NL8902283A - Veterinary insertion tool injecting cylindrical implant - uses spring for rapid injection of transponder or medicament into living tissue via needle - Google Patents

Abstract

The implants (7) are encased in a 'bubble pack' magazine (5), together with disinfectant fluid or pasta. The user draws back the spring-loaded plunger and needle (26) using a cocking time mechanism (13) so that the next implant is inserted in a groove in the needle. The front end of the device is placed in position on the animal's skin and the trigger (3) in the pistol grip (2) is pressed. The needle in injected and an internal rod ejects the implant from the end of the needle. The machine can be powered electrically, rather than by springs.

Description

Implantation tools with impulse action

The invention relates to a tool for implanting a generally cylindrical object via a hypodermic needle, a so-called implant, which contains, for example, a medicinal preparation or an electronic circuit for remote detection, in particular that the hypodermic needle is operated by an independent power source, which is unleashed by a trigger mechanism, is rapidly driven in and that said injection needle, after having reached depth, is also automatically retracted again quickly, leaving the implant in the body, kept at the correct depth by a tool present in the tool push pin.

The tool according to the invention can furthermore be provided with an interchangeable magazine with one or more implants, which are successively offered for implantation by means of a transport device, and which magazine is pierced by the implanting needle, whereby an implant is always taken into the needle cavity.

The insertion of an implant via a hypodermic needle is known per se. Usually the needle is inserted by hand. This is relatively slow - the animal feels pain and will move, which only increases the pain and can also bend the needle. When retraction of the needle also takes place with manual force, the same drawbacks arise. The latter problem was solved by allowing the needle to spring back into the tool under spring force. The applicant has applied for a patent for this.

The tool according to the invention offers a solution to the above drawbacks. The needle is inserted very quickly with an additional power source and retracted very quickly in the same manner, the additional power source operating independently of the manual force. The tools should only be pushed into the correct skin area prior to the implant operation and operated via a trigger mechanism. All implant movements are then made very quickly in an impulse and with a minimal feeling of pain for the animal. When pressing the tool, the skin part to be pierced is also tensioned, so that the needle experiences minimal resistance both during insertion and extraction. It is further ensured that the needle hits the skin while flying, that is to say at a certain speed. The additional, hand-independent power source for performing the needle movements can, for example, be a pre-tensioned spring or a gas pressure cartridge, but it is also possible to use electric energy or a compressed air system.

The tool according to the invention can be loaded with a magazine with one or more implants, which, as described in an earlier applicant's application, is located in front of the tip of the injection needle, so that it must move through the magazine, on its way implant. An advantage of such a device is that, when piercing the magazine, the needle entrains internally and externally part of the disinfectant liquid present in the magazine, so that wound infections are prevented.

An exemplary embodiment of the invention will be described with reference to Figure 1, in which the additional, hand-independent power source consists of a pretensioned spring.

The tubular part 1 is provided with a pistol grip 2 with trigger 3 therein. A channel 4 is located at the front of the tubular part 1. In this channel 4 there can be a magazine 5, in which one or more implants 6 are located, by means of of an attachment device, not shown, move stepwise in the direction of the arrow.

The implants 6 are accommodated in cavities 7 which are closed on the open sides by, for example, sea foil 8. In the cavities 7, in addition to an implant 6, there can also be an amount of disinfecting liquid or paste.

Inside tube 1 is slide 9, which can move in slots 10 in the axis direction. A pretensioned spring 11 attempts to move the carriage to the left, but the latter is held back by the spring-loaded catch 12. Spring 11 can be operated with manual force. can be tensioned via hand button 13. Ratchet 12 can be moved via trigger 3, which revolves around pin 14 and the stroke of which is determined by the space which pin 15 has in hole 16.

In the drawn condition, trigger 3 is blocked by latch 17, which transitions to the front of the implant tool into nose 1. The latch is held to the left by spring 20. Only when the implant tool with nose 18 is pressed into the implant site (thereby at the same time tensioning the skin on the spot), the bolt 17 is moved to the right and cam 21 stands for hole 22 of tractor 3. Tractor 3 can now be pulled over, so that slide 9 can be released via pawl 12, which then moves under the action of spring 11 will move to the left. The slider 9 takes along this needle 26 via the springs 23, the cams 24 and the pressure piece 25, in which injection needle 26 is detachably attached, which penetrates into the body to be implanted with the tip. At the start of the needle stroke, it was already in one of the magazine cavities 7 and included an implant 6. In the left-going implantation movement, the implant is carried under the force of the push pin 27 attached to slide 9. Needle 26 now has the correct penetration depth (dotted), the bent-up parts 28 of springs 23 are spread by parts 29. The cams 24 release thrust piece 25, which shoots to the right under the action of spring 30, thereby pulling needle 26 out of the body to be implanted again. . The end of the return stroke of gland 25 is determined by buffer 31, which abuts against bent part 32 of slide 33.

Slide 9 is received at the end of its stroke to the left by buffers 34. The situation is now such that the needle 26 has returned to the drawn position and slide 9 to the left rests against buffer 34.

The implantation operation has now ended and has taken place in a very short time. It should also be noted that the piercing of the skin is facilitated not only by tightening the skin with nose 18, but moreover by the fact that the needle tip in the drawn, prestressed condition still has some distance 19 from the skin . Thus, during implantation, the needle tip strikes the skin at a certain speed, in addition to the force of spring 11, also the mass of slide 9 with all the associated parts (23, 24, 25, 26, 27) for an impulse-like penetration of the often provides relatively tough skin.

The preparation of the tool for a subsequent implantation now takes place by moving the slide 9 with the hand button 13 to the right against the force of the spring 11, until the slide 9 hits the bottom 35 of tube 1. In this movement, needle 26 is withdrawn from the implant cavity 7 and thereafter is released even further from the implant magazine, during which additional stroke the magazine is conveyed in one increment in a manner not shown.

The next implant cavity is now in front of the needle tip. By now moving the hand button to the left again, the slide 9 moves along and the needle 26 pierces the first sealing foil 8 of magazine 5 and takes up a new implant 6. The needle does not yet pierce the second sealing foil 8, because catch 12 retains slide 9 via cam 36 before this moment.

The implantation tool is now ready for the next implantation. It may also be noted that trigger 3 remains blocked for safety reasons until nose 18 is pressed onto the implant site.

It will be clear that spring 11 can be replaced in a known manner by other power sources, such as gas pressure or electricity. The recoil mechanism can also be solved in other ways, but this does not affect the essence of the invention.

Claims (8)

Tool for implanting a generally cylindrical object, a so-called implant, via a hypodermic needle, into a living object, for example containing a medicinal preparation or an electronic circuit for remote detection, characterized in that the implanting needle, which is designed as a hollow tube, is a hand-independent power source, which is unleashed by a trigger mechanism, is quickly driven in and then, after reaching depth, is automatically retracted again quickly, leaving the implant in the body, kept at the correct depth by a the tool provided with a pressure pin. Implanting tool according to claim 1, characterized in that the implanting needle already has a certain speed when it touches the skin during the upward stroke. Implanting tool according to claims 1 and 2, characterized in that an annular nose piece is arranged, which tightens the skin of the implant site and which is simultaneously coupled with a safety latch which prevents the tool from being operated without that it is pressed on the skin. Implanting tool according to one or more of the preceding claims, characterized in that an incrementally transportable magazine with objects to be implanted is located in front of the tip of the implanting needle, so that it must first pierce the magazine before penetrating into the place to be implanted. and take an implant with you, possibly with a disinfectant. Implantation tool according to one or more of the preceding claims, characterized in that the hand-independent power source is other than a tensioned spring. Implantation tool according to claim 5, characterized in that the hand-independent power source consists of a gas pressure cartridge. Implanting tool according to claim 5, characterized in that the hand-independent power source obtains its energy from an existing compressed air network. Implanting tool according to claim 5, characterized in that the hand-independent power source derives its energy from an electricity source, for instance from a possibly rechargeable battery or via a cable from the mains.