter of the outer cylinder and abuts against the flange surface. It can also be comprised by what expands to a position. Furthermore, it can be constituted by a stopper ring provided with a horizontally long slot that is engaged with the flange portion of the outer cylinder and is mounted so as to be reciprocally movable at a predetermined interval in a direction orthogonal to the axis of the outer cylinder. A stopper projection that protrudes inward is connected to one side of the stopper ring, and when the outer cylinder is biased to one side of the stopper ring, this stopper projection is provided on the shaft of the inner cylinder. When engaged with the portion and biased toward the other side, the reinforcing portion may be able to pass through the position where the stopper protrusion is disposed.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings. First, as an example, the syringe barrel device according to the present invention can be used as a means for generating a negative pressure suction force in a tissue collection device. Therefore, FIG. 1 shows the entire configuration of the tissue collection device, and FIG. 2 shows a state in which body tissue cells are collected by this cell collection device. Here, the tissue collection device is inserted into a body cavity through a treatment instrument insertion channel of an ultrasonic endoscope, for example, and is necessary under monitoring by an endoscope observation means at a stage before being inserted into the body. After being inserted into the puncture site and inserted into the body, it is placed under the supervision of the ultrasonic observation means and guided to the tissue collection site.
[0012]
Thus, as is apparent from FIG. 1, the tissue collection device 1 is composed of a catheter 2 inserted into a body cavity using a treatment instrument insertion channel or the like of an ultrasonic endoscope as a guide, and an operation unit 3 thereof. The syringe barrel device 10 is detachably connected to the proximal end portion of the operation unit 3. The catheter 2 is longer than at least the entire length of the treatment instrument insertion channel, and from the outermost peripheral side, the sheath member 4, a puncture tube 5 inserted into the sheath member 4, and the puncture tube 5 The cutter tube body 6 is inserted.
[0013]
The sheath member 4 is a cylindrical member having flexibility, and is composed of, for example, a close-contact coil. Further, the puncture tube body 5 can be projected and retracted with respect to the sheath member 4, and is constituted by a thin pipe having an open tip, and a sharp needle tip 5a is formed by cutting the tip of the tip obliquely. ing. A suction hole 5b is formed in the vicinity of the tip of the needle tip 5a. On the other hand, the cutter tube body 6 is a thin pipe-like member inserted so that the entire circumference slides into the puncture tube body 5, and the outer peripheral edge side of the tip thereof is sharpened in a blade shape. In this state, an annular cutting edge 6a is formed.
[0014]
The puncture tube 5 is movable in the front-rear direction within the sheath member 4, and the cutter tube 6 is moved in the front-rear direction with almost no gap with respect to the puncture tube 5. Yes. The puncture tube 5 moves to a retracted position where the needle tip 5a is covered by the sheath member 4 and an operating position protruding from the tip of the sheath member 4 by a predetermined length. Further, the cutter tube body 6 is reciprocally displaced in the puncture tube body 5 between a retracted position where the blade edge 6a is located on the proximal end side with respect to the suction hole 5b and an extrusion position passing through the suction hole 5b. However, even when the cutter tube 6 is displaced to the pushing position, the cutting edge 6a of the cutter tube 6 is held at a position in front of the portion of the puncture tube 5 where the needle tip 5a is formed.
[0015]
The operation portion 3 provided at the proximal end portion of the catheter 2 is connected to the holding cylinder 7 to which the proximal end portion of the sheath member 4 is connected and the proximal end portion of the puncture tube 5, and slides relative to the holding cylinder 7. The first sliding member 8 that is dynamically displaced and the second sliding member 9 that is connected to the proximal end portion of the cutter tube 6 and that is slidably displaced with respect to the first sliding member 8 are configured. . With respect to the holding cylinder 7, the first and second sliding members 8 and 9 move in conjunction with each other so that the puncture tube 5 and the cutter tube 6 are integrated with each other to advance and retract with respect to the sheath member 4. Therefore, when the first sliding member 8 is operated so as to be pushed into the holding cylinder 7, the puncture tube 5 keeps a predetermined positional relationship with respect to the cutter tube 6, and the distal end of the sheath member 4. Can project a predetermined length. In this state, when the second sliding member 9 is slid with respect to the first sliding member 8, the cutter tube body 6 appears and disappears with respect to the puncture tube body 5.
[0016]
By configuring as described above, the body tissue can be cut out and collected. For this purpose, first, the distal end of the catheter 2 is guided to a predetermined position with respect to the inner wall S of the body cavity with the puncture tube 5 and the cutter tube 6 pulled into the sheath member 4. From this state, by operating the first sliding member 8 to be pushed into the holding cylinder 7, the needle tip 5a of the puncture tube 5 is inserted into the body toward the tissue T to be collected, As shown in FIG. 2, the suction port 5b is advanced to a position where it enters the tissue T. At this time, the cutter tube body 6 is positioned on the proximal side from the suction port 5b of the puncture tube body 5. Next, by applying a negative pressure suction force to the cutter tube 6 that is substantially in close contact with the puncture tube 5, the body tissue T enters the suction port 5 b of the puncture tube 5. Will be drawn.
[0017]
After the body tissue T is sufficiently drawn into the puncture tube 5 from the suction port 5b, the second sliding member 9 is operated to be pushed into the first sliding member 8. As a result, the cutter tube 6 is pushed out and moved forward to a position where it passes through the suction hole 5b of the puncture tube 5. As a result, the internal tissue T is cut by the cutting edge 6a and taken into the puncture tube 5. Then, the tissue T is collected by removing the catheter 2 from the body cavity while maintaining the state in which the negative pressure suction force is applied to the cutter tube 6. In this way, when the applied pressure is applied to the cutter tube 6 after the catheter 2 is taken out of the body cavity, the collected tissue T can be transferred to, for example, a test tube or the like.
[0018]
As described above, in order to collect the tissue T, it is necessary to apply a negative pressure suction force to the cutter tube 6, and the second sliding member 9 is a syringe barrel for applying a negative pressure suction force. A connecting portion 9a of the device 10 is provided, and this syringe barrel device 10 is detachably connected to the connecting portion 9a.
[0019]
FIG. 3 shows a basic configuration of the syringe barrel device 10. The syringe barrel device 10 includes an outer barrel 11 and an inner barrel 12. The outer tube 11 has a tube tip 13 continuously provided on an end wall on the distal end side thereof, and this tube tip 13 is formed in a tapered shape, and is a second portion constituting the operation unit 3 of the tissue sampling device 1. The connecting portion 9a provided on the sliding member 9 is detachably coupled by a luer lock mechanism or the like. A flange portion 14 as an operation force acting portion is formed in the opening portion on the proximal end side of the outer cylinder 11, and this flange portion 14 functions as a finger hook portion when used for fluid pressure feeding.
[0020]
The base end portion of the outer cylinder 11 is open, and the inner cylinder 12 is inserted therein. This inner cylinder 12 is provided by connecting a piston portion 16 to the tip of a shaft portion 15. Although the shaft portion 15 has a shape such as a circular rod shape, in order to give strength and strength in the bending direction, the shaft portion 15 is made of a cross-shaped member, and is located in the middle In two or three places, disk-shaped reinforcing portions 17 are continuously provided. Further, a circular finger rest 18 is continuously provided at the base end portion of the shaft portion 15, and this finger rest 18 is also an operating force acting portion, as a finger rest when used for fluid pressure feeding. It functions.
[0021]
Therefore, this syringe barrel device 10 incorporates the inner cylinder 12 into the outer cylinder 11, and stores a chemical solution or the like in the fluid chamber defined by the piston portion 16 of the inner cylinder 12 inside the outer cylinder 11, By positioning the index finger and the middle finger on both sides of the outer cylinder 11 and abutting on the flange part 14 and abutting the thumb against the finger rest part 18, the syringe barrel apparatus 10 can be held in a stable state. . When operated so as to push in the finger rest 18, the chemical solution in the fluid chamber is pumped from the tube tip 13 toward the suction passage 6. Therefore, this syringe barrel device 10 functions as a syringe for fluid pressure feeding.
[0022]
If the piston portion 16 of the inner cylinder 12 is displaced in the direction in which it is pulled out with respect to the outer cylinder 11, the volume of the fluid chamber is increased, so that it can also function as a suction syringe. However, in this case, since the operation is performed in the direction in which the inner cylinder 12 is pulled out, the syringe apparatus 10 cannot be operated with one hand, and the outer cylinder 11 is fixedly held by one hand and the other hand is operated. Thus, the operation is performed in the direction in which the inner cylinder 12 is pulled out.
[0023]
By the way, as described above, when the syringe barrel device 10 configured as described above is used to suck the tissue T and connected to the cell collection device 1, the tissue can be operated with both hands when performing the suction operation. Until the catheter 2 of the collection device 1 is taken out of the body, the syringe barrel device 10 must be kept as it is, that is, in a state where negative pressure is acting on the fluid chamber. If the hand is released from the syringe cylinder device 10, the inner cylinder 12 is drawn into the outer cylinder 11 by the action of negative pressure in the fluid chamber, and the tissue T taken into the cutter cylinder 6 becomes the puncture tube 5. It comes out from the opening of the tip.
[0024]
  Therefore, in the present invention, the inner cylinder 12 and the outer cylinder 11 are placed in a state in which the inner cylinder 12 of the syringe barrel apparatus 10 is pulled out to a predetermined position with respect to the outer cylinder 11 by a simple mechanism and simple operation. Can be fixedly held in this state. For this purpose, the syringe barrel device 10 holds the inner barrel 12 in a predetermined position.A stopper is installed. Configure this stopperThe stopper means is basicallyThe flange portion 14 of the outer cylinder 11 andA disc-shaped reinforcing portion 17 provided on the shaft portion 15 of the inner cylinder 12;The inner cylinder 12 is held at a predetermined position with respect to the outer cylinder 11.Therefore, in the following description, the hook means shown in FIGS. 4 to 6 as the first form of the stopper means, the elastic stopper system shown in FIGS. 7 to 9 as the second form, and FIG. 10 as the third form. The slide system shown in FIG. However, it goes without saying that the configuration of the stopper means is not limited to these specific examples.
[0025]
First, as a first embodiment of the stopper means, the hook unit 20 shown in FIG. 4 is used. This hook unit 20 has a hook 22 mounted on a hook body 21 so as to be swingable. The hook body 21 is fixedly held on the outer cylinder 11. Therefore, the hook main body 21 has a substantially portal shape, and the inner side has an arc shape substantially the same as the outer diameter of the outer cylinder 11, and this arc is preferably an arc surface 21a of 180 ° or less. . Further, slits 21 b and 21 b are formed from the lower end surface of the hook body 21 to a predetermined position, and the slit 21 b is for inserting the flange portion 14 provided in the outer cylinder 11. Here, a plurality of anti-slip protrusions 14a are formed on the finger-holding surface of the flange portion 14, and the width of the slit 21b is the total of the thickness of the flange portion 14 and the protrusion height of the protrusion 14a. It is slightly smaller. Therefore, when the hook body 21 is attached to the outer cylinder 11, the flange portion 14 enters the slit 21b, and the slit 21b is slightly expanded by the tip of the protrusion 14a. It is fixed very firmly.
[0026]
A groove 21c is formed on the upper surface of the hook body 21, and the hook 22 is swingably mounted inside the groove 21c. The hook 22 has a U-shaped cross section. As is apparent from FIG. 5, the hook body 21 is provided with a swing shaft 23 so as to penetrate in the width direction of the groove 21c. The swing shaft 23 is swingably supported. For this purpose, overhang portions 22a and 22a are provided in the intermediate portion of the hook 22, and the swing shaft 23 is inserted through the overhang portions 22a and 22a. Further, a torsion coil spring 24 for applying a biasing force to the hook 22 is attached to the swing shaft 23 at a position between the overhanging portions 22 a of the hook 22.
[0027]
As shown in FIG. 5, when the hook unit 20 is attached to the outer cylinder 11 of the syringe barrel device 10, the hook 22 is held at a position where it abuts against the edge portion of the groove 21a by the action of the torsion coil spring 24. The In this state, the hook 22 is inclined so that the tip 22b faces the shaft 15 side of the inner cylinder 12. In this state, the tip portion 22b of the hook 22 is not in contact with the shaft portion 15 of the inner cylinder 12 (in the shaft portion formed in a cross shape, in the space between the plate surface and the plate surface). Positioned) and disposed at a position to engage with the reinforcing portion 17.
[0028]
By configuring the stopper means as described above, as shown in FIG. 5, from the state in which the piston portion 16 is pushed into the vicinity of the cylinder tip 13 of the outer cylinder 11, as shown in FIG. When the piston portion 16 is slid and displaced with respect to the outer cylinder 11 and pulled out to a predetermined position, the volume of the fluid chamber increases, and negative pressure suction corresponding to the increase in the volume is achieved. Force is generated.
[0029]
When the inner cylinder 12 is pulled out from the outer cylinder 11, the hook 22 protrudes toward the inside of the outer cylinder 11, but the hook 22 is not in contact with the shaft portion 15 of the inner cylinder 12. The inner cylinder 12 can be pulled out smoothly. The shaft portion 15 is provided with a reinforcing portion 17, and the hook 22 is in contact with the reinforcing portion 17. However, since the hook 22 can rotate in the direction indicated by the arrow in FIG. 5 against the urging force of the torsion coil spring 24, the hook 22 can get over the reinforcing portion 17. Then, after overcoming the reinforcing portion 17, the hook 22 returns to the original state by the action of the torsion coil spring 24.
[0030]
In the shaft portion 15, when the force applied to the inner cylinder 12 is released after the inner cylinder 12 is pulled out to the position where any one of the reinforcement portions 17 is over the hook 22, the hook 22 comes into contact with the reinforcement portion 17. And stop at that position. Therefore, even when a negative pressure is applied to the inside of the fluid chamber, the cut tissue T is drawn into the inner part of the cutter cylinder 6, and the distal end side is in a negative pressure state from the position of the tissue T. However, the inner cylinder 12 is not displaced in the direction of being drawn into the outer cylinder 11. Of course, the inner cylinder 12 is subjected to a pulling force into the outer cylinder 11, so there is no possibility that the inner cylinder 12 moves in the direction in which the inner cylinder 12 is pulled out from the outer cylinder 11. As a result, the operator or the like grasps the outer tube 11 with one hand and pulls out the inner tube 12 with the other hand, and then is taken into the catheter 2 even if the hand is released from the syringe device 10. The tissue T is kept in a stable state.
[0031]
Next, in the second embodiment of the stopper means, as shown in FIG. 7, a tweezers-type elastic stopper 30 in which an elastic member is bent into a V shape is used. Here, the elastic stopper 30 has a length equal to or shorter than the interval between the front and rear reinforcing portions 17, 17 in the shaft portion 15 of the inner cylinder 12, and the folded portion is opposite to the piston portion 16. Two pieces are mounted on both front and back sides of one plate surface constituting the shaft portion 15 so as to face the side. In the free state, as shown by the phantom line in FIG. 7, the elastic stopper 30 has the flange of the outer cylinder 11 from the position of the plate surface of the shaft portion 15 when the inner cylinder 12 is inserted into the outer cylinder 11. Only the width up to the middle position of the portion 14 can be expanded. The elastic stopper 30 having the above-described configuration is configured such that one side thereof is a fixed portion 30a fixed to the plate surface of the shaft portion 15 by means of adhesion, and the other side is a resilient portion 30b held in a free state. In addition, the adhering portion 30a does not necessarily need to be adhering when it is held so as not to be detached from the shaft portion 15 due to its elasticity.
[0032]
As shown in FIG. 8, when the inner cylinder 12 is pushed into the outer cylinder 11, the elastic stopper 30 elastically deforms the elastic portion 30b toward the fixing portion 30a. Thus, the shaft portion 15 is accommodated in the outer cylinder 11 including the elastic stopper 30. When the fluid chamber formed by the piston portion 16 is expanded in the outer cylinder 11 and the inner cylinder 12 is pulled out from the outer cylinder 11 to generate a negative pressure in the fluid chamber, the shaft portion 15 The elastic stopper 30 provided between the reinforcement parts 17 and 17 is also pulled out with this.
[0033]
When the inner cylinder 12 is pulled out to a position where the elastic stopper 30 is completely exposed to the outside, the restriction on the elastic portion 30b of the elastic stopper 30 is released, and the elastic stopper 30 is elastically deformed in a direction away from the fixing portion 30a. As a result, as shown in FIG. 9, the tip of the resilient portion 30 b rides on the flange portion 14 provided continuously with the outer cylinder 11. Here, since the fluid chamber is in a negative pressure state, the fluid pressure acts in a direction in which the inner cylinder 12 is to be pulled into the outer cylinder 11, but the tip of the elastic portion 30 b in the elastic stopper 30. Is pressed against the flange portion 14, and the folded portion from the elastic portion 30 b to the fixing portion 30 a is pressed against the reinforcing portion 17 and held in this state. Therefore, even if the operator removes his / her hand from the syringe barrel device 10, there is no possibility that the inner barrel 12 will be pulled into the outer barrel 11. Further, since the fluid pressure is applied to the inner cylinder 12 in the direction in which the inner cylinder 12 is drawn into the outer cylinder 11, the inner cylinder 12 does not move in the direction in which it is pulled out from the outer cylinder 11.
[0034]
Further, as a third embodiment of the present invention, as shown in FIG. 10, the inner cylinder 12 can be held in a state where it is pulled out from the outer cylinder 11 by using a slide type stopper ring 40. It is configured. Here, the stopper ring 40 has a long hole 41 penetrating in the plate thickness direction, and this long hole 41 has a diameter through which the outer cylinder 11 of the syringe barrel device 10 is inserted. A first arc surface portion 41a and a second arc surface portion 41b are formed on the other side, and a linear portion having a predetermined length is formed between the arc surface portions 41a and 41b. Both circular arc surface portions 41 a and 41 b have the same radius of curvature as the outer surface of the outer cylinder 11, and the width dimension of the straight line portion between them is substantially the same as the diameter of the outer cylinder 11. The outer cylinder 11 is movable along a long hole 41 from a position where it comes into contact with the first arcuate surface portion 41a to a position where it comes into contact with the second arcuate surface portion 41b. The stopper ring 40 is further formed with a slit having a width through which the flange portion 14 connected to the outer cylinder 11 is inserted, and a notch groove slightly wider than the width dimension of the flange portion 14 on one end surface side thereof. 42 is formed. The slit becomes the stopper non-operating side slit 43a on the first arcuate surface portion 41a side, and the stopper operating side slit 43b on the second arcuate surface portion 41b side. A stopper projection 44 is formed on the end face of the cut-out groove 42 on the position side.
[0035]
The outer cylinder 11 constituting the syringe barrel apparatus 10 is incorporated so as to be inserted into the long hole 41 of the stopper ring 40. When the outer cylinder 11 is inserted into the stopper ring 40, the flange portion 14 is inserted into the notch groove 42 by being inserted at the position of the straight portion in the long hole 41 of the stopper ring 40. As shown in FIG. 11, when the outer cylinder 11 is brought into contact with the first arcuate surface portion 41a, the flange portion 14 is inserted into the stopper non-operation side slit 43a. As a result, the outer cylinder 11 is held in a stable state in the stopper ring 40. In this state, the inner cylinder 12 provided in the outer cylinder 11 can be pushed and pulled without any obstacles.
[0036]
By pulling out the inner cylinder 12 from the outer cylinder 11, a negative pressure suction force can be applied to the fluid chamber. After the reinforcing portion 17 provided on the shaft portion 15 of the inner cylinder 12 is stroked until it is positioned outside the flange portion 14 of the outer cylinder 11, the stopper ring 40 is pushed in a direction orthogonal to the axis of the outer cylinder 11. Then, the outer cylinder 11 is slid to a position where it comes into contact with the second arcuate surface 41b. At this time, the flange portion 14 is inserted into the stopper operating side slit 43b. Since the stopper projection 44 protrudes from the stopper operation side slit 43b side in the notch groove 42, the stopper projection 44 is on the surface of the shaft portion 15 of the inner cylinder 12 facing the piston portion 16 side. Engage. As a result, the inner cylinder 12 is fixed at that position, a negative pressure is applied in the fluid chamber, and a pulling force is applied to the inner cylinder 12 even though a force to pull the inner cylinder 12 into the outer cylinder 11 is applied. Even if the inner cylinder 12 is released, the inner cylinder 12 does not move freely.
[0037]
【The invention's effect】
Since the present invention is configured as described above, when the operation of pulling out the inner cylinder from the outer cylinder to a predetermined position is performed, the inner cylinder is fixed to a position where the inner cylinder is pulled out from the outer cylinder by a predetermined amount automatically or by a simple operation. The effect that it can hold | maintain etc. is produced.
[Brief description of the drawings]
FIG. 1 is an overall configuration diagram of a tissue collection device to which a syringe barrel device according to an embodiment of the present invention is attached.
2 is a cross-sectional view of a distal end portion of a catheter showing a state in which a body tissue is to be collected by the tissue collection device of FIG.
FIG. 3 is an overall configuration diagram of a syringe barrel device.
FIG. 4 is an external view of stopper means showing the first embodiment of the present invention.
FIG. 5 is a cross-sectional view in which the stopper means of FIG. 4 is incorporated in a syringe barrel device and the stopper means is in an inoperative state.
6 is a cross-sectional view in which the stopper means of FIG. 4 is incorporated in a syringe barrel device and the stopper means is in an activated state.
FIG. 7 is an external view of stopper means showing a second embodiment of the present invention.
8 is a cross-sectional view in which the stopper means of FIG. 7 is incorporated into a syringe barrel device and the stopper means is in an inoperative state.
9 is a cross-sectional view in which the stopper means of FIG. 7 is incorporated into a syringe barrel device and the stopper means is in an activated state.
FIG. 10 is an external view of stopper means showing a third embodiment of the present invention.
11 is a cross-sectional view in which the stopper means of FIG. 10 is incorporated into a syringe barrel device and the stopper means is in an inoperative state.
12 is a cross-sectional view in which the stopper means of FIG. 10 is incorporated into a syringe barrel device and the stopper means is in an activated state.
[Explanation of symbols]
1 Tissue Collection Device 10 Syringe Device
11 outer cylinder 12 inner cylinder
14 Flange part 15 Shaft part
16 Piston part 17 Reinforcement part
18 Finger rest 20 Hook unit
21a Arc surface 21b Slit
22 Hook 23 Oscillating shaft
24 torsion coil spring 30 elastic stopper
30a adhering part 30b impacting part
40 Stopper ring 41 Long hole
41a First arc surface 41b Second arc surface
42 Notch groove 43a Stopper non-operating side slit
43b Stopper operating slit 44 Stopper protrusion

Claims (2)

A cylinder tip is formed at the tip, and an outer cylinder made of a cylindrical member provided with a flange at the opening end opposite to the cylinder tip, and a piston that slides in a tightly fitted state inside the outer cylinder are provided at the tip. The base end portion is provided with a finger contact portion, a shaft portion is continuously provided between the piston and the finger contact portion, and one or a plurality of disk-shaped members are provided in an intermediate portion in the axial direction of the shaft portion. The inner cylinder is provided with a reinforcing portion, and is attached to an injection cylinder device in which a fluid chamber is formed between the cylinder tip of the outer cylinder and the piston of the inner cylinder, and holds the fluid chamber in a negative pressure state. A stopper for
When the inner cylinder is moved in the direction of pulling out from the outer cylinder, the inner cylinder is engaged between the flange portion of the outer cylinder and the reinforcing portion provided in the inner cylinder, and the inner cylinder is engaged with the outer cylinder. A hook body that is detachably fixed to the flange portion of the outer cylinder, and a direction that is rotatably attached to the hook body and that is close to the inner cylinder by a biasing means to prevent being pulled into the inside. The shaft is pulled out, and when the reinforcing part passes through the hook, the hook engages with the reinforcing part and is pulled into the outer cylinder of the inner cylinder. A stopper for a syringe barrel device characterized by comprising stopper means for restricting movement of the syringe barrel. A cylinder tip is formed at the tip, and an outer cylinder made of a cylindrical member provided with a flange at the opening end opposite to the cylinder tip, and a piston that slides in a tightly fitted state inside the outer cylinder are provided at the tip. The base end portion is provided with a finger rest portion, a shaft portion is continuously provided between the piston and the finger rest portion, and a plurality of disk-shaped reinforcing portions are provided in an intermediate portion in the axial direction of the shaft portion. And is mounted on a syringe barrel device in which a fluid chamber is formed between the barrel tip of the outer barrel and the piston of the inner barrel, and holds the fluid chamber in a negative pressure state. A stopper,
When the inner cylinder is moved in the direction of pulling out from the outer cylinder, the inner cylinder is engaged between the flange portion of the outer cylinder and the reinforcing portion provided in the inner cylinder, and the inner cylinder is engaged with the outer cylinder. In order to prevent it from being pulled in, it is arranged between the front and rear reinforcing parts, and is composed of an elastic stopper made up of a V-shaped spring that always exerts an elastic force outwardly. Mounted in a state of expanding toward the piston side, and in a free state, the tip is configured to expand to a position that is outside the inner diameter of the outer cylinder and abuts on the surface of the flange portion. A stopper of the syringe barrel device .

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