EP1299036A2

EP1299036A2 - Surgical device for the removal of tissue cells from a biological structure

Info

Publication number: EP1299036A2
Application number: EP01957706A
Authority: EP
Inventors: Andreas Pein
Original assignee: Andreas Pein Medizintechnik GmbH
Current assignee: TAUFIG Ahmmed Ziah
Priority date: 2000-07-07
Filing date: 2001-07-05
Publication date: 2003-04-09
Also published as: US20040092987A1; WO2002003866A3; CA2415129A1; DE10033278B4; CA2415129C; WO2002003866A2; DE10033278A1

Abstract

Fatty tissue is conventionally removed from the human body by disrupting the fatty tissue cells, by means of ultrasound and then being sucked out. The above damages the human body as other neighbouring tissue cells, such as blood cells, are also disrupted. A surgical device is thus disclosed, comprising a liquid jet device (1), with a particular operating hand piece (1). Said operating hand piece (1), comprises a capillary (3) for the emerging liquid jet and a capillary (4) for sucking out the separated tissue cells. The emerging liquid jet is formed in cross-section so as to give a sloughing effect.

Description

description

Surgical device for removing tissue cells from a biological structure

The invention relates to a surgical device for removing tissue cells from a biological structure according to the preamble of claim 1. Such instruments are used in surgical clinics.

The cell is the basic unit of living matter and essentially consists of one or more cell nuclei that are embedded in the cytoplasm and one

Cell membrane are enclosed. Several cells form a tissue in the most varied of ages in the association.

There are now frequent reasons for such tissue cells from a biological

Structure, such as the human body.

For health or cosmetic reasons, there must often be excess

Fat tissue can be taken from all possible parts of the body. Such

Withdrawal takes place either in an open operation or through a

Sonication. In practice, ultrasound treatment is usually used

Application in which an ultrasound probe and a suction cannula into the relevant

Adipose tissue to be inserted. With the help of those exiting in all directions

Ultrasonic waves destroy and destroy all adjacent fat cells

Suction canals removed.

This process has major disadvantages. So of course not only the affected fat cells are destroyed, but also all others in the effective range

Tissue cells, such as blood cells. This damages the human body and therefore complicates and extends the healing process. Another disadvantage It follows from this that such ultrasonic probes emit radiation on all sides and therefore cannot be used in a targeted manner. For example, it is not possible to work on border areas between the fat tissue to be extracted and an adjacent healthy tissue without damaging the healthy tissue.

It is also part of medical practice to remove vital tissue cells from a biological structure, for example the liver, in order to multiply them outside the human body by way of division and to subsequently return the tissue cells grown in this way to the relevant organ of a human body. Such vital tissue cells are removed either in an open operation or, as is the rule, endoscopically, in which a small group of tissue cells are mechanically separated and removed. But here too there is the disadvantage that healthy tissue cells are affected and damaged. This in turn damages and burdens the human organism.

The invention is therefore based on the object of developing a surgical device for removing tissue cells from a biological structure, with which tissue cells can be separated and removed undamaged.

This object is achieved by the characterizing features of claim 1. Further configuration options result from subclaims 2 to 8. The invention eliminates the disadvantages of the prior art mentioned. The particular advantage of the invention is that neither the tissue cells to be removed nor the adjacent and remaining tissue cells are damaged during the removal. On the one hand, this makes it possible to continue using the removed tissue cells, for example for an increase in the tissue cells carried out outside the human or animal body. This type of withdrawal but also protects all healthy tissue cells that remain in the body, because only the desired tissue cells are removed. For this purpose, it is expedient to design the liquid jet like a peeling knife or a scraper. This happens, for example, by means of a flat jet of liquid, or by means of a plurality of individual point-shaped individual jets which are arranged on a straight or even a curved line and thus form a closed and elongated jet of liquid again in association. However, it is also expedient for some possible applications to use only a punctiform or only a slightly flattened liquid jet and to swing this liquid jet in a pendulum-like manner over a certain area using technical movement elements or only by the operator's hand movements on a line. This also has the effect of a flat jet of liquid.

It is also advantageous if the more or less flat liquid jet extends transversely at a right angle to the suction lines located on an axial line, because this results in the shortest transport path of the removed tissue cells between the peeling edge of the liquid jet and the suction holes.

The invention will be explained in more detail using an exemplary embodiment. To show:

Fig. 1: the surgical handpiece of the surgical device with a round liquid jet and Fig. 2: the surgical handpiece with a flat liquid jet.

The structure of the surgical device for removing vital tissue cells from a biological structure largely corresponds to that of a liquid jet device for separating a biological structure. Such a separation device is generally mine known and need not be shown separately here. For example, a corresponding separation device is described in EP 0 551 920 B1. The surgical device for removing tissue cells from a biological structure thus essentially consists of a pressure generator, a piston-cylinder unit and a special surgical handpiece 1. In the cylinder space of the piston-cylinder unit, a cartridge is inserted in a form-fitting manner, which is fitted with a sterile Liquid is filled and which is connected to the surgical handpiece 1. In operation, the pressure medium of the pressure generator loads the cartridge, as a result of which the sterile liquid is pressed out of the cartridge and conveyed to the surgical handpiece 1, where it emerges under pressure in the form of a fine liquid jet. All device units of this high-pressure liquid jet device are designed and coordinated so that on the one hand a continuous sterile chain is guaranteed for the liquid and on the other hand the escaping liquid jet can intelligently process different biological structures with the highest precision.

According to FIGS. 1 and 2, the special surgical handpiece 1 consists of a handle gap (not shown) for the surgeon and a cannula 2 for insertion into the biological structure. Inside the cannula 2 is a capillary 3 for the emerging

Liquid jet and a capillary 4 for the suction of separated tissue cells and the used liquid.

The capillary 3 for supplying liquid is preferably arranged on the inside and coaxial with the cannula 2, and the capillary 4 for suctioning the tissue cells is designed as an annular channel encompassing the inside capillary 2. Alternatively, both capillaries 3 and 4 can of course also be arranged separately next to one another in the cannula 2.

The capillary 4 for suctioning the tissue cells has at the distal end of the cannula 2 a plurality of radial suction openings 5, which are arranged on two opposite axial lines at equal distances from one another. The diameter of the radial

Suction openings 5 are selected so that, on the one hand, the build-up of a suction force and, on the other hand, the passability of the separated tissue cells is made possible. The capillary 3 for the emerging liquid jet likewise opens at the distal end of the cannula 2 in a nozzle piece 6 which is rigidly connected to the cannula 2. The nozzle piece 6 is preferably screwed into the cannula 2. The nozzle piece 6 has an axially arranged nozzle opening 7, which is designed in a special way for a wide variety of applications.

For example, for the removal of adipose tissue cells, the nozzle opening 7 of the nozzle gap 6 according to FIG. 2 is designed to be flat in such a way that an emerging liquid jet with a strongly flattened cross section results. This flat liquid jet is oriented such that each of the two rows of radial suction openings 5 is at right angles to one of the two flattened long sides of the liquid cross section.

In contrast, the nozzle opening 7 of the nozzle piece 6 is designed, for example, for the removal of vital tissue cells from the liver according to FIG. 1 round or approximately round in such a way that a liquid jet with a round cross section, with a round cross section with a slight flattening or with an oval cross-section emerges. Here too, the radial suction openings 5 are arranged approximately at right angles to the existing flattenings of the liquid jet. The dashed outlet line 8 is intended to indicate that the emerging liquid jet can also emerge at a predetermined angle with respect to the central axis of the cannula 2 by a corresponding shape and arrangement of the nozzle opening 7 in the nozzle piece 6.

To remove adipose tissue cells, for example for cosmetic reasons, a minimal surgical incision is first made in the patient's abdominal wall and then the cannula 2 with the liquid jet already emerging under pressure is attached to this opening. The opening of the abdominal wall is pressed apart so far by the pressure of the emerging liquid jet that the cannula 2 of the

Surgical handpiece can be easily inserted under the abdominal wall into the area of the fatty tissue. With his free hand, the surgeon can feel the position of the cannula 2 and the direction and position of the flat liquid jet at the pressure emanating from the liquid jet outside the abdominal wall and correct or change it with the guide hand. The pressure of the liquid jet is regulated on site in such a way that the flat liquid jet emerges with a force which does not destroy the adipose tissue cells but only displaces it from the jet area. As a result, neighboring fat cells shift and stand out from one another, so that free spaces are formed between the fat cells, into which the liquid jet penetrates and there pushes apart the seams of the neighboring cell membranes that are still present. In this way, fat cells are peeled off from neighboring fat cells without being damaged. These effects can be enhanced by pulsing and moving the liquid jet. The Felt cell bundles thus lifted are then sucked off via the radial suction openings and the capillary 4 and collected separately.

To remove tissue cells, for example from the liver, the cannula 2 of the surgical handpiece 1 is only equipped with such a nozzle piece 6, which produces a round, or approximately round and punctiform liquid jet, and a lower pressure on the liquid jet is set on the surgical device. With this cannula 2 and with this pressure adjustment, the procedure is the same as for the removal of fat cells. As required, the punctiform liquid jet is moved sideways on a line to increase the peeling effect. The individual or smaller cell bundles are again suctioned off and then placed in a corresponding station for the purpose of cell multiplication. List of reference numbers

1 surgical handpiece

2 cannula

3 capillaries to supply liquid

4 capillaries for suctioning separated tissue cells

5 radial suction opening

6 nozzle piece

7 nozzle opening

8 dashed exit line

Claims

claims

1. Surgical device for removing tissue cells from a biological structure, characterized in that the surgical device is a liquid jet device consisting of a pressure generator, from a reservoir for the liquid to be pressurized by the pressure generator and from an operating handpiece () for the outlet of the pressurized liquid, the surgical handpiece (1) having a capillary (3) for the emerging liquid jet and a capillary (4) for the suction of separated tissue cells and the emerging liquid jet is designed in its cross-section so that a peeling effect occurs ,

2. Surgical device according to claim 1, characterized in that the cross section of the emerging liquid jet is non-circular.

3. Surgical device according to claim 2, characterized in that the cross section of the emerging liquid jet is flat.

4. Surgical device according to claim 3, characterized in that the cross section of the emerging liquid jet is formed from a plurality of individual radiators which have a round cross section and are arranged on a common straight or curved line.

5. Surgical device according to claim 1, characterized in that the emerging liquid jet has a round cross section and is deflected laterally to a limited extent via movement elements.

6. Surgical device according to claim 1, characterized in that the emerging liquid jet is directed at a pre-determined exit angle to the capillary (3).

7. Surgical device according to claim 1, characterized in that the capillary (4) is separated for the suction

Tissue cells within the operational handpiece (1) are designed as an annular channel and have radial suction openings (5) arranged on the circumference.

8. Surgical device according to claim 7, characterized in that the suction openings (5) are arranged on two opposite axial lines and are directed at right angles to the flat liquid jet.