The present invention relates to the field of surgical devices and systems, including those using electromechanical actuation.
There are various types of surgical robotic systems on the market or under development. Some surgical robotic systems use a plurality of robotic arms. Each arm carries a surgical instrument, or the camera used to capture images from within the body for display on a monitor. See U.S. Pat. No. 9,358,682 and US 20160058513, which are incorporated herein by reference. Other surgical robotic systems use a single arm that carries a plurality of instruments and a camera that extend into the body via a single incision. Each of these types of robotic systems uses motors to position and/or orient the camera and instruments and to, where applicable, actuate the instruments. Typical configurations allow two or three instruments and the camera to be supported and manipulated by the system. Input to the system is generated based on input from a surgeon positioned at a master console, typically using input devices such as input handles and a foot pedal. Motion and actuation of the surgical instruments and the camera is controlled based on the user input. The image captured by the camera is shown on a display at the surgeon console. The console may be located patient-side, within the sterile field, or outside of the sterile field.
System 10 comprises at least one robot arm 11 which operates under the control of a command console 12 operated by the surgeon, as described in the Background. The robotic manipulator (or each robotic manipulator) has a terminal portion 13 designed to support and operate a surgical device assembly 14. The surgical device assembly includes a surgical instrument having shaft 15 and a distal end effector 17 positionable within a patient 16.
In this configuration, the manipulator arm receives the surgical device assembly 14 at the terminal portion 13 as shown in
The end effector 17 may be one of many different types of that are used in surgery including, without limitation, end effectors 17 having one or more of the following features: jaws that open and close, section at the distal end of the shaft that bends or articulates in one or more degrees of freedom, a tip that rolls axially relative to the shaft 15, a shaft that rolls axially relative to the manipulator arm 11. For the sake of simplicity, in
During use, the robotic system controls movement of the robotic manipulator and movement of the end effector (e.g. jaw open/close, tip roll, articulating or bending, etc.) based on surgeon input received by the system via the console 12. The control signals used to generate the various types of movement depend in some cases on the geometry, length, weight, or other parameters of the surgical instrument 14.
The system is configured to allow removal and replacement of surgical instruments 14 during the course of a procedure, so that instruments with different end effector types may be chosen as the surgeon's needs require.
Instruments that can articulate in multiple degrees of freedom can be particularly useful to a surgeon because their dexterity can simplify relatively complex tasks. Some commercially available instruments used in robotic surgery make use of three wire loops (or 6 wires) for control of the instruments degrees of freedom. A first of the loops is dedicated to one degree of freedom—the yaw motion of the instrument. A second loop controls the pitch of one jaw and the third controls the pitch of the second jaw. In the case of bipolar instruments, these instruments also run two additional cables down the instrument shaft. This brings the total number of wires/cables running the length of the shaft to 8 wires.
The described instruments are designed to minimize the overall size of the instrument shaft, as well as reducing the complexity of the assembly and part count. The instrument uses two cable loops to control pitch, yaw and jaw actuation. Some embodiments are configured to enable electrical energy to be passed through the mechanical control cables to deliver monopolar and bipolar energy to the instrument jaws.
Details of a first embodiment of an instrument 200 will next be described with reference to
Referring to
Four drive cables extend through the shaft 202 and links 210, 212 to the end effector: first cables 314a, 314b, which terminate at jaw member 214, and second cables 315a, 315b that terminate at jaw member 215. In this description, cables 314a, 315a may be referred to as “upper cables” and cables 314b, 315b may be referred to as “lower cables”. All orientation references such as these are used for the sake of convenience in describing the orientation of these features in the drawings, and should not be construed to require a particular orientation for the end effector etc.
Each jaw member may include cable guide features around which the cables are routed. In the jaw members shown in the drawings of the first embodiment, the proximal portion of the jaw member is shaped similar to a pulley, with a partially-annular groove 218 having a profile that curves with a constant radius relative to the axis of the pin 216. The groove 218 for jaw member 214 is shown in
Referring again to
From the cable guides 222, the cables extend proximally into the first link 210, which may be a clevis-type link as shown.
Referring again to
The proximal ends of the drive cables 314a-b, 315a-b are engaged with actuators that may be disposed in a housing at the proximal end of the shaft 202. These actuators are driven by or receive mechanical input from drive motors disposed within a component of the robotic surgical system that receives the instrument, such as the terminal portion of the robotic arm. One configuration is shown in commonly owned co-pending application Ser. No. 16/732,307, entitled Compact Actuation Configuration and Expandable Instrument Receiver for Robotically Controlled Surgical Instruments, filed Dec. 31, 2019, which is incorporated herein by reference. The actuators may be configured to receive linear and/or rotational drive input to selectively alter the tension on the drive cables, resulting in movement of the jaws and/or link 212.
Given the arrangement of cables at the end effector, movement in accordance with the following degrees of freedom can be achieved using combination of tension in the respective cables listed on Table 1 below. Note that in the table, “+” means tension is applied to, or increased in, the cable, and “−” means tension is reduced or released. The indications of “up”, “down” are relative to the page of the figures. The indications of “left” and “right” are assuming the user is looking distally down the shaft of the instrument towards the end effector.
An additional degree of freedom of the end effector is that of that axial rolling, which is achieved by rotating the shaft 202 about its axis.
As indicated in Table 1, yaw motion of the end effector in one direction or the other involves simultaneously tensioning both cables associated with one jaw member and simultaneously relaxing both cables associated with the other jaw member. Pitch motion is achieved by pivoting both jaws in the same direction (up or down) about pin 216. As shown in Table 1, upward pitch results when both upper cables 314a, 315a are tensioned while both lower cables 314b, 315b are relaxed, and downward pitch occurs when the lower cables are tensioned and the upper cables are relaxed. The jaws are closed, such as for grasping, by pivoting jaw members 214, 215 towards one another about pin 216. As shown on Table 1, to close the jaws, lower cable 314b of jaw member 214 and upper cable 315a of jaw member 215 are tensioned. To open the jaws, upper cable 314a of jaw member 214 and lower cable 315b of jaw member 215 are tensioned.
The cables may be stainless steel braided cables, tungsten braided cables, or any other tendon, wire or cable having the appropriate strength, durability and other properties for its intended use. Note that in this description the terms “tendon,” “wire,” and “cable” are used broadly to encompass any type of tendon that can be used for the described purpose.
The shaft 202 may be rigid, as may be suitable for use with the systems described in the Background, or it may include an elongate flexible section so that it may be used through flexible (e.g. steerable) cannulas.
The end effector of the instrument 400 has a pair of jaw member assemblies 414, 415. An exploded view of one of jaw member assemblies 415 of the second embodiment is shown in
When the jaw member assembly 415 is assembled, the collar 456 of the jaw member 450 is captured between the medial and lateral pulley sections 452, 454. One of the pulley sections may include an annular post 462 to help retain the jaw member 450 between the pulley section. In this embodiment, the lumen of the collar 456 of the jaw member 450 is disposed over the annular post 462. See
The medial and lateral pulley sections have opposed faces possessing surface geometry that, when they are assembled, define an annular pathway through which the cable is routed. In the illustrated embodiment, an annular rib 464 on one of these pulley sections (shown on the medical section but it may be on either) may contact the opposed face of the other of the pulley sections to define the pathway. As will be understood from viewing
The three primary elements of the jaw member assembly may be keyed or mated together to ensure rotation as a unit during use. Referring to again to
Where the jaw assembly is used for electrosurgical applications, the jaw member 450 is formed of a conductive material, while the medial and lateral pulley sections are formed of insulating materials.
A particular advantage of the disclosed jaw assembly is that it allows a variety of articulating instrument types (e.g. Maryland grasper, needle holder, scissors) to be assembled from sets of components that are identical to one another except for the jaw member 450 itself. In other words, the component parts can be manufactured so that each instrument type can utilize identical medial and lateral pulley sections, but different jaw members 450 having the appropriate jaw shapes.
For electrosurgical instruments, the second embodiment provides the advantages of delivering both mechanical and electrical energy with the same cables, which reduces the number of cables needed for the instrument. This also allows the use of larger cables (for increased strength), or a reduction in the diameter of the instrument shaft than might be achieved using separate electrical and mechanical cables.
Methods and configurations for electrically and mechanically connecting the cables to the jaw members will next be described. The purpose of these concepts is to achieve a mechanical bond between jaw and cable capable of delivering adequate jaw grasping and spreading strength as well as to achieve an electrical bond between jaw and cable capable of reliably delivering electrocautery to the surgical site. These two requirements must be achieved in such a way that the rest of the instrument remains isolated from the electricity passing through the cable to the jaw to prevent undesired tissue damage.
According to a first method, each cable (see cable 415s in
The cable is assembled with the relevant electrically conductive jaw member with the exposed conductive region positioned in electrical contact with the jaw member. When a jaw member of the type used for the
In a slight modification to this embodiment, the hypotube 417 may be coupled to the jaw prior to crimping. For example it might be positioned in the pass-through such as by being welded or otherwise attached to the jaw or seated in a pocket positioned on the jaw.
In an alternative method, the cable is one coated with a dielectric polymer. The jaw is formed with a cable pass-through 460a having a geometry designed such that compression of the pass-through during crimping will pierce the dielectric polymer coating on the cable, creating the electrical connection between cable and jaw. At the same time, the compression of the pass-through creates the mechanical bond between cable and jaw. Referring to
A third method also uses a length of cable coated with a dielectric polymer. In this method, the section of the cable that is to be crimped to the jaw member is identified and the coating in that section is removed prior to crimping the jaw to the cable. Once the segment of coating has been removed, the cable may be inserted through the pass through in the jaw such that the jaw is aligned with the uncoated segment. Once aligned, the jaw is crimped and the compression of the pass through creates the electrical and mechanical connection to the cable beneath the dielectric coating.
A fourth method makes use of a length of cable that is not coated with a dielectric polymer. It is fed through pass-through 460 in the jaw member. The pass-through is compressed in a crimping operation to create the mechanical and electrical connection between cable and jaw. Dielectric material is applied over each portion of the cable extending away from the pass-through, providing electrical isolation along the length of the cable that is outside the pass-through. This dielectric material may be heat shrink tubing or some other tubing applied on the cable, or it might be a dipped or sprayed dielectric coating. If heat shrink tubing is used, the cable will be fed into the tube and the tube shrunk down onto the cable to form a physical barrier between the cable and the rest of the instrument assembly.
A fifth method makes use of two separate cables to form the cable coupled to a jaw. In this configuration, the end of each cable is stripped of the dielectric polymer coating. The stripped ends of both cables are positioned in the pass-through 460 in the jaw member and the pass-through is then compressed in a crimping operation.
Features unique to this invention include the use of a shaped pass through designed to pierce a dielectric coating on a wire during the fabrication of a surgical instrument, and the application of heat shrink tubing to either side of an uncoated cable, after that cable has been crimped to a surgical instrument jaw.
In each embodiment, because the cable is pulled through a series of pulleys and conductive structures for steering the instrument end effector, the insulative coating is sufficiently thick and durable to prevent electrical energy conducted through the cable from passing to components of the instrument that are not intended to be energized.
When both jaws have been crimped to the middle of each coated cable, the assembly of the joints of the instrument can begin. The coated cables are threaded through the pulley structure and down the instrument shaft to the cable control geometry. The exposed free ends of each cable loop are attached to an electrical connector to which a line from an electrosurgical generator unit may be coupled in the operating room. In preferred configurations, there is a service loop between the electrical connector and the actuation mechanism that is configured to engage with the robotic manipulator. The service loop allows the actuation mechanism to progress through its range of motion without imparting stress to the section of cable that is attached to the electrical connector.
Referring to
The wire guide openings 413 may be defined by a single integral component, or they may be defined by a combination of more than one component, depending on the desired material properties of the guiding surfaces.
Arranging the upper proximal pulley stack to have an axis that is offset from the axis of the lower proximal pulley stack standardizes the locations at which the cables exit the end effector, standardizes the cable exit locations and standardizes the impact of cable force to shaft deflection by making sure the cables are all the same distance from the shaft central axis and minimizes the likelihood that the cables routed around the pulleys will rub against internal edges in the instrument shaft.
Referring again to
The proximal ends of the drive cables are engaged with actuators that may be disposed in a housing supported at the proximal end of the shaft 402. These actuators are driven by or receive mechanical input from drive motors disposed within a component of the robotic surgical system that receives the instrument, such as the terminal portion of the robotic arm. One configuration is shown in commonly owned co-pending application Ser. No. 16/732,307, filed Dec. 31, 2019, entitled Compact Actuation Configuration and Expandable Instrument Receiver for Robotically Controlled Surgical Instruments, which is incorporated herein by reference. The actuators may be configured to receive linear and/or rotational drive input to selectively alter the tension on the drive cables, resulting in movement of the jaws and/or link 412.
In use, actuation of the cables in the manner described with respect to the first embodiment produces the types of motion (pitch, yaw and jaw open-close) delineated in that description, and reference should be made to that discussion for details pertaining to those types of motion. As with that embodiment, pitch motion and jaw open-close motion occurs about the axis of pin 416 that extends through the pulleys defined by the lateral and medial pulley sections of each jaw member assembly. Yaw motion occurs about the axis of the pin 428 extending through distal pulleys 428a-d.
A “fleet angle” is an angle between the cable and the plane that the corresponding pulley is rotating on. Referring to
As an alternative to the use of the angled bosses, the angle of the cables at the yaw pulleys could be achieved by opening the tolerance between each yaw pulley 428a-d and its corresponding boss, allowing each of the pulleys 428a-d to tilt on its axis.
Other modifications designed to reduce the angle of the cables may be made in addition to, or as alternatives to, those described in this section. For example, the angle can be reduced by increasing the distance between the axes of the distal pulleys 428a-d and the axes of the proximal pulleys 429a-d, and/or the radius of the pulley portion of each jaw member assembly may be reduced.
While certain embodiments have been described above, it should be understood that these embodiments are presented by way of example, and not limitation. It will be apparent to persons skilled in the relevant art that various changes in form and detail may be made therein without departing from the spirit and scope of the invention. Moreover, features of the different embodiments can be combined in different ways to produce other, different, embodiments. This is especially true in light of technology and terms within the relevant art(s) that may be later developed. Moreover, features of the various disclosed embodiments may be combined in various ways to produce various additional embodiments.
Any and all patents, patent applications and printed publications referred to above, including for purposes of priority, are incorporated herein by reference.
This application is a continuation in part of U.S. application Ser. No. 16/732,306, filed Dec. 31, 2019, which claims the benefit of U.S. Provisional Application No. 62/787,244, filed 31 Dec. 2018, and U.S. Provisional Application No. 62/787,303, filed 1 Jan. 2019.
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File history for commonly owned, co-pending U.S. Appl. No. 16/732,306, filed Dec. 31, 2019. |
File history for commonly owned, co-pending U.S. Appl. No. 17/064,376, filed Oct. 6, 2020. |
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20200375680 A1 | Dec 2020 | US |
Number | Date | Country | |
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62787303 | Jan 2019 | US | |
62787244 | Dec 2018 | US |
Number | Date | Country | |
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Parent | 16732306 | Dec 2019 | US |
Child | 16999943 | US |