Patent Application
20120245414
The present invention relates to a handle for controlling instruments. This handle comprising a frame with a center line, operating elements that are connected to the frame, which operating elements are movable between a first and a second position, an actuator element that is controllable by the operating elements, which actuator element is constructed and arranged for controlling an instrument that is arranged at a distance from the handle, wherein the operating elements are constructed and arranged for enabling a longitudinal displacement of the actuator element upon a movement of the operating elements between the first and the second position.
An instrument that can be controlled by the handle might be used in minimal invasive surgical interventions. In those interventions, the instrument is commonly used in combination with an endoscope through which the instrument is guidable into body cavities. Therefore, these instruments are commonly indicated as endoscopic instruments.
Endoscopic instruments can also be used for other than medical applications. Examples include inspection and/or repair of mechanical or electronic installations at locations that are difficult to reach. In the following description, terms as endoscopic application or endoscopic instrument might be used. However, these terms must be interpreted as covering also other applications or instruments as explained above.
The present invention further relates to an endoscopic instrument comprising a tube like element with a proximal end and a distal end, a tool and a handle according to the present invention. The handle and the tool are arranged respectively at the proximal end and the distal end of the tube like element. The tube like element and the tool are constructed and arranged for being operated by the handle according to the present invention.
The present invention also relates to an assembly of an endoscopic instrument and an endoscope that is constructed and arranged for being controlled by a handle according to the present invention.
Transformation of surgical interventions requiring large incisions for exposing an operation area into minimal invasive surgical interventions, i.e. requiring only small incisions for establishing access to the operation area, is a well-known and ongoing trend. To be able to perform a minimal invasive surgical intervention, a physician needs to have access to surgical instruments that enable reaching the operation area via a small incision and to remotely perform actions at the operation area. Such instruments are well-known in the art and include endoscopic instruments comprising a tube like element with a distal and proximal end, a handle connected to the proximal end and a surgical tool connected to the distal end of the tube like element. The terms distal and proximal are defined with respect to the physician that operates the instruments, i.e. the physician manipulates the proximal end of the instrument which results in an event at the distal end of the instrument at the operation area inside a patient's body. Therefore, the tube like element of the endoscopic instruments preferably is steerable as described in international patent applications WO 2009/112060 and WO 2009/127236 of the applicant, which applications were filed on 30 Jun. 2008 and 18 Apr. 2008, respectively and are here incorporated by reference.
Known handles for steerable endoscopic instruments comprise a pistol grip or pliers grip or scissors grip. Handles with a pistol grip comprise a trigger element that is constructed and arranged for activating the tool, e.g. a biopsy cutter, a pair of scissors, pliers, grippers. Steering of the tube like element of the endoscopic instrument and of the tool located at the distal end thereof is commonly done via a joystick or via a thumb controlled operating element. Known handles of the kinds mentioned above have several drawbacks that render the endoscopic instruments in which they are applied unsuitable for being used in minimal invasive interventions.
A first drawback of the abovementioned known handles is that although an operator, e.g. a physician, can of course learn how to steer the endoscopic instrument and the tool at the distal end thereof with the thumb, this is not a natural mechanism of action and reaction and usually does not give a one on one deflection feedback. In addition, operating a trigger element, for example for closing a pair of scissors or pliers, is not a natural mechanism of action and reaction and usually does not provide logical force feedback.
A second drawback is that rotating the endoscopic instrument requires not only rotation of a wrist or rotation of the wrist and under arm but in some cases also rotation of a whole arm or even rotation or repositioning of substantially the whole body of the operator.
A third drawback is that the handles described above can be quite voluminous. If in a minimal invasive intervention two endoscopic instruments comprising such handles are to be used side by side, it might at least be difficult if not impossible to do so as the handles could be in each other's way. As a result, freedom of manipulation would at least severely be reduced. To solve this, in practice two incisions at sufficient distance from each other would be necessary.
A fourth drawback is that the known handles commonly comprise many separate parts and pulling cable mechanisms, which are complex to assemble and therefore expensive to manufacture. As a result, these kinds of handles are commonly applied in instruments that are reused because of the relatively high costs involved. Reuse of surgical instruments might imply risks with respect to cleaning and sterilization and require proper equipment and manpower in the hospital. Unfortunately, infections as a result of surgical instruments that have not been cleaned and sterilized properly frequently occur.
It is an object of the present invention to provide a handle for controlling instruments, such as endoscopic instruments, that preempts or at least reduces the drawbacks of the abovementioned known handles. It is also an object of the present invention to provide an endoscopic instrument that is controllable by the handle according to the present invention. It is a further object of the present invention to provide an assembly of an endoscopic instrument and an endoscope that is constructed and arranged for being controlled by a handle according to the present invention.
At least one of these objects is achieved by a handle according to the present invention, wherein the operating elements are arranged in a rotationally symmetric configuration that is concentric with the center line of the frame, wherein the operating elements are movable between the first and second positions by a displacement in a direction substantially perpendicular to the center line of the frame. The handle according to the present invention has a rotationally symmetric outer circumference when the operating elements are in or in between the first and second positions. Such a rod like handle provides a pen-like grip that enables convenient and natural manipulation of the handle between thumb and fingers. Therefore, the handle should have an outer diameter in a radial direction with respect to the center line of the frame that lies in a range from about 10-50 millimeters, preferably in a range from about 20-40 millimeters.
By interconnecting the operating elements via a resilient element, such as a rubber ring or rubber cover, all operating elements are movable substantially simultaneously between the first and second position when at least one of them is displaced in a direction substantially perpendicular to the center line of the handle. As a result, by simply squeezing the handle anywhere at its outer circumference between thumb and fingers, an actuating element that is constructed and arranged for controlling an event at a distal end of an endoscopic instrument is controlled such that a tool at a distal end of an endoscopic instrument changes state, e.g. is activated or deactivated. Upon releasing the handle, the operating elements are moved from the second to the first position as they are prestressed towards the first position by a first pretensioning element. As a result, the actuating element is controlled such that the tool at the distal end of the endoscopic instrument changes state, e.g. is deactivated or activated.
The outer circumference of the handle according to the present invention remains rotationally symmetric when the operating elements are moved between the first and second positions. As a result, manipulation of the handle remains convenient and controllable.
Rotation of the endoscopic instrument over the complete 360° can easily be done by rotating the handle between thumb and fingers, without requiring any adjustment in position of the arms and/or the whole body of the operator.
Steering of the endoscopic instrument can be achieved by moving the handle in any desired direction. Steering can be done in situations in which the handle is un-squeezed, i.e. operating elements are in the first position, or squeezed, i.e. operating elements are in between the first and the second position or in the second position, without requiring rotation of the whole arm or even rotation or repositioning of substantially the whole body of the operator. The handle according to the present invention enables steering of the endoscopic instrument and controlling of the tool located at the distal end thereof by simple manipulations performed by the thumb and fingers and/or the wrist and/or under arm of the operator. As a result, the handle according to the present invention provides a natural mechanism of action and reaction and a one on one deflection feedback. In addition, the handle according to the present invention provides logical force feedback. The force feedback can be one on one (1:1) but it can also be tuned by applying a second pretensioning element that prestresses the operating elements towards the second position. Because of the clear feedback the operator, e.g. a physician, can clearly feel which forces are exerted by the endoscopic instrument and/or the tool at the distal end thereof on treated or surrounding tissue.
The slim and compact pen-like construction of the handle according to the present invention might enable the use of two endoscopic instruments comprising such handles side by side in a minimal invasive intervention. As the freedom of manipulation might significantly be increased, it might no longer be necessary to make two incisions at sufficient distance from each other in certain applications. Instead a single incision might be made and the two instruments might be guided through a single endoscope.
According to another aspect of the present invention an endoscopic instrument is provided comprising a tube like element with a proximal end and a distal end, a tool and a handle according to any of the preceding claims, wherein the handle and the tool are arranged respectively at the proximal end and the distal end of the tube like element, wherein the tube like element and the tool are constructed and arranged for being operated by the handle.
The handle is constructed and arranged for controlling the tool located at the distal end of the endoscopic instrument by mechanical means like a pulling wire. Examples include closing and opening of cutting blades of a pair of surgical scissors or inserting or retracting a needle. The handle can also be constructed and arranged for controlling such tools by means of making and/or breaking an electrical contact and/or by means of opening and/or closing a pneumatic or hydraulic valve or combinations of all means mentioned. The handle according to the present invention is also constructed and arranged for rotating the endoscopic instrument and steering of the distal end thereof.
The actual steering mechanism of the endoscopic instrument is located in the tube like element. The proximal and distal ends thereof comprise flexible portions that are constructed and arranged for steering the tube like element of the endoscopic instrument by moving the handle in any direction. The tube like element comprises longitudinal elements that are constructed and arranged for transferring a displacement of the proximal end to the distal end resulting in a change in orientation thereof. The distal end comprises at least two independent flexible portions. This enables for example making S-like curves with the distal end of the tube like element.
The proximal and distal ends comprise a corresponding number of flexible portions, wherein each flexible portion at the proximal end is connected by means of its own set of longitudinal elements to a flexible portion at the distal end. A detailed description of such steerable tube like elements and preferred processes for producing them have been described in international patent applications WO 2009/112060 and WO 2009/127236 of the applicant, which applications were filed on 30 Jun. 2008 and 18 Apr. 2008, respectively and are here incorporated by reference. These steerable tube like elements provide enhanced guiding capabilities of the endoscopic instrument and enhanced positioning capabilities of a tool, e.g. a surgical pair of scissors, a biopsy cutter, pliers or grippers, at an operation location.
According to another aspect of the present invention an assembly is provided comprising an endoscopic instrument and an endoscope that is constructed and arranged for being controlled by a handle according to the present invention. Therefore, the endoscope comprises a tube like element having proximal and distal ends that comprise flexible portions that are constructed and arranged for steering the endoscope by moving the handle according to the present invention in any direction.
These and other features and effects of the present invention will be explained in more detail below with reference to drawings in which preferred and illustrative embodiments of the invention are shown. The person skilled in the art will realize that other alternatives and equivalent embodiments of the invention can be conceived and reduced to practice without departing from the scope of the present invention.
a shows a schematic representation of a longitudinal cross section of the handle according to
a shows a cross section of the handle in
a shows a schematic representation of a longitudinal cross section of the handle according to
a shows a cross section of the handle in
b shows a longitudinal cross section of the preferred embodiment of the handle according to the present invention, wherein the levers are in the second position.
a shows a schematic representation of a longitudinal cross section of the embodiment of the handle according to
a shows a schematic representation of a longitudinal cross section of the embodiment of the handle according to
a shows a schematic representation of a longitudinal cross section of the embodiment of the handle according to
a shows a side view of the endoscopic instrument according to
b shows a side view of the endoscopic instrument according to
The figures are not necessarily drawn to scale. In the figures identical components are denoted by the same reference numerals.
The handle as shown in the annexed drawings can be used with endoscopic instruments for medical applications but its use is not restricted to that. It may also be used in other applications such as technical applications in which endoscopic instruments are used for handling or viewing parts of machines or installations which are otherwise difficult to reach. The handle according to the present invention as used in this description will implicitly include these applications.
a shows a schematic representation of a longitudinal cross section of the handle 1 according to
a shows a cross section of the handle in
The preferred embodiment of the handle 1 according to the present invention should achieve a larger displacement Δx of pulling wire 6 while maintaining the ratio of length LA and length LB for achieving a sufficient displacement force.
a shows a schematic representation of a longitudinal cross section of the handle according to
It has to be noted that in the case of applications in which the pulling wire 6 only has to be displaced about an amount Δx a first group of levers 4 suffices. Furthermore, in those cases in which no actuator element 6 is required for controlling a tool that is located at a distal end of an endoscopic instrument the same arrangements of levers can be used, i.e. only a first group of levers 4 that are arranged in a rotationally symmetric configuration that is concentric with the center line 9 of the frame 2 or a first group of levers 4 and a second group of levers 10 that are arranged in a rotationally symmetric configuration that is concentric with the center line 9 of the frame 2, wherein the first group of levers 4 is arranged mirror wise with respect to a second group of levers 10. Using one of these arrangements, it is possible for example to make or break an electrical contact and/or to control a potentiometer and/or to open and close a valve in a dosed manner.
a shows a cross section of the handle in
b show that the levers 4, 10 of the first and second groups provide handle 1 with a rotationally symmetric outer circumference when the levers 4, 10 are in the first and second positions.
Especially for medical applications, it is required that handle 1 is hermetically sealed from an outside environment. This can be done by a sealing 14 that fully encloses the outer circumference of handle 1 as is shown in
From
In order to maintain levers 4, 10 in the first position, handle 1 comprises a first pretensioning element 15 that is constructed and arranged for prestressing the levers 4, 10 towards the first position. In the preferred embodiment shown in
b shows a longitudinal cross section of the preferred embodiment of the handle 1 according to the present invention, wherein the levers 4, 10 are in the second position. As stated above, the levers 4, 10 can be prestressed towards the second position by resilient sealing 14. However, prestressing of levers 4, 10 towards the second position can also be achieved or, if necessary, can be enhanced by a second pretensioning element 18 that is arranged around the levers 4, 10 in a radial direction with respect to the center line 9 of frame 2. The second pretensioning element 18 can be a resilient circular element. Pretensioning element 18 can comprise rubber or a metal spring.
When the levers 4, 10 are moved from the first to the second position, first lever arms 7 of levers 4 displace connecting element 17 in a longitudinal direction opposite to that in which plunger element 16 is forced by spring 15. At the same time, frame 2 is longitudinally displaced in the direction of first arms 7 of levers 4 by first arms 11 of levers 10 via connecting element 19.
b show that handle 1 has a rotationally symmetric outer circumference when the levers 4, 10 are in the first and second positions and any position in between. It will be clear to the person skilled in the art that the first position is only maintained if the force exerted by spring 15 results in a larger and oppositely directed torque than the torque resulting from the force exerted by resilient sealing 14 and/or the second pretensioning element 18. These torques are tunable such that an operating force is established that allows force feedback from the activated instrument resulting from manipulation or cutting the treated tissue.
With the preferred embodiment as shown in
Materials that can be used in the production process are thermoplastic materials that might be fiber reinforced and are suitable for injection molding. Examples of such materials are nylon, polyvinyl chloride (PVC), acrylonitrile butadiene styrene (ABS), polyethylene terephthalate (PET) and others as long as they are sufficiently strong and rigid from a mechanical point of view. Other preferable materials are plastics, metals or resins that can be shaped with for example three dimensional printing. With respect to metals, other suitable choices are alloys that can be injection molded and/or alloys that are easily machinable.
As can be seen from
An embodiment of handle 1 could be assembled from parts that are cheaply connectable without needing any crew connections at all. Although adjustment of the first position of the handles 4, 10 might not be possible, such an embodiment could reduce the costs of handle 1.
An embodiment of handle 1 could comprise real hinge constructions that are fixed to the frame 2 and levers 4, 10. The costs of this embodiment would be higher as more parts are required and assembly is more difficult.
An embodiment of handle 1 could comprise levers 4,10 that are integrated with connecting elements 17, 19 to form a single integrated part. This could possibly further reduce the costs of handle 1.
It will be clear to the person skilled in the art that many alternative embodiments are possible without departing from the scope of the present invention.
The main difference between the handles shown in
The first position of the operating elements 24 is maintained by a first pretensioning element. A second pretensioning element can be arranged around the operating elements 24 in a radial direction with respect to the center line 9 of the frame 2 of the handle 1 for prestressing the operating elements 24 towards the second position. A resilient sealing will also be arranged around the handle 1 in order to hermetically seal it from an environment.
The embodiment of the handle 1 shown in
Again the main difference between the handles shown in
Frame 2 comprises an interior volume 28 that is in a communicating relationship with an interior volume of housing 3. The interior volume of housing 3 is divided into two parts 25, 26 by plunger 16. Squeezing the handle 1 results in a displacement of the operating elements 24 in a direction substantially perpendicular to the center line 9 of the frame 2 towards the second position. As a result, the interior volume 28 of frame 2 decreases. This decrease is compensated by an increase in volume of part 25 and a decrease in volume 26 of the interior volume of the housing 3. The volume of part 26 can be decreased because of the communicating connection 27 between part 26 and an environment outside the handle 1 or by filling this volume with a compressible gas. Due to the increase of the volume of part 25 of the interior volume of the housing 3 plunger element 16 is displaced in a longitudinal direction. As the plunger 16 is connected to an actuator element 6, e.g. a pulling wire, the radial displacement of operating elements 24 is transferred into a longitudinal displacement Δx of the actuator element 6.
If no force is applied to the handle 1, the operating elements 24 are prestressed towards the first position by the first pretensioning element. As a result the volume 28 of the frame 2 is increased. The increase in volume 28 is compensated by a decrease of the volume of part 25 and an increase in the volume of part 26 of the housing 3. The volume of part 26 of the housing 3 can increase because of the communicating connection 27 between part 26 of the interior volume of the housing 3 and the outside environment of the handle 1. As a result of the changing volumes of parts 25 and 26 of the housing 3, plunger element 16 is displaced in an opposite longitudinal direction with respect to the transition of the operating elements 24 from the first to the second position. This situation is most likely for an embodiment of handle 1 in which interior volumes 28 and 25 are filled with a gas.
In an embodiment of handle 1 in which interior volumes 28 and 25 are filled with a liquid, the plunger 16 is prestressed towards the first position by the first pretensioning element which is for example a spring or a compressed gas arranged in volume 26. If no force is applied to the handle 1, volume 25 is decreased. The decrease in volume 25 is compensated by an increase of volume 28. As a result of the increasing volume 28, operating elements 24 will move and will be kept in the first position.
The main difference between the embodiments of the handle 1 shown in
The frame 2 of the handle 1 comprises two parts 42, 43 that are connected via operating elements 24. When moved between the first and second positions, the operating elements 24 pivot around pivot points 5 that are arranged on the parts 42, 43 of the frame 2 respectively. When the operating members 24 are moved from the first to the second position the length of the handle 1 will increase in longitudinal direction as parts 42 and 43 are displaced in a direction opposite to each other.
As the embodiment of the handle 1 shown in
The actual steering mechanism of the endoscopic instrument 60 is located outside the handle 1 in the tube like element 50.
a shows a side view of the endoscopic instrument 60 according to
b shows a side view of the endoscopic instrument 60 according to
It will thus be seen that the invention efficiently attains the objects set forth above, among those made apparent from the preceding description. Since certain changes can be made in the above constructions without departing from the scope of the invention, it is intended that all matter contained in the above description or shown in the accompanying drawings be interpreted as illustrative and not in a limiting sense.
It is also to be understood that the following claims are to cover all generic and specific features of the invention described herein, and all statements of scope of the invention which, as a matter of language, might be said to fall therebetween.
