DE19655239B4 - Transponder unit for implantation - Google Patents

Abstract

To produce a transponder for implantation, an ampoule (10) is prepared with an open end (12), and outer (14) and inner (13) wall, to be filled partially with a liquid material (18) such as a PVC adhesive which can be hardened by ultra-violet light. The electronic transponder (20) is inserted into the liquid (18) so that the transponder (20) is wholly shrouded by it (18). The liquid (18) is then set and hardened.

Description

This invention relates generally an improved method for producing an identification marker, which can be implanted in an animal and left in it. In particular is the identification marker or the identification mark an implantable electrical transponder that Tier contains identification information from an external Detector can be read.

An implantable electronic Transponder or responder who provides identification information about a Animal contains has significant utility in the biomedical field. To the Example allows a programmable and temperature sensing electronic Transponder when implanted in an animal, not just that positive identification of the animal, but also allows reproduction or reading the temperature of the animal.

One of the main requirements related with the manufacture of a transponder is the encapsulation of the IC circuit hybrid assembly and the antenna coil so that this critical components of the body fluid can be isolated once the transponder is inserted into the animal. The body fluid contains a salt component that, when used with the electronics of the transponder comes into contact, the electronics usually within twenty four hours after injection by corrosive action damaged and makes useless. The encapsulation process must also apply to the surrounding tissue on the Implantation site to be bio-compatible and not disadvantageous.

Current encapsulation procedures use a glass capsule. Glass is heated to a discrete one Dimension drawn and to a length cut with one end open and the other end sealed is what an ampoule gives. The IC circuit hybrid assembly and the antenna coil are placed inside the glass ampoule. If these components inserted into the glass ampoule, the open end of the glass ampoule is sealed. Procedures currently available for sealing the open end are limited to those that a glow-and-smoothing and / or laser technology use. These two procedures are very time consuming and very expensive as they are careful Tolerance control, special equipment and specially trained Require workers. Furthermore, laser technology is for one Workers potentially very dangerous and special rooms and controlled environments be set up to apply such procedures.

An additional problem with the known method for sealing the open end of the glass ampoule related, is the thermal shock that occurs during manufacturing as a result of using heat for sealing the open end of the glass ampoule in the sensitive IC circuit hybrid assembly and antenna coil occurs. A thermal shock can be life shorten the unit and / or destroy the unit during manufacture. To avoid this problem it is known to use partial adhesive to the components attach inside the ampoule before the open end of the ampoule is sealed.

The currently available sealing methods of the open end prevent a full second or secondary seal of these critical components within the ampoule through use of glue. One for gluing the electronic components useful material within the ampoule to create a secondary seal (Klebstoffeinkapselungs insulating substrate) can only partially fill the ampoule, since the adhesive must be kept away from the ampoule end so that the ampoule can be sealed. If adhesive is allowed near the end of the ampoule the adhesive will contaminate the glass walls, causing a Burning the glue during which leads to heat treatment, what a complete Sealing prevents or in certain cases destroys the entire transponder assembly. This Inability, with the glue or glue by filling the ampoule a second Forming a seal that completely covers the transponder makes the internal electronic components due to excessive vibration during shipping and damage through body fluid for one early Failure prone, if the glass ampoule breaks or breaks when it is inside the Host animal is placed.

An additional problem with the known sealing methods is that the ampoules length longer have to be, around the additional glass wall material Provide that is heated to invade itself to effect what a glass ball or Cap closure of the Generated ampoule end. this leads to that the final Installation of the glass longer takes as necessary and has a major disadvantage if the transponder has to be placed in animals of any kind.

Furthermore, when currently known sealing methods are used, pores or bubbles on the order of microns remain in the sealed end of the ampoule. These pores or bubbles are extremely difficult to identify because of the size of the transponder. If these unwanted pores remain, the body fluid will leak into the electronic assembly of the transponder and cause damage to it. Since the heating of the glass depends directly on the wall thickness, cold forming or welding results SEN. During shipping, the ball or cap end of the ampoule breaks off and the product is useless for the intended application.

A new transponder module is accordingly and a new method of manufacturing a transponder assembly he wishes, which protects the components within the glass ampoule in order to overcome the disadvantages of the prior art.

Accordingly, it is an object of the present invention to an improved method of manufacturing a transponder create.

Another object of the invention is in creating an improved transponder assembly where the transponder components in the use of body fluids and the like are isolated.

This goal is achieved through the claims 1 and 7 specified procedures reached.

The new transponder module and the new method of manufacturing a transponder assembly, the protects the components inside the glass ampoule, comes without use from heat and overcomes the disadvantages of the prior art.

A method of forming a Contains markers the step of providing a glass ampoule. The glass ampoule is up to a predetermined volume that is at least the volume corresponds in which the unfilled Volume of the ampoule equal to the displacement volume of an IC hybrid chip and an antenna ("transponder components"), with one quick drying or curing liquid filled. The transponder components are placed in the ampoule so that they are completely from of the drying or vulcanizing liquid. It becomes sufficiently hardenable liquid Material filled into the ampoule, so it's over overflow the open end can and the outer wall the vial is at least partially covered at the open end if the electronic transponder is inserted into the ampoule. hereby is achieved when hardening between the cap and the wall of the ampoule curable Materials connect the cap to that before hardening the ampoule has been placed with the ampoule. By the drying that's a curing or vulcanization can be an improved transponder created that has an anti-migration cap without pores and in which the Transponder components are safely included.

According to the invention, a method for Making a transponder created without using Heat gets along.

The method also leads to production a transponder according to the invention to create a more stable Transponder.

The dependent claims concern further preferred and advantageous designs.

Other objects and advantages of the invention are partly obvious and partly based in particular recognizable from the description.

The invention accordingly includes the various Steps and the relationship of one or more such steps to each other, the device, the characteristics of the construction, combination and arrangement of parts embodied, and the object, the characteristics, properties and relationship of elements as it does everything in the below Disclosure is exemplified, and the scope of the invention is in the claims specified.

For a fuller understanding of the Invention is based on the following description in connection with the accompanying drawing, in which:

1 3 is a perspective view showing an ampoule used in accordance with the invention;

2 FIG. 4 is an exploded perspective view of the invention showing the hybrid IC chip and antenna just prior to insertion into an ampoule, illustrating a step in accordance with the method of the invention;

3 FIG. 4 is an exploded perspective view of the cap and ampoule, illustrating another step in accordance with the method of the invention,

4 Figure 3 is a perspective view of a transponder constructed in accordance with the invention, and

5 a sectional view taken along the line 5-5 in the 4 is.

According to the preferred embodiments of the invention, one is described with reference to FIG 1 to 5 Described improved construction method of an improved identification mark or identifier, which is designed to be implanted in an animal.

The 1 generally shows a bio-compatible glass ampoule 10 that have a fully sealed end 11 and an open end 12 Has. Annealing-and-smoothing methods known in the art can be used to create a sealed end 11 and the open end 12 easily smoothed by annealing to remove any sharp edges left by the cutting process used to make the glass ampoule 10 is used. The glass ampoule 10 has an outer wall 14 and an inner wall 13 ,

The 2 describes the next step of assembly, which is filling the glass ampoule 10 with a fast-curing liquid. at An exemplary version is a bio-compatible, UV-curable material 18 in a liquid state to a predetermined level 19 filled. The predetermined level is selected so that when a transponder unit 20 into the glass ampoule 10 is introduced, UV-curable material 18 is displaced and the ampoule 10 completely fills and the transponder unit 20 completely surrounds. Such a UV curable material 18 is a UV-curable polyvinyl chloride adhesive or binding adhesive, for example because of its suitability for animal use, such as the USP class 6 Medicine quality. However, other fast curing or drying materials can also be used for non-biomedical uses.

The transponder unit 20 can be from an IC circuit hybrid assembly 15 and an antenna coil 16 consist. Furthermore, the transponder unit 20 in addition to containing identification information, be programmed to collect physiological data relating to the animal. For example, a transponder that is programmable and senses or detects temperatures can be used to maintain the temperature of the animal.

As in 3 is shown, surrounds the UV-curable material 18 after the transponder unit 20 inside the glass ampoule 10 is placed, the transponder unit 20 completely and fills the glass ampoule 10 completely on, and an anti-migration cap 22 is about the open end 12 the glass ampoule 10 set. The use of an anti-migration cap to aid in holding the transponder in a cannula and / or to prevent migration or migration of the transponder from an animal after injection or implantation is disclosed in U.S. Patent No. US 55,074,318 A detailed which patent is incorporated herein by reference as if it were fully reproduced herein. One version is the UV-curable material 18 excessive in the glass ampoule 10 filled and runs on the outer wall 14 down when the transponder unit 20 in the glass ampoule 10 is placed, which results in UV curable material 18 on the outer wall 14 the glass ampoule 10 is available. Accordingly, if the cap 22 on the ampoule 10 is placed, the UV curable material will be located between the cap and the ampoule and will act as an adhesive that secures or secures the cap to the ampoule when the UV material is dried or cured.

The anti-migration cap 22 will once over the glass ampoule 10 about half of the glass ampoule 10 cover. The anti-migration cap 22 is used to prevent the marker from slipping out of the animal when the marker is implanted or implanted in the animal. The anti-migration cap 22 consists of a material that has a high coefficient of friction. The anti-migration cap is preferably made of a bio-compatible material. For example, the anti-migration cap 22 by injecting medical grade polypropylene into a mold cavity. A further description of the anti-migration cap, as well as advantages provided by such a device, is given in U.S. Patent No. US 5,074,318 A specified.

After the anti-migration cap 22 on the glass ampoule 10 this unit is then UV-irradiated for a few seconds. As a result of the radiation, the UV-curable material goes 18 in the glass ampoule 10 into a solid mass, and the UV curable material 18 that over the glass ampoule 10 overflowed and in the space between the inner wall 33 the anti-migration cap 22 and the outer wall 14 the glass ampoule 10 is locked, also solidifies, which leads to the anti-migration cap 22 permanently with the glass wall 14 connected is.

If hardenable material 18 Dried or vulcanized to a hardened state, the result is a solid transponder that has a glass housing or glass capsule, with the circuit and antenna within the now solid and hardened material 18 run and are protected, as in the 4 and 5 is shown. The resulting transponder contains an outer glass layer 10 , a solid protective layer 18 , a circuit 15 and an antenna 16 , The cap 22 acts as a partial coating on the glass ampoule 10 ,

In an alternative version, the anti-migration cap 22 projections 29 included to further prevent migration or migration. projections 29 are useful when the marker or marker in the form of an implantable transponder is fully assembled and ready to be inserted into an animal. Typically, the implantable transponder is inserted or inserted into an animal using an implantation device, which is also disclosed in U.S. Patent No. US 5,074,318 A is described. projections 29 are used to interact with animal tissue after injection to prevent the marker from migrating.

When the implantable transponder is used for mouse studies or for pets, the dimensions of the glass ampoule are as follows: outer diameter 2.12 ± 0.03 mm, inner diameter 1.75 ± 0.03 mm and length 13.20 ± 0.3 mm. In such a case it is preferred that the transponder 20 if he is inside the glass ampoule 10 is located 0.02 mm below the open end 12 the glass ampoule 10 is arranged.

The marker thus produced is characterized by several clear advantages over the implantable transponders, according to the methods currently available in the art getting produced.

For example, the anti-migration cap provides funds ready to have a smooth radius at the flat end of the glass ampoule to create. Furthermore, the anti-migration device is not a sliding fit more on the glass, but is now permanently connected to the glass wall, and it is unlikely that they while of shipping or use accidentally slips down.

This also eliminates this The method disclosed the need to open the glass ampoule using glow-and-smoothing or Seal laser methodology. This elimination leads to significant cost savings, because special equipment and specially trained workers who are required for these procedures are no longer needed become.

The thermal shock on the transponder unit is also eliminated since no heat is required to to seal the open end of the ampoule. The possibilities of pores or Bubbles that could form if the open end of the ampoule is by the annealing-and-smoothing or laser method is also eliminated.

The secondary seal created by the UV hardened material created with the transponder unit also works for isolation the electronics of the body fluid, even if the glass ampoule during use in an animal jumps or breaks so the damage, which can arise with electronics, is insignificant.

In addition, the complete encapsulation makes the IC hybrid circuit and antenna coil assembly make them very stable. This improves the suitability for programming and calibrate, essential because of the very small mass of the device very vulnerable for and sensitive to changes in Is air or water temperature. By completely accommodating the transponder assembly inside the UV-cured Materials will have greater stability throughout Device created, whereby a monolithic mass is produced will that the required execution the programmable device much faster and the calibration for time and Accuracy steps make it immensely better.

The secondary seal also protects the electronics from vibrations or shocks that occur during the Shipping occurs what the survival rate of the units shipped significantly improved.

Finally, if this method is used will, the length the glass ampoule be shorter, than when conventional Methods are used because the need to open the end of the Ampoule using a glow-and-smoothing or laser process, is eliminated.

In summary, the invention provides in one embodiment an improved identification marker and a method for producing the marker, which in one embodiment contains the steps of a glass ampoule ( 10 ) and the glass ampoule ( 10 ) with a fast curing liquid ( 18 ) to a predetermined volume that corresponds at least to the volume at which the unfilled volume of the ampoule ( 10 ) equal to the displacement of an IC hybrid circuit ( 15 ) and one ( 16 ) Antenna is. The hybrid IC circuit ( 15 ) and the ( 16 ) Antenna are in the ampoule ( 10 ) arranged so that it is completely free from the liquid ( 18 ) are surrounded. A cap ( 22 ) is on the ampoule ( 10 ) set, and the liquid ( 18 ) is hardened or generally dried. The cap is preferably an anti-migration cap ( 22 ) so that when the transponder ( 20 ) is implanted in an animal, the transponder ( 20 ) prevents it from slipping out.

It can thus be seen that the above stated objectives among those based on the previous description have been clarified, can be achieved effectively, and as certain changes when running of the above procedure (process) and on the specified subject can be made without departing from the character and scope of the invention, it is intended that everything what is included in the description above and in the accompanying Drawing is shown as illustrative and not in a limiting Meaning should be interpreted.

It is also understandable that is intended that the following claims all general and specific features of the invention described herein and all indications of the scope of the invention, as a linguistic Matter could be described as intervening.

Claims (7)

A method of making an identification marker formed from an ampoule, the method comprising the steps of: providing an ampoule with an open end and having an outer wall and an inner wall, partially filling the ampoule with a predetermined volume of a biocompatible ultraviolet-curable material in a liquid state, inserting an electronic transponder into the ampoule containing the curable material, the insertion of the electronic transponder causing the curable material to completely surround the transponder, curing the ultraviolet curable material, attaching a cap over the open end of the ampoule prior to curing the curable material, and ensuring that the curable liquid material fills the ampoule sufficiently that the curable liquid material overflows over the open end and at least partially covers the outer wall of the ampoule at the open end when the electronic transponder is inserted into the ampoule so that the hardening of the curable liquid material located between the cap and the outer wall of the ampoule causes the cap to bond to the ampoule. Method according to claim 1, the curable Material a UV curable Material and the ampoule is a glass ampoule and still the Included is the glass ampoule with one on the open Cap arranged end of the glass ampoule for a sufficient period of time exposed to UV radiation in order to solidify the UV-curable material. Method according to claim 1, the predetermined volume being greater than the volume of the ampoule less of the displacement volume of the transponder. Method according to claim 2, the cap being an anti-migration cap that is smooth Radius deploys when on top of the open end of the glass ampoule is arranged. Method according to claim 1, wherein the transponder is an IC circuit hybrid assembly and Contains antenna coil. A method according to claim 1, characterized in that the curable Material made from a UV curable Polyvenyl chloride adhesive exists. A method according to any of claims 1-6, wherein the ampoule and the Cap made of bio-compatible material.