EP2323581A1

EP2323581A1 - Method for operating a medical robot, medical robot, and medical work place

Info

Publication number: EP2323581A1
Application number: EP09777747A
Authority: EP
Inventors: Andreas Summerer; Thomas Neff; Tobias Ortmaier; Marc-Walter Ueberle
Original assignee: KUKA Roboter GmbH
Current assignee: KUKA Deutschland GmbH
Priority date: 2008-08-14
Filing date: 2009-08-07
Publication date: 2011-05-25
Also published as: US20110190790A1; WO2010017919A1; DE102008041260A1

Abstract

The invention relates to a method for operating a telemanipulated medical robot (R) guided by hand or by means of an input device, to a telemanipulated medical robot (R) guided by hand or by means of an input device, and to a medical work place. The medical robot (R) comprises a robot arm (M) with a plurality of moveable axes (1-6) and a control device (17) for moving the axes (1-6) of the robot arms (M) by means of drives (11-16). The control device (17) is adapted to automatically change the work region (A) of the medical robot (R) due to a change of position, relative to a robot base (B) of the medical robot (R), of a living being (P) that is being treated by means of the medical robot (R) in such a way that the work region (A) of the medical robot (R) stays the same relative to the living being (P).

Description

Method for operating a medical robot, medical robot and medical workstation

The invention relates to a method for operating a medical hand-held, in particular hand-guided, or telemanipulated by means of an input device, a medical hand-held or telemanipulated by means of an input device, and a medical workstation.

Robots are working machines which can be equipped with tools for the automatic handling and / or machining of objects and which can be programmed in several axes of motion, for example with regard to orientation, position and operating sequence.

Robots can e.g. for medical and / or clinical applications and are then e.g. Part of a medical workplace. Robots can also be tele-guided or directly guided for these applications.

US 2004/0077939 A1, for example, discloses a medical workstation with an X-ray machine, a surgical instrument, a position detection system and a robot guiding the surgical instrument for treating a patient in an at least partially automated manner. In order to detect the positions of the surgical instrument, the X-ray apparatus and the patient, position markers are arranged on the X-ray apparatus, on the patient and on the surgical instrument or on the robot, which are recorded by an optical position detection apparatus of the position detection system. On the basis of an evaluation of the images of the position markers recorded with the optical position detection device, the position, ie the position and orientation of the position markers and thus of the surgical marker Instruments, the X-ray machine and the patient in the room to be determined.

Particularly in the case of a surgical procedure, it is desirable to treat as far as possible only tissue of the patient to be treated with the robot or with the instrument guided by the robot.

The object of the invention is to create conditions on the basis of which the risk of injury to a living being treated by means of a robot is at least reduced.

The object of the invention is achieved by a method for operating a medical hand-held, in particular hand-guided or telemanipulated by means of an input device, comprising the following method steps:

Determining a working area of a medical robot provided for the treatment of a living being relative to

Creature,

Detecting a changing position or position of at least a part of the living being treated by the medical robot and

- Automatically adjusting the working area of the medical robot due to the changing position of the living being relative to the robot base, so that the working area of the medical robot remains the same relative to the living being.

The object of the invention is also achieved by having a medical hand-held or in particular telemanipulated by means of an input device a robot arm with several movable axes and

a control device for moving the axes of the robotic arm by means of drives, wherein the control device is set up to automatically change the working area of the medical robot due to a changing position or attitude of a living body treated by the medical robot relative to a robot base of the medical robot; so that the working area of the medical robot remains the same relative to the living being.

According to one embodiment of the robot according to the invention or of the method according to the invention, the robot treating the animal is either telemanipulated or hand-guided. The restriction of the work area can be presented to the attending physician via forces on the robot during manual operation or via forces at an input station during telemani- culated deployment. It is also possible that the robot can not be moved beyond the working area in telemanipulated use.

The inventive method can thus be carried out with the robot according to the invention.

The medical robot according to the invention is provided for treating the living being, for example a human, with it. For this purpose, for example, a medical instrument, in particular a surgical instrument, is attached to a fastening device of the robot, with which the living being is to be treated. For example, the robot according to the invention may be programmed to move the medical instrument on a predetermined path. The inventive However, robots can also be tele-guided or directly guided.

In order in particular to protect the living being during the treatment, the working range of the robot according to the invention is limited. The working area of a robot is the allowed area for the robot to work and process. During operation of the robot according to the invention, in particular the so-called Tool Center Point, if appropriate also the axes of the robot, must be located within a workspace. This prevents the robot from entering a forbidden region or leaving a predetermined path.

As already mentioned, the robot according to the invention is used to treat the living being. In general, the living being is treated only in a partial area of his body, so that the working area of the robot according to the invention can be chosen such that the tool center point and thus possibly the medical instrument moved with the robot according to the invention move substantially only within this partial area can. As a result, conditions are created that parts of the living being not to be treated are not accidentally injured by the robot according to the invention. According to the invention, the working range of the medical robot according to the invention is determined relative to the living being. This can e.g. be realized in that the work area is set relative to a life-living coordinate system associated with the living being.

During the treatment of the living being, it is possible that this moves relative to the robot base, which is associated with a robot coordinate system, for example. Accordingly, the position or posture changing the position and 0- Orientation of the living being relative to the robot base or relative to the robot coordinate system. In order to cope with such a change, according to the invention, the working area of the medical robot according to the invention is automatically adjusted due to the changing position of the living being relative to the robot base or relative to the robot coordinate system. Thus, the working range of the medical robot according to the invention remains relatively constant relative to the living being.

The working range of the robot according to the invention can e.g. be limited or adjusted by means of a running on the control device of the robot computer program.

If the medical robot according to the invention is e.g. due to a movement of the living being relative to the robot base outside its current working range, then it is according to an embodiment of the method according to the invention or the invention. Robot to automatically move the medical robot to its current workspace. This is realized, for example, by the control device of the robot according to the invention being arranged to automatically move the robot arm to guide the tool center point into the current work area when the tool center point is outside due to the movement of the living being relative to the robot base of the current workspace.

According to a variant of the method according to the invention, the current position or position of the living being is detected by means of a navigation system. The control device of the robot according to the invention can accordingly be set up to determine the relative position of the living organism on the basis of the current position or position of the living being detected by means of the navigation system. Determining the position or position of the living being relative to the robot base in order to adapt the work area.

A further aspect of the invention also relates to a medical workstation comprising the robot according to the invention and the navigation system communicating with the control device of the robot, which is set up to detect the current position or position of the living being, wherein the control device is set up on the basis of detected by the navigation system current position or position of the living being to determine the relative position or position of the living being relative to the robot base to adapt the workspace.

Navigation systems are generally known in medical technology, in particular in minimally invasive medical technology, for example from US Pat. No. 6,895,268 B1. Navigation systems include a detection device which is, for example, an optical detection device, e.g. Cameras, a laser tracking system, projectors for a structured

May have light or line projectors. The detection device is set up to detect in a generally known manner, for example on the living being, in particular on its surface arranged markers or prominent parts of the living being. Due to the markers or landmarks detected by the detection device, a computing device of the navigation system can determine the position and optionally the orientation, ie the position of the living being, in a manner which is generally well known.

Navigation systems are used, for example, to intraoperatively display an instrument guided in the living being, for example the medical instrument moved by the robot according to the invention, into a preoperatively recorded image of the living being. The image of the living being is a 3D image, for example was recorded with a computer tomograph or a magnetic resonance device. As a rule, a so-called registration of the image data set assigned to the pre-optive image to the interoperative situation is generally necessary for the superimposition of the medical instrument in the preoperatively recorded image. In the case of a rigid body situation, for example, a homogeneous coordinate transformation, for example via corresponding points, is determined, which images both data sets on one another.

According to a further variant of the method according to the invention, the current position of the tool center point of the medical robot by means of the navigation system and the current position or the current position of the living being relative to the robot base based on the determined current positions of the living being and the Tool Center Points determined. The control device of the robot according to the invention can therefore be set up, based on the determined by means of the navigation system current location of the tool center point of the medical robot, the current position or the current position of the living organism relative to the robot base based on the determined current positions of the animal and the tool center Determine points to adjust the workspace.

In these variants of the robot according to the invention or the medical workstation according to the invention, the navigation system or its computing device communicates with the control device of the robot according to the invention. This can be realized, for example, such that the navigation system and the control device of the robot according to the invention are connected to one another by means of a communication line or also wirelessly and communicate via a common communication protocol. About this can Status information, commands and / or data of the detection device of the navigation system are transmitted.

An embodiment of the invention is illustrated by way of example in the accompanying schematic drawings. Show it :

1 a medical workstation with a navigation system and a medical robot for the treatment of a living being,

Fig. 2 the medical workstation associated coordinate systems and

3 is a flowchart illustrating the operation of the medical robot.

FIG. 1 shows a medical workstation having a medical robot R with a robot arm M. The robot arm M essentially represents the movable part of the robot R and comprises a plurality of axes 1-6, a plurality of levers 7-10 and a flange F to which a surgical instrument 18 is attached in the case of the present embodiment.

Each of the axes 1-6 is moved by a drive, for example an electric drive 11-16, which are electrically connected in a manner not shown to a control computer 17 of the robot R, so that the control computer 17 or one on the control computer 17 running computer program, the electric drives 11-16 can control such that the position of the flange F of the robot R and thus the surgical instrument 18 and its Tool Center Point TCP can be aligned substantially freely in space. The electric drives 11-16 of the robot R comprise, for example, because an electric motor and possibly a motor controlling the power electronics.

In the case of the present exemplary embodiment, the control computer 17 is designed such that it or a computer program running on it can restrict a working area A of the robot R. Under the working area A of the robot R is meant the allowable area for the robot R for working and procedures. In the operation of the robot R, in the case of the present exemplary embodiment, the surgical instrument 18 and in particular the tool center point TCP must be located within the working area A. In the case of the present exemplary embodiment, the working area A is delimited by a virtual wall W shown in dashed lines in FIG. 1, the working area A of the robot R being located below the virtual wall W.

In the case of the present exemplary embodiment, the robot R is intended to treat a patient P lying on a patient couch L with the surgical instrument 18. In addition, in the case of the present embodiment, the robot (R) is operated by a person not shown, e.g. a physician treating the patient by hand, e.g. on the robot arm M presses or pulls. Alternatively or additionally, the robot R can also be moved by this person by means of an input device connected to the control computer 17, for example a joystick J, in a manipulated manner.

FIG. 1 further shows a navigation system which has a detection device E having two cameras 20, 21 in the case of the present exemplary embodiment, a marker M 1 arranged on the robot R and a marker M2 arranged on the patient P. In the case of the present exemplary embodiment, the detection device E of the navigation system comprises Furthermore, a computer 22 and is mounted on a tripod 19 and the markers Ml of the robot R are arranged at its flange F.

Navigation systems as such are known to those skilled in the art from, inter alia, US Pat. No. 6,895,268 B1 and are intended to control the position, i. to determine the position and orientation of an object, for example the patient P.

Navigation systems may, for example, be magnetic or, as is the case with the present exemplary embodiment, optical navigation systems and are used, for example, to determine the position and optionally the orientation of an object. In order to determine the position of, for example, the patient P or the tool center point TCP of the robot R, the navigation system uses its cameras 20, 21 to determine the positions of the markers M1, M2 in the space.

In the case of the present embodiment, the computer 22 of the detection device E via an electrical line 24 with a monitor 25 having a computer 23 is connected. The computer 23 stores an image data record associated with an image of the patient P, the associated image of which can be displayed by the monitor 25. The image data set has been e.g. recorded with an imaging medical device, such as a magnetic resonance device or a computer tomograph before treatment of the patient P with the robot R. During the treatment of the patient P with the robot R, a picture of the surgical

Instruments 18 are displayed in the image of the patient P. For this purpose, the position of the patient P and of the surgical instrument 18 relative to the coordinate system of the image data record assigned to the image by the patient must be determined. In the case of the present embodiment, the computer 22 of the detection device E is also connected by means of a communication line 26 to the control device 17 of the robot R, so that the computer 22 and the control device 17 can communicate with each other in particular by means of a common communication protocol. A wireless communication between the computer 22 and the control device 17 is also conceivable.

FIG. 2 shows the robot R, the patient P arranged on the patient couch L, the virtual wall W, and a TCP coordinate system 30 assigned to the tool center point TCP of the robot R, a robot coordinate system 31 assigned to the robot R. the origin of which falls on the robot base B of the robot R, a patient coordinate system 32 associated with the patient P, and a workspace coordinate system 33 associated with the virtual wall W. In the case of the present embodiment, the coordinate systems 30-33 are Cartesian coordinate systems.

As already mentioned above, in the case of the present embodiment, the tool center point TCP should be located within the working area A during the treatment of the patient P only. During the treatment of the patient P, moreover, the working area A is to be related to a potential movement of the patient P relative to the robot base B, in this case relative to the robot coordinate system 31, for example by a movement of the patient P or a movement of the robot base B of the robot R , to adjust. This process is illustrated by means of a flowchart shown in FIG. In the case of the present exemplary embodiment, first the working area A is defined relative to the patient P, in particular relative to the patient coordinate system 32, step S1 of the flowchart of FIG. 3. In the case of the present exemplary embodiment, as already mentioned, the working area A is determined by FIG virtual wall W, so that the virtual wall W or its wall coordinate system 33 relative to the patient P or its patient coordinate system 32 is defined. This is described by a transformation T3. As a result, there are preconditions that the surgical instrument 18 is not outside of the working area A during the treatment of the patient P. The working area A can also be limited, for example, by a plurality of walls or differently, such as, for example, balls, cylinders, cones or free-form surfaces.

During the treatment of the patient P, the detection system detects the markers M1 and M2, whereby a computer program running on the computer 22 determines the position of the patient P and thus his patient coordinate system 32 and the position of the flange F and thus the position of the tool center point TCP or whose TCP coordinate system 30 can detect. This results in a transformation T2, which represents the position of the patient P from the point of view of the tool center point TCP, step S2 of the flowchart. This computer program can also run on the control device 17 of the robot R. Previously, as is well known to those skilled in the art, registration was made.

The position of the tool center point TCP or its TCP coordinate system 30 in the robot coordinate system 31 (coordinate system of the robot base B) is represented in the case of the present embodiment by a transformation Tl, which is calculated, for example, from measurements of the angles of the joints of the robot arm M. , Step S3 of the flowchart program. Alternatively, it is also possible to attach another marker to the robot base B of the robot R, whose position or position is detected by the detection device E and used to calculate the transformation Tl.

The representation of the virtual wall W, ie of the working area A in the robot coordinate system 31, results from the multiplication of the transformations T1, T2, T3 (T1 X T2 X T3), step S4 of the flow chart.

The transformations Tl and T2 are in the case of the present embodiment in e.g. predetermined intervals or when a predetermined change is exceeded is updated, whereby a movement of the patient P relative to the robot base B or relative to the robot coordinate system 31 is detected. Thereby, it is possible for the control device 17 to also update the work area A or the position of the wall coordinate system 33, so that the work area A always remains fixed relative to the patient P, step S5 of the flow chart.

A protection of risk structures while performing the treatment of the patient P by the robot R to target structures is therefore possible both in a movement of the robot R with respect to its robot base B as well as a moving virtual wall W. The protection may be for the functional end of the robot R, e.g. the surgical instrument 18, as well as the structure of the robot R are realized.

If, due to a movement of the patient P relative to the robot base B, the surgical instrument 18 is outside the current work area A, then in the case of the present exemplary embodiment it is provided that the control tion device 17 automatically moves the surgical instrument 18 in the updated work area A.

If the robot R is guided by hand, then, in the case of the present exemplary embodiment, the robot R can no longer be moved manually manually or only with increased force when the robot R leaves the working area A. This can e.g. be achieved in that the control computer 17 controls the drives 11-16, so that they exert a torque on the levers 7-10.

If the robot R is moved by means of the joystick J telemanipuliert, then in the case of the present embodiment, the robot R can no longer move or the joystick J generates a tactile feedback to the person when the robot R leaves the work area A.

Claims

claims

1. A method for operating a particular hand-held or by means of an input device telemanipulierten medical robot, comprising the following method steps:

- Defining a work area (A) of a medical treatment provided for the treatment of a living being (P)

Robot (R) relative to the living being (P),

- detecting a changing position or location of at least a portion of the (R) animal being treated by means of the medical robot (P) relative to the ro ^'boterbasis (B) of the medical robot (R) and

- Automatically adjusting the working area (A) of the medical robot (R) due to the changing position of the living thing (P) relative to the robot base (B), so that the working area (A) of the medical robot (R) relative to the living being (P) stays the same.

2. Method according to claim 1, comprising automatically moving the medical robot (R) into its current working area (A) when the medical robot (R) moves away from its current working area due to a movement of the animal (P) relative to the robot base ( A) is located.

3. The method of claim 1 or 2, comprising detecting the current position or position of the living being (P) by means of a navigation system (E, M2).

4. The method of claim 3, comprising determining the current position of the tool center point (TCP) of the medical robot (R) by means of the navigation system (E, Ml) and determining the current position or the current position of the living being (P) relative to the robot base (B) based on the ascertained actual positions of the living being (P) and the tool center point (TCP) or via at least one marker attached to the robot base (B) of the robot (R), which is detected by the detection unit (E) is detected and used to determine the current position or positions of the living being (P).

5. The method of claim 1, comprising

moving the robot (R) by hand or moving the robot (R) by means of an input device; and

Generating forces on the robot (R) or on the input device when the robot (R) leaves the work area (A).

6. Medical robot, in particular hand-guided or telemanipulierter by means of an input device medical robot, comprising

- A robot arm (M) with several movable axes

(1-6) and

- A control device (17) for moving the axes

(1-6) of the robot arm (M) by means of drives (11-16), wherein the control device (17) is arranged, automatically the working area (A) of the medical robot (R) due to a changing position or to change the position of a living being (P) treated by the medical robot (R) relative to a robot base (B) of the medical robot (R) so that the working area (A) of the medical robot (R) relative to the animal (P) stays the same.

7. Robot according to claim 6, the control device thereof

(17) is set up to drive the drives (11-16) so that the robot (R) exerts a force on a person handling the robot (R) when leaving the working area (A).

8. The robot according to claim 6, whose movement is telemanipulated by means of the input device and whose control device (17) is set up to control the input device in such a way that it exerts tactile feedback on a person operating the input device when the robot controls the work area (FIG. A) leaves.

9. Robot according to one of claims 6 to 8, the control device (17) is arranged to automatically move the robot arm (M) such that the Tool Center Point (TCP) is within the current work area (A), if itself the Tool Center Point

(TCP) due to the movement of the animal (P) relative to the robot base (B) outside of the current work area (A).

10. Robot according to one of claims 6 to 9, the control device (17) is set up, based on the detected by means of a navigation system (E, M2) current position or attitude of the living being (P), the relative position or position of the living being (P) relative to the robot terbasis (B) to adjust the work area (A).

11. Robot according to claim 10, whose control device (17) is set up, based on the current position of the Tool Center Point (TCP) of the medical robot (R) determined by the navigation system (E, Ml), the current position or the current position of the Living entity (P) relative to the robot base based on the determined current positions of the living thing (P) and the Tool Center Points (TCP) to determine the work area (A).

12. Medical workstation, comprising

- A robot (R) according to any one of claims 6 to 11 and

a navigation system (E) communicating with the control device (17), which is set up to detect the current position or position of the living being (P), the control device (17) being set up on the basis of the navigation system (E) detected current position of the living being (P) to determine the relative position or position of the living being (P) relative to the robot base to adapt the work area (A).

13. Medical workstation according to claim 12, whose navigation system (E) is set up to determine the current position of the Tool Center Point (TCP) of the medical robot (R), and whose control device (17) is set up on the basis of the Navigation system (E) determined current location of the Tool Center Point (TCP) of the medical robot (R) the current Determining the position or the current position of the living being (P) relative to the robot base (B) based on the determined current positions of the living thing (P) and the Tool Center Points (TCP) to adapt the work area (A).