WO2003055397A1

WO2003055397A1 - Method and device for sectioning tissue by means of a jet

Info

Publication number: WO2003055397A1
Application number: PCT/DE2002/004671
Authority: WO
Inventors: Carl Joachim Wirth; Henning Windhagen; Stephan Schmolke; Frank Witte; Ludger Kirsch; Friedrich-Wilhelm Bach; Hartmut Louis; Frank Pude; Volker Kaese; Peter Wilk
Original assignee: Universität Hannover; Medizinische Hochschule Hannover
Priority date: 2001-12-28
Filing date: 2002-12-19
Publication date: 2003-07-10
Also published as: DE10164024A1; EP1460949A1; AU2002363837A1

Abstract

The invention relates to a method and a device (1) for sectioning human or animal body tissue (2), in particular osseous tissue, using a jet of liquid. To increase the removal capacity, an abrasive agent (5) that is compatible with the body and at the same time pharmacologically acceptable is added to the jet of liquid. The use of an abrasive agent (5) containing substantially biodegradable components, which dissolve in the body by means of a corrosion process, allows a high degree of material removal to be achieved with a high degree of compatibility with the body, irrespective of the solubility of the abrasive agent (5) in the liquid (3). The residue of the abrasive agent (5) in the body tissue (2) is thus harmless.

Description

Method and device for jet cutting tissue

The invention relates to a method for jet cutting human or animal tissue, in particular bone tissue, by means of a fluid jet, to which a body-compatible and at the same time pharmacologically acceptable abrasive is added to increase the removal rate. The invention further relates to a device for carrying out the method and an abrasive intended for use in the method.

Such a method for removing an implant or a prosthesis from bone tissue is known, for example, from DE 198 04 065, by means of which a substantial part of the bone cement can be removed with the aid of a high-pressure liquid jet and a water-soluble abrasive. As a result, the implant can be removed with only a small amount of force and is therefore gentle on the tissue. The comparatively thin fluid jet is ideally suited for this purpose, because it enables a large depth of cut to be achieved with little loss of substance. Corresponding to the different material properties of the bone tissue on the one hand and the bone cement on the other hand, the parameters of the liquid jet can be adjusted by supplying a suitable abrasive in such a way that damage to the bone tissue is excluded in any case. Therefore, incorrect operation, which could lead to injury to the patient, is also ruled out with manual guidance.

It is also known to set the parameters of the fluid jet in such a way that the fluid jet selectively only cuts through parenchymatous organs such as the liver or the kidney while the firmer vessels are preserved and can be ligated by the surgeon safely and with little blood loss. Other areas of application are, albeit to a much smaller extent, in neurosurgery.

When selecting such abrasives for jet cutting when processing biological tissue, it must be ensured, however, that the abrasive used is at the same time tolerable to the body and pharmacologically harmless. Only those abrasives are used that dissolve as quickly and residue-free as possible in order to avoid an undesirable abrasive effect in the tissue. Therefore, water-soluble substances are used in practice. So far, fine crystalline sugar has been used as a biocompatible abrasive in experimental investigations. Sugar is pharmacologically inert and remains crystalline due to the extremely short dwell time in the fluid jet until it hits the tissue.

A device for separating a biological structure is also known from DE 42 00 976 C2, which allows the surgeon to make a sensitive and reproducible setting of the fluid pressure by appropriate arrangement of the components. In a method known from DE 693 24 117 T2 for treating bone tissue, the fluid is introduced into the bone tissue in a supercritical state. Simply bringing the bone tissue into contact with the supercritical fluid is intended to increase its mechanical strength even during the extraction of the organic matter.

Furthermore, DE 198 43 683 A1 discloses a partially metallic abrasive which contains particles from industrial sludges, for example grinding sludge or rolled and forged scale, and a process for the production thereof by deoiling and drying these sludges. However, these slurries are not suitable for use in jet cutting of human or animal tissue, since residues of particles of the abrasive in the tissue create an increased risk of infection.

Based on these findings, the present invention has for its object to provide a way to further improve the use and application of jet cutting with abrasives. Furthermore, an apparatus for performing the method and a suitable abrasive are to be created. The first-mentioned object is achieved according to the invention with a method according to the features of patent claim 1. The subclaims relate to particularly expedient developments of the invention.

According to the invention, a method is therefore provided in which an abrasive consisting of essentially biodegradable constituents is used. By using such self-dissolving substances as an abrasive, a high material removal with a high degree of body tolerance can be achieved regardless of the solubility of the abrasive in the fluid. The abrasive remains in the tissue harmless. The use and handling of the abrasives is considerably simplified because the dissolving process is not in the fluid, but by a corrosion process and is therefore delayed.

A particularly advantageous embodiment of the invention is achieved in that a magnesium alloy is used as the abrasive. Due to its essential character, it is ideally suited as an abrasive agent for bodily functions and flushing out overdoses via the urinary tract. Furthermore, the magnesium introduced into the body can increase the strength of the tooth enamel and the trabeculae or the substitution of the calcium. Magnesium is also cardioprotective by being antiarrhythmic and lowering blood pressure. The magnesium corrodes in the body in saline immersion, so that the desired mechanical resilience, which is decisive for the removal performance, is achieved when hitting, for example, bone tissue with the optimal biodegradable property required at the same time.

The second task, a device for jet cutting body tissue, which works according to the known injector or the suspension jet principle, with a line element through the outlet opening of which a fluid jet, which contains an abrasive which increases the removal capacity, can be fed to the body tissue, for carrying out the To create a method is achieved according to the invention in that the line element has, at least in the region of the outlet opening, essentially biodegradable material components. As a result, during the removal of material, which is unavoidable in the operation of the fluid jet, only those components are introduced into the tissue whose biodegradable properties ensure a completely harmless temporary stay in the body until the corrosive dissolution process is complete. A damaging influence due to worn material components of the line element is thereby reliably avoided. For this purpose, the line element can also be provided with a corresponding coating, which may or may not be renewable Be provided stratification, which is optionally renewable or can be replaced together with an interchangeable component of the line element.

It is particularly advantageous if, when using the injector jet principle, the line element has a focusing tube which consists of a biodegradable metal, at least in the region of its inner wall. In practice, the focusing tube is subject to increased stress from the fluid jet and thus increased wear. A focusing tube consisting of the biodegradable metal, in particular in the area of the outlet opening, therefore prevents the entry of undesirable, in particular damaging, components into the human or animal body.

It proves to be particularly practical if the hardness or the abrasion resistance of the biodegradable material components of the line element is greater than that of the abrasive used, in order to minimize the wear of the line element, in particular of the focusing tube.

Furthermore, a further development of the invention proves to be particularly advantageous if the line element has a magnesium alloy as an essential material component, in order to obtain the desired, comparatively favorable surface quality with sufficient hardness and the desired biodegradability, in particular by optimal selection of the magnesium alloy.

The further mentioned task of creating a body-compatible and at the same time pharmacologically acceptable abrasive for use in jet cutting of human or animal tissue, in particular bone tissue, which is added to the fluid jet to increase the removal rate, is achieved according to the invention by a biodegradable metal as an essential material component reached. As a result, the removal or cutting performance of the fluid jet mixed with the abrasive agent can be significantly increased, in particular in comparison to the abrasive agent consisting of sugar crystals according to the prior art. Any material constituents of the abrasive remaining in the tissue are dissolved by a corrosion process, so that a risk of infection can be excluded.

A particularly promising embodiment is also achieved by using a magnesium alloy as an essential material component. In this way the good physical tolerance of the magnesium can be used. At the same time, the material properties problem-free adaptation to different material removal rates and operating conditions.

In this case, premature dissolution of the magnesium alloy in the fluid is avoided in a particularly advantageous manner by a composition of the magnesium alloy which is determined in accordance with the ratio of the dissolution rate in the fluid jet and the reaction kinetics in the tissue. As a result, the removal rate becomes largely independent of the residence time of the magnesium alloy in the fluid, as a result of which the use in practice can be considerably simplified.

Furthermore, it proves to be particularly expedient if the removal rate can be set independently of the fluid parameters by means of a composition of the magnesium alloy determined in accordance with the desired degree of hardness of the abrasive thus obtained. For example, this enables problem-free adaptation to soft tissue on the one hand and hard tissue, in particular bone tissue, on the other.

Another particularly advantageous embodiment of the abrasive according to the invention is achieved by a composition of the magnesium alloy which is determined in accordance with the desired surface condition of the abrasive thus obtained. The properties of the cutting edges are changed by the alloy components and can thus be adapted to the respective application, for example for removing or cutting the tissue in a manner that is gentle on the substance.

The invention permits various embodiments. To further clarify its basic principle, one of these is shown in the drawing and is described below. This is shown in a schematic diagram in

1 shows an inventive device for jet cutting according to the suspension jet principle;

2 shows a device for jet cutting according to the injector jet principle.

1 shows a schematic diagram of a device 1 according to the invention for jet cutting body tissue 2. For this purpose, a fluid 3 inside a pressure vessel 4 is supplied with a biodegradable abrasive 5 which contains a magnesium alloy as an essential material component. The fluid 3 is in operation by a line element 6 and an outlet opening 7 is directed onto the body tissue 2. At least in the area of the outlet opening 7, the line element 6 also has biodegradable material components, in order to prevent impairment due to the inevitable removal of these material components. In practice, the line element 6 can be made interchangeable or can be provided with a renewable coating.

In addition, FIG. 2 shows a device 8 for jet cutting according to the injector jet principle. In this case, the abrasive 5 is supplied to the fluid 3 only immediately before it exits through an outlet opening 9 of a focusing tube 10 of a line element 11, so that due to the short residence time in the fluid 3 before it hits the body tissue 2, a dissolution process does not occur or only in an extremely high degree to a small extent. When using the injector jet principle, soluble abrasives 5 can therefore also be used in particular.

Claims

claims

1. A method for jet cutting human or animal tissue, in particular bone tissue by means of a fluid jet, to which a body-compatible and at the same time pharmacologically acceptable abrasive is added to increase the removal rate, characterized in that an abrasive made from biodegradable constituents is used.

2. The method according to claim 1, characterized in that a magnesium alloy is used as the abrasive.

3.Device (1, 8) for jet cutting body tissue (2) with a line element (6, 11), through the outlet opening (7, 9) of which a fluid jet which contains an abrasive agent (5) which increases the removal capacity, the body tissue (2 ) can be supplied, characterized in that the line element (6, 11) has at least in the region of the outlet opening (7, 9) essentially biodegradable material components.

4. The device (8) according to claim 3, characterized in that the line element (11) has an at least in the region of its inner wall made of a biodegradable metal focusing tube (10).

5. Device (1, 8) according to claims 3 or 4, characterized in that the hardness or the abrasion resistance of the biodegradable material components of the line element (6, 11) is greater than that of the abrasive used (5).

6. The device (1) according to at least one of claims 3 to 5, characterized in that the line element (6, 11) has a magnesium alloy as an essential material component.

7. A body-compatible and at the same time pharmacologically acceptable abrasive for use in jet cutting of human or animal tissue, in particular bone tissue, which is added to the fluid jet to increase the removal rate, characterized by a biodegradable metal as an essential material component.

8. Abrasive according to claim 7, characterized by a magnesium alloy as an essential material component.

9. Abrasive according to claims 7 or 8, characterized by a composition of the magnesium alloy determined in accordance with the desired reaction kinetics in the tissue.

10. Abrasive according to at least one of claims 7 to 9, characterized by a composition of the magnesium alloy determined in accordance with the ratio of the dissolution rate in the fluid jet and the reaction kinetics in the tissue.

11. Abrasive according to at least one of claims 7 to 10, characterized by a composition of the magnesium alloy determined according to the desired degree of hardness of the abrasive thus obtained.

12. Abrasive according to at least one of claims 7 to 11, characterized by a composition of the magnesium alloy determined according to the desired surface condition of the abrasive thus obtained.