WO1992007516A1 - Surgical instrument - Google Patents

Abstract

The invention concerns a surgical instrument, in particular a suction cutter for taking tissue samples, with a cutter mouth operated by means of a handle or similar device acting through at least one connecting rod or similar device. The connecting rod or similar device is connected to a drive unit (13). This drive unit (13) is an electric motor with clockwise/anti-clockwise transmission.

Description

 Surgical instrument

The invention relates to a surgical instrument, in particular a suction punch for taking tissue samples, with a scissor jaw, which can be actuated from a handle or the like by means of at least one push rod or the like.

A large number of surgical instruments have a scissor jaw so that, for example, a tissue sample can be taken from the human body or other surgical interventions, such as in particular separating cuts, can be carried out. All these surgical instruments are usually operated manually, with one or both elements of the scissor jaw being connected to scissor-like handles via a push rod, pull rope, wire rod or the like. Especially when a large number of tissue samples are to be taken, manual operation is tedious and exhausting. The cutting force to be applied also depends on the skills of the operator and is difficult to determine manually.

The present invention relates in particular to all clamping and cutting surgical instruments, such as scissors, punches, pliers, clamps, etc.

The present invention has for its object to provide a surgical instrument of the above. To develop a way in which cutting force and cutting sequence are automatically controlled.

To achieve this object, the push rod or the like is connected to a drive.

As a result, the operation of the surgical instrument is made independent of the skills of the operator, so that a multitude of cutting sequences can take place without the operator's strength waning. For this purpose, the drive, which is advantageously designed as an electric motor, has a right / left rotation. It should be designed so that the drive direction is changed at the push of a button, or that a change can be made continuously or after a predetermined time. Known electronic aids are used for this.

For controlling the cutting force, the drive has corresponding control devices which switch the drive off or on when a certain cutting force is exceeded. Of course, this is also possible by appropriate design of a gear assigned to the drive.

The drive should preferably have a drive shaft which transmits its rotation to the push rod by mechanical means. For example, corresponding spindle drives with a threaded spindle and ball screw drives or the like are conceivable here. However, a pinion is preferred, which sits on the drive shaft and engages with a corresponding toothing on the push rod. As a result, the rotational movement of the drive shaft is converted into a linear movement of the push rod.

As a rule, a motor with a relatively high speed will be preferred. A DC motor with 12,000 revolutions per minute was used in the test stage. To convert this high speed to a relatively slow movement of the push rod, a reduction gear is necessary. For example, a gearbox with a gear ratio of 2,000: 1 or 1,000: 1 is recommended. This also controls the cutting force. It is sufficient if the transmission can be switched over in individual stages. The entire regulation is carried out by appropriate control electronics.

In the case of the transmission of the rotary movement of a drive shaft to a linear movement of the push rod, it is advisable for the drive shaft to run transversely to the push rod or its toothing. The toothing, which is in engagement with the toothed pinion, can either be molded into the push rod itself or a sleeve, which is then placed on the push rod. There should be no limit to the invention here.

For a more compact design of the surgical instrument, it is advisable to connect the drive to a handle, in which the transmission of the rotational movement of the pinion gear onto the rack and thus the conversion into the linear movement of the push rod takes place.

Depending on the application, the push rod will be designed differently. If only one separation is to take place, the push rod is made of solid material. On the other hand, if, for example, a tissue sample is suctioned off after cutting, this is advantageously done by means of a sleeve-shaped rod, the interior of which forms a suction channel. As is known, this sleeve rod slides in an outer sleeve rod and, together with it, forms the scissor jaw. In this exemplary embodiment, the inner sleeve rod is then connected to a vacuum source, by means of which the tissue sample can be suctioned through the suction channel in the inner sleeve rod.

When using a handle, it is advisable for the inner sleeve rod to pass through the handle and, on the other hand, to open into a connection nipple for the vacuum source. However, this is only one exemplary embodiment for the use of the drive according to the invention. Other possible uses are also intended to be encompassed by the present inventive concept. Further advantages, features and details of the invention result from the following description of preferred exemplary embodiments and from the drawing; this shows in

Figure 1 is a plan view of a drive according to the invention for a surgical instrument;

Figure 2 is a side view of the drive according to the invention according to Figure 1;

FIG. 3 shows a longitudinal section through an exemplary embodiment of a surgical instrument which is used in connection with the drive according to FIG. 1;

Figure 4 is a plan view of individual elements of the drive according to the invention according to Figure 1;

Figure 5 is a block diagram representation of the control of the drive.

In FIG. 3, as an example of a surgical instrument, a suction punch 1 is shown which has two sleeve rods pushed into one another. An outer sleeve rod 2 is stationary relative to a screw connection 3 or the like, while an inner sleeve rod 4 has a smaller diameter than the outer sleeve rod 2 and slides in the outer sleeve rod 2. The inner sleeve rod 4 actuates a cutting element 5 of a scissor jaw 6, a counter element 7 to the cutting element 5 being part of the outer sleeve rod 2.

The inner sleeve rod 4 is connected to the cutting element 5 in an articulated manner via a pivot pin 8, while the cutting element 5 forms a swivel joint 9 with the outer sleeve rod 2. The cutting element 5 rotates about this swivel joint 9 and, in cooperation with the counter element 7, can thus take a tissue sample or the like from inside a human body.

The inner sleeve rod 4 also forms a suction channel 10, which, not shown, is connected to a vacuum source. In this way, a cut tissue sample from the scissor jaw 6 passes in the direction of arrow x through the suction channel 10 into a collecting device, also not shown in detail.

The outer sleeve rod 2 can be placed together with the screw connection 3 on a handle 11, as shown in FIGS. 1 and 2. It is not shown that the inner sleeve rod 4 passes through the handle 11 and opens into a connecting nipple 12 for connecting, for example, a suction hose. A drive 13 is connected to the handle piece 11 and can be operated by a button 14. A drive shaft 15, indicated in FIG. 4, of the drive 13 runs perpendicular to the inner sleeve rod 4, which, as previously described, is designed as a push rod. On the drive shaft 15, a pinion 16 is placed, which cooperates with a toothing 17 on the inner sleeve rod 4. It is also possible that a separate sleeve 18 provided with the toothing 17 is pushed onto the inner sleeve rod 4. When the drive 13 is actuated, the toothed pinion 16 transmits the rotational movement of the drive shaft 15 into a linear movement of the inner one Sleeve rod 4, which results in an actuation of the scissor jaw 6. In this way, for example, the scissor jaw 6 can be closed at certain intervals by means of an electronically controlled change in the rotary movement of the drive shaft, and tissue samples can thus be taken. It is also possible to adjust the cutting force, which can also be controlled electronically.

The drive is preferably a DC electric motor, which is supplied via a corresponding connector 19. For example, this motor should make about 12,000 revolutions per minute, a reduction gear 20 being arranged between it and the drive shaft 15. This transmission 20 has a gear ratio of 2,000: 1 or 1,000: 1.

To control the entire instrument, the following must be added with reference to FIG. 4:

The drive is switched on using button 14. This resets the entire system. The further operation of the instrument then also takes place via the button 14. Pressing the button 14 closes and opens the scissor jaw 6. This is done by setting the drive 13 to the left or right.

The electronic control is designed so that the driving force remains constant by a current or voltage control. An overload control is built in to protect the drive. The drive is defined as an actuator. All functions come from the control. The rest position is also adjustable, this being done by an electronic evaluation.

Claims

PATENT CLAIMS

1. Surgical instrument, in particular a suction punch for taking tissue samples, with a scissor jaw, which can be actuated from a handle or the like by means of at least one push rod or the like,

characterized,

that the push rod or the like. Is connected to a drive (13).

2. Instrument according to claim 1, characterized in that the drive (13) is an electric motor with right / left rotation.

3. Instrument according to claim 1 or 2, characterized gekenn¬ characterized in that the rotational force of the drive (13) is controllable.

4. Instrument according to one of claims 1 to 3, characterized in that the drive (13) has a Antriebs¬ shaft (15) with a pinion (16) which is in engagement with a toothing (17) on the push rod.

5. Instrument according to claim 4, characterized in that a gear (20) is arranged between the drive (13) and the pinion (16).

6. Instrument according to claim 5, characterized in that the transmission (20) has different stages for reducing the drive speed.

7. Instrument according to at least one of claims 4 to

6, characterized in that the drive shaft (15) extends transversely to the push rod or its toothing (17).

8. Instrument according to at least one of claims 4 to

7, characterized in that the toothing (17) of a sleeve (18) is formed and this is placed on the push rod.

9. Instrument according to at least one of claims 1 to

8, characterized in that the drive (13) is attached to a handle (11).

10. Instrument according to at least one of claims 1 to

9, characterized in that the push rod is designed as a sleeve rod (4) which slides in an outer sleeve rod (2) and together with this forms the scissor jaw (6).

11. Instrument according to claim 10, characterized in that the inner sleeve rod (4) forms a suction channel (10) which is connected to a vacuum source in connection.

12-. Instrument according to claim 11, characterized in that the inner sleeve rod (4) passes through the handle (11) and opens into a connection nipple (12) for the vacuum source. _ _ __-

13. Instrument according to at least one of claims 1 to 12, characterized in that a regulation of the drive (13) is carried out by a current or voltage control so that its force remains constant.

14. Instrument according to claim 13, characterized in that an overload control is integrated in the electronic control.