EP1171401A1

EP1171401A1 - Medical instruments

Info

Publication number: EP1171401A1
Application number: EP00920688A
Authority: EP
Inventors: Ralf-Peter Franke; Michael Fripan; Wolfgang Burger; Herbert Richter
Original assignee: Ceramtec GmbH
Current assignee: Ceramtec GmbH
Priority date: 1999-04-11
Filing date: 2000-04-11
Publication date: 2002-01-16
Also published as: AU4117400A; US20070276389A1; DE10017952A1; WO2000061517A1

Abstract

The present invention relates to the use of biocompatible and bioinert materials for producing medical/surgical instruments. The invention also relates to medical/surgical instruments made of biocompatible and bioinert materials. The invention further relates to tools made of biocompatible and bioinert materials for the use as medical/surgical instruments. The invention also relates to the use of tools made of biocompatible and bioinert materials in surgery.

Description

Medical instruments

The present invention relates to medical instruments, processes for their production and their use.

Recent studies on patients with implants / prostheses have shown that traces of iron could be detected in the periprosthetic tissue. This finding is surprising in that iron could also be detected when implants / prostheses made of absolutely iron-free materials were used and the explants of the implants / prostheses and the analysis of the periprosthetic tissue had been carried out using iron-free examination instruments. Even with explants made of absolutely iron-free materials, for example also with titanium prostheses, iron of up to 1 mg / g tissue could be detected in such examinations in the periprosthetic tissue.

The induction effect of iron, for example on fibroblasts, is known. About 30% of the so-called alternate operations are mainly required due to particles in the periprosthetic tissue, which are responsible for the loosening of the implants / prostheses ("particle disease"). Iron, on the one hand, an essential element for the organism, on the other hand, exercises in the vicinity of implants / Prostheses obviously have massive adverse effects, for example on the ingrowth behavior of osteosynthesis plates, implants, prostheses, screws, etc.

Due to the results obtained through the special examination method - using absolutely iron-free instruments - the iron detected in the periprosthetic tissue of iron-free implants / prostheses must therefore have been introduced during the operation.

Many surgical techniques in orthopedics or surgery involve the use of scalpels, scissors, saws, drills, taps, centering tools, drill sleeves, templates and similar instruments made of ferrous materials. Reference is made here, for example, to the article "Semiconstrained Total Elbow Replacement for the Treatment of Post-Traumatic Osteoarthrosis" by AG Schneeberger et al., The Journal of Bone and Joint Surgery, Vol. 79-A, No. 8, August 1997 , P. 1211 ff. Surprisingly, examinations of these instruments clearly showed clear signs of wear after their use in many cases. Wear that is caused by abrasion of the ferrous material and is partially visible to the naked eye. This iron-containing abrasion that occurs during the operation obviously accumulates in the periprosthetic tissue and can therefore be made at least partly responsible for the loosening of the prostheses.

The present invention has therefore set itself the goal of safely avoiding iron abrasion during operations.

An object of the present invention was therefore to provide tools and instruments which do not cause iron abrasion in surgery, when used in operations, for example when working on bones, when inserting implants, in order to thereby prevent osteolytically active iron in the tissue.

The object on which the present invention is based was achieved according to the invention by the use of biocompatible bio-inert materials for the production of medical / surgical instruments or by the use of the medical / surgical instruments made from biocompatible bio-inert materials during operations.

According to the invention, medical / surgical instruments made of bio-compatible bio-inert materials are provided.

The use of biocompatible bio-inert materials is of crucial importance for the solution according to the invention. Such bio-compatible bio-inert materials preferably include ceramics. Examples include high-strength technical ceramics, such as those based on aluminum oxide, zirconium oxide or silicon nitride. So-called Y-TZP ceramics or ZPTA ceramics are particularly preferred. ZPTA ceramics consist of a matrix material, which consists of an aluminum oxide / chromium oxide mixed crystal and is platelet-reinforced “in situ”. Such ceramics are described, for example, in EPA O 542 815. This is a ceramic in which one zirconium dioxide containing stabilizing oxides is incorporated from a matrix material of an aluminum oxide / chromium oxide mixed crystal of a sintered molded body, the amount of stabilizing oxides added being selected such that the zirconium dioxide is predominantly tetragonal that she are bio-compatible and bio-inert. Such ceramics have long been known in medical technology. They include the ceramics from which implants are made, for example, and which are sold by the applicant under the names Biolox ^® and Ziolox ^® .

These high-strength technical ceramics can be used, for example, to produce scalpels, scissors, saws, drills, taps, centering tools, drill bushes, templates and similar instruments.

The ceramics required for these instruments are produced in a manner known per se to the person skilled in the art. It should be noted, however, that the ceramics required for these instruments for use in medicine or surgery according to the invention should be sharp-edged and have no phase, as when using ceramics as a tool for machining metal.

A drill according to the invention is obtained, for example, by first producing a cylinder, for example from a ceramic according to EPA 0 542 815, into which the contour required for use as a cutting instrument is then ground. Figure 1 shows drills made in this way. It is also possible to manufacture a ceramic close to the final shape by injection molding or by the so-called DCC process, which is then reworked accordingly. In the DCC process, the green body is made directly from the suspension. For this purpose, the ceramic mixture with a solids content of more than 50% by volume is ground in an aqueous suspension. The pH of the mixture should be adjusted to 4 - 4.5. After grinding, urea and a quantity of the enzyme urease, which is suitable for breaking down the urea, are added before this suspension is poured into a mold. Due to the enzyme-catalyzed urea decomposition, the pH of the suspension shifts to 9, the suspension coagulating. The green body produced in this way is dried and sintered after removal from the mold. The sintering process can be carried out without pressure, but pre-sintering, followed by subsequent hot isostatic post-compression, is also possible. Further details on this method (DCC method) are disclosed in WO 94/02429 and in WO 94/24064, to which express reference is made.

A scalpel according to the invention or a pair of scissors according to the invention can in principle also be obtained according to DE 43 13 305, the Cutting blades of the scissors according to the invention can have both different and the same hardness.

According to the invention it is also possible to coat known medical / surgical instruments with bio-compatible bio-inert materials.

In all cases it applies that the appearance, the shape, the geometry, the size of the medical / surgical instruments according to the invention can correspond to the medical / surgical instruments previously used.

The inventive use of biocompatible bio-inert materials for the production of medical / surgical instruments or the use of the instruments / tools consisting of biocompatible bio-inert materials during operations makes it possible for the first time to reliably avoid the introduction of iron-containing particles into the tissue. The medical / surgical instruments according to the invention can thus be used, for example, to avoid operation-related osteolytic iron-containing abrasion particles when processing bones.

The medical / surgical instruments according to the invention have extremely high wear resistance and correspondingly high mechanical properties. It is also advantageous that the cutting characteristic of the medical / surgical instruments according to the invention is significantly better than the cutting characteristic of conventional instruments of the same geometry. Figure 2 shows the comparison between a conventional drill made of metal and a drill according to the invention made of bio-compatible bio-inert ceramic when used in the bone. One reason for this is the surface of the ceramics used according to the invention. While it is known to be with conventional medical / surgical instruments

Wettability problems arise when cutting fatty tissue - fatty tissue makes conventional scalpels blunt, a reason why scalpels are now used as disposable instruments - this problem does not occur with the medical / surgical instruments according to the invention.

Due to the better cutting characteristics of the medical / surgical instruments according to the invention, improved performance can generally also be assumed. Table 1 and Figure 3 show the comparison of two drills according to the invention with a conventional drill of the same geometry made of metal when used in the bone.

Of particular, especially economic importance is the possibility of being able to use the medical / surgical instruments according to the invention several times. Conventional metal instruments can and are usually used only once. Because of the surface chemistry, the medical / surgical instruments according to the invention can be easily re-sterilized even after their use; Even if the medical / surgical instruments according to the invention are autoclaved, they are superior in their performance to conventional instruments (cf. FIG. 3).

Of particular advantage is the use of the medical / surgical instruments according to the invention with regard to new surgical techniques such as the so-called "roboting" or the so-called "imaging". For example, the use of magnetic resonance imaging in the operating room requires the use of non-metallic instruments. While magnetic instruments are imaged out of focus in magnetic resonance imaging, the medical / surgical instruments according to the invention are imaged with sharp contours.

If medical / surgical instruments are used in connection with this invention, then instruments and tools are to be understood, which at least partially consist of bio-compatible bio-inert materials and are used in medicine / surgery and for the same purpose as the medical / surgical instruments should serve.

Table 1

*) with protein-dissolving detergent

Claims

claims

1. Medical / surgical instrument made of bio-compatible bio-inert material.

2. Medical / surgical instrument, characterized in that it is coated with bio-compatible bio-inert material.

3. Medical / surgical instrument according to claim 1 or 2, characterized in that the biocompatible bio-inert material is high-strength technical ceramic.

4. Medical / surgical instrument according to claim 1 or 2, characterized in that the bio-compatible bio-inert material on a ceramic

Alumina, zirconia or silicon nitride base.

5. Medical / surgical instrument according to claim 1 or 2, characterized in that the biocompatible bio-inert material is a Y-TZP or ZTPA ceramic.

6. Medical / surgical instrument according to one or more of claims 1 to 5, characterized in that it is designed as a scalpel, scissors, saw, drill, tap, centering tool, drill sleeve or as a template.

7. Use of a bio-compatible bio-inert material for the manufacture of medical / surgical instruments.

8. Use of a bio-compatible bio-inert material for the production of medical / surgical instruments, characterized in that the bio-compatible bio-inert material is a high-strength technical ceramic.

9. Use of a bio-compatible bio-inert material for the production of medical / surgical instruments, characterized in that the bio-compatible bio-inert material is a ceramic based on aluminum oxide, zirconium oxide or silicon nitride.

10. Use of a bio-compatible bio-inert material for the production of medical / surgical instruments, characterized in that the bio-compatible bio-inert material is a Y-TZP or ZTPA ceramic.

1 1. Use of a bio-compatible bio-inert material for the production of medical / surgical instruments, characterized in that the bio-compatible bio-inert material is characterized according to one of claims 3 to 5 and the instrument as a scalpel, scissors, saw, drill, thread cutter, centering tool, drill sleeve or as a template is trained.

12. Use of a biocompatible bio-inert material for coating medical / surgical instruments.

13. Use of a bio-compatible bio-inert material for coating medical / surgical instruments, characterized in that the bio-compatible bio-inert material is a high-strength technical ceramic.

14. Use of a bio-compatible bio-inert material for coating medical / surgical instruments, characterized in that the bio-compatible bio-inert material is a ceramic on aluminum oxide,

Is based on zirconium oxide or silicon nitride.

15. Use of a bio-compatible bio-inert material for coating medical / surgical instruments, characterized in that the bio-compatible bio-inert material is a Y-TZP or ZTPA ceramic.

16. Use of a biocompatible bio-inert material for coating medical / surgical instruments, characterized in that the biocompatible bio-inert material is characterized according to one of claims 3 to 5 and the instrument as a scalpel, scissors, saw, drill, thread cutter, centering tool, drill sleeve or is designed as a template.

17. Use of a tool made of biocompatible bio-inert material in surgery.

18. Use of a tool made of bio-compatible bio-inert material for processing bones.

19. Use of a tool made of biocompatible bio-inert material for machining bones.

20. Use of a tool made of bio-compatible bio-inert material to avoid osteolytic abrasion particles.

21. Use of a tool made of bio-compatible bio-inert material according to one of claims 17 to 20, characterized in that the bio-compatible bio-inert material is characterized according to one of claims 3 to 5.

22. Use of a tool made of bio-compatible bio-inert material according to one of claims 17 to 20, characterized in that the bio-compatible bio-inert material is characterized according to one of claims 3 to 5 and the tool as a scalpel, scissors, saw, drill,

Thread cutter, centering tool, drill sleeve or is designed as a template.

23. Tool made of biocompatible bio-inert material for use as a medical / surgical instrument.

24. Tool according to claim 23, characterized in that the bio-compatible bio-inert material is high-strength technical ceramic.

25. Tool according to claim 23, characterized in that the biocompatible bio-inert material is a ceramic based on aluminum oxide, zirconium oxide or silicon nitride.

26. Tool according to claim 23, characterized in that the biocompatible bio-inert material is a Y-TZP or ZTPA ceramic.

27. Tool according to one of claims 23 to 26, characterized in that the tool is designed as a scalpel, scissors, saw, drill, tap, centering tool, drill sleeve or as a template.

28. Tool according to one of claims 23 to 27, characterized in that at least part of the surface consists of the biocompatible bio-inert material.

29. Use of a tool made of bio-compatible bio-inert material for "roboting" or "imaging".