GB2550577A - Control system - Google Patents

Abstract

A control system 200 suitable for a robotic surgical system is connected between a robotic surgical instrument 100 and a computer system 200 and has a motherboard with modular components comprising a safety watchdog module 206 which is connected between a plurality of motor controller modules 204 for independently controlled motors and a mains power supply 202 and which monitors at least one parameter of the robotic surgical system, such as temperature, motor current and communications between the computer and control system, and is configured to isolate power from the motor controllers in response to detection by the safety watchdog module of one or parameters deviating from a pre-determined range or exceeding a pre-determined threshold, to prevent erroneous operation and damage or injury to a patient.

Description

CONTROL SYSTEM

FIELD

The present invention provides a control system for a robotic system, particularly, but not exclusively, a robotic surgical system.

BACKGROUND

Traditional laparoscopic manual instruments are composed of a handle, a rigid shaft and a functional end effector, such as graspers, scissors or suction channels for example. Usually, two laparoscopic instruments are used at the same time by a surgeon. The laparoscopic instruments may be located within a single port or within multiple ports. The common characteristics of all these instruments are that motion is transmitted from the handle to the end effector by exploiting the fulcrum effect between the rigid shaft and the port where the instrument is inserted. Generally, instruments used in laparoscopic surgery provide four degrees of freedom. Taking transanal endoscopic micro-surgery as an example, the workspace available to a surgeon is very limited meaning that manoeuvring the handles of prior art instruments to achieve the fulcrum effect is very challenging and instrument collision is common both at the functional end effector and handle.

Manual articulated laparoscopic surgical tools are inherently bulky and provide challenges to surgeons in terms of safely using such tools within a limited workspace. A large amount of research has been undertaken into robotic surgical tools for use in many different medical applications. Examples are: CN104434318 describes an example of a robotic surgical instrument that provides four degrees of freedom. KR100778387 describes a surgery robot for laparoscopic procedures that comprises a hinged elbow function and a rotatable wrist function. US5624398 describes an endoscopic robotic surgical tool that provides a shoulder flexion joint, upper arm rotational Joint, elbow flexional Joint and wrist rotational Joint. US8603135 describes an example of an articulating surgical instrument constructed from a series of links to enable snake-like motion of the surgical instrument.

However, prior art robotic articulated surgical tools are not suitable for use in laparoscopic procedures where space is limited. The prior art robotic articulated surgical tools also do not have sufficient DoF at the tip suitably sized tool tips for use in many laparoscopic procedures.

During surgery, a surgeon is constrained to working within a tightly defined workspace. It is important that the surgeon does not permit surgical instruments to deviate from within the defined workspace or damage could result to a patient. Measures are therefore required to prevent surgical instruments from deviating from the defined workspace. US2005/0166413 describes a robotic arm that can define a boundary prior to use by moving the arm through a pre-determined set of co-ordinates. In use, if the boundary is crossed the arm is disabled to prevent further movement outside of the boundary. US2010174410 describes a robotic arm that is operated by depression of a single operating switch.

Robotic surgery typically involves the use of a port device mounted on a robotic arm. The port device comprises a limited number of lumens for receiving respective surgical tools. Often, surgeons utilise all ports in the port device and require additional tools which have to be used independently of the port device.

The present invention seeks to overcome challenges encountered during transanal robotic endoscopic micro-surgery.

SUMMARY OF THE INVENTION

An aspect of the invention provides a control system for a robotic surgical system comprising a plurality of motor controllers, a safety watchdog module, and a motherboard, wherein the safety watchdog and plurality of motor controllers are operably connected to the motherboard and wherein the safety watchdog module monitors at least one parameter of the robotic surgical system and is configured to isolate power from the motor controllers in response to detection by the safety watchdog module of one or parameters deviating from a pre-determined range or exceeding a pre-determined threshold.

Provision of a safety watchdog beneficially reduces the risk of erroneous operation of a robotic surgical instrument and minimises risk of injury or damage to a patient.

In one embodiment the safety watchdog module and plurality of motor controllers are modular components of the motherboard and can be selectively removed and replaced without removal of other modular components of the motherboard.

The use of modular components reduces the footprint of the robot control system as compared to the prior art and generally increases and optimises the ability to service and upgrade the robot control system.

In one embodiment the plurality of motor controller modules comprise four motor controller modules, wherein each motor controller module is configured to be operably coupled to up to two motors.

In one embodiment each motor controller module has a unique identifier.

In one embodiment the motherboard has an associated address changeable through operation of one or more switching means.

The ability to change the address of the motherboard enables the address of the entire robot control system to be changed to enable more than one robot control system to be operably coupled to a computer system.

FIGURES

The invention will now be described by way of reference to the following figures:

Figure 1 shows a surgical instrument according to aspects of the invention;

Figure 2 shows a first and second section of the surgical instrument of figure 1;

Figure 3 shows an illustrative view of the degrees of freedom of movement of the surgical instrument of figure 1;

Figure 4 shows a further view of the surgical instrument of figure 1;

Figure 5 shows a PTFE catheter for use with embodiments of the invention;

Figure 6 shows an example surgical instrument combining a primary end effector (bipolar) and suction and/or irrigation functionality;

Figure 7 shows an instrument base for coupling a surgical instrument to a robotic arm assembly;

Figure 8 shows a robotic arm according to aspects of the invention;

Figure 9 shows a schematic of a control system for robotic systems;

Figure 10 shows a view of a protective sleeve for use with embodiments of the invention; Figure 11 shows a detailed view of the protective sleeve of figure 10;

Figure 12 shows a view of a end effector adapted to receive a sensor therein;

Figure 13 shows a first view of a needle driver end effector;

Figure 14 shows a second view of the needle driver of figure 13.

DESCRIPTION

Surgical instruments according to aspects of the invention are illustrated generally in figure 1. A surgical instrument (10) comprises a plurality of sections (12, 14, 16, 18, 20, 22) connected to a rigid shaft (24). The rigid shaft (24) is connected to an instrument base (not shown in figure 1). An instrument tip (26), also referred to as an end-effector herein, is connected to the section (22) furthest away from the rigid shaft (24). A first section (12), as illustrated in figure 2, is fixedly connected to the rigid shaft (24) by way of a splined connection (12a). The first section (12) comprises a generally cylindrical body (12b) having the splined connection (12a) at one end thereof and a mounting feature (12c) at the other end thereof. The splined connection (12a) is 4mm long and comprises eight projections (12d) extending radially from a central lumen (12e). Each of the eight projections (12d) are evenly spaced apart with a length of 1.7mm measured from the central axis of the first section (12) and define a scallop (12f) between each adjacent pair of the eight projections (12d). Each scallop (12f) receives a tendon (not shown in figures 2a and 2b) with each tendon passing through the generally cylindrical body (12b) of the first section (12) through a respective hole (12g) arranged around the central lumen (12e). The splined connection (12a) further comprises a locking formation (12h) for restricting or preventing rotation of the first section (12) relative to the rigid shaft (24).

The central lumen (12e) has a cylindrical profile and an internal diameter of between 1.5mm and 3mm.

The mounting feature (12c) comprises an opposite pair of generally semi-circular tabs (12i) extending longitudinally away from the generally cylindrical body (12b). Each generally semicircular tab (12i) has a radius of 0.5m and a thickness of between 0.5mm and 1.5mm. The generally semi-circular tabs (12i) are mounted at the extreme end of the body (12b) and define between them a flattened apex (12J) from which the generally cylindrical body (12b) is chamfered in both directions away from the end of the first section (12) to enable relative movement of an adjacent section (14). The angle of chamfer in each direction is ninety four degrees to enable the adjacent section (14) to hingedly rotate through eighty degrees relative to the first section (12).

The rigid shaft (24), as shown in figure 1, comprises a hollow tube having an outer diameter of 5 mm and an inner diameter of 4 mm. The rigid shaft (24) is formed from stainless steel and is between 200mm and 300mm long. The first end (24a) of the rigid shaft (24) is configured to receive the splined connection (12a) of the first section (12) and restrict rotation of the splined connection (12a) of the first section (12) therein. The rigid shaft (24) is connected at the second end (12b) thereof to an instrument base (not shown in figure 1 or figure 2). The rigid shaft (24) is used to transmit linear translation and axial rotation motion from the instrument base to the end effector (26). All other degrees of freedom are controlled through use of the tendons that pass through the rigid shaft (24) to the surgical instrument sections (12, 14, 16, 18, 20, 22).

The rigid shaft (24) further comprises a complimentary locking formation (24c) for cooperation with locking formation (12h) of the first section (12) to prevent rotation of the first section (12) relative to the rigid shaft (24).

The second section (14), as illustrated in figure 2, is hingedly connected to the first section (12). The second section (14) comprises a generally cylindrical body (14a) having a first end (14b) and a second end (14c). The first end (14b) of the second section (14) comprises a groove of triangular cross section (14d) for receiving the generally semi-circular tabs (12i) of the mounting formation (12c) of the first section (12). The profile of the cylindrical body (14a) of the second section (14) is chamfered away from the triangular groove (14d) in both directions towards the second end (14c). The angle of chamfer in each direction is ninety four degrees to enable relative hinged movement between the first section (12) and the second section (14). The second section (14) further comprises an internal lumen (14e) substantially similar to the internal lumen (12e) of the first section (12).

The second end (14c) of the second section (14) comprises a mounting feature (14f) substantially the same as the mounting feature (12c) of the first section (12). A plurality of holes (14g) for receiving respective tendons pass longitudinally through the cylindrical body (14a) and surround the lumen (14e).

The third and fourth sections (16, 18) are substantially the same as the second section (14) and connected together in a snake like formation. The sections (12, 14, 16, 18) can be arranged to provide hinged movement in any direction as necessary according to intended use of the surgical instrument (10). The second section (14) as illustrated in figure 2 shows the mounting formation (14e) and triangular groove (14d) aligned. In other embodiments, such as illustrated in figure 1, the mounting formation (16a) and triangular groove (16b) are orientated at ninety degrees from one another. It will be appreciated that the orientation of the mounting formation (16a) and triangular groove (16b) can be selected based on the range of motion required for a particular application.

In some embodiments, each of the second, third and fourth sections (14, 16,18) are movable independently of one another to provide maximum dexterity. Other embodiments require less dexterity and two or more adjacent sections may be locked together causing such sections to move in unison.

Figure 3 illustrates the degrees of freedom of movement of a surgical instrument (10) according to aspects of the invention. The arrows shown indicate the general direction of movement of each component of the surgical instrument (10).

The rigid shaft (24) imparts translational movement and axial rotation to the surgical instrument (10). None of the sections (12, 14, 16, 18, 20, 22) or end effector (26) have the independent ability to translate or rotate around the axis of the surgical instrument (10). The first section (12) is positionally fixed relative to the rigid shaft (24). The second section (14) defines an elbow Joint with the first section (12) and is hingedly movable relative to the first section (12) through an angular range of movement of eighty degrees. The third section (16) defines an elbow joint with the second section (14) and is hingedly movable relative to the second section (14) through an angular range of movement of eighty degrees. The fourth section (18) defines an elbow joint with the third section and is hingedly movable relative to the third section (16) through an angular range of movement of up to eighty degrees. In some embodiments the angular range of movement is sixty degrees.

The fifth section (20) and sixth section together define part of the wrist joint of the surgical instrument (10). The fifth section (20) defines an elbow with the fourth section (18) and is hingedly movable relative to the fourth section (18). The fifth section (20) also defines a separate hinged joint (21) with the sixth section (22). The sixth section (22) is hingedly movable relative to the fifth section (20). The sixth section (22) defines a hinged connection (27) with an end effector (26) which is arranged perpendicular to the hinged connection between the fifth section (20) and sixth section (22). The hinged connection (27) between the sixth section (22) and end effector (26) and the hinged connection (21) between the fifth section (20) and sixth section (22) together define all DoF provided by the wrist joint.

In some embodiments, each of the sections (14, 16, 18, 20, 22) is independently movable relative to adjacent sections (14, 16, 18, 20, 22) This arrangement enables the surgical instrument (10) to be manoeuvred in a snake like manner to provide an optimised motion path for a surgeon during surgery. In other embodiments sections (14, 16, 18, 20) may be coupled to adjacent sections (12, 14, 16, 18, 20) such that one or more adjacent sections (14, 16, 18, 20) move together.

As shown in figure 4, tendons (28) passing through the lumen in the rigid shaft (24) and through respective holes in each section (12,14, 16, 18, 20, 22) and end effector (26) are used to provide independent control to each respective section (12, 14, 16, 18, 20, 22) and end effector (26). Each section (12, 14, 16, 18, 20, 22) and end effector (26) is associated with an antagonistic pair of tendons (28). By antagonistic it is meant that tensioning one of the pair of antagonistic tendons will result in movement of a section (12, 14, 16, 18, 20, 22) or end effector (26) in one direction and tensioning of the other of the pair of antagonistic tendons will result in movement of a section (12, 14, 16, 18, 20, 22) or end effector (26) in the other direction.

Each one of a pair of antagonistic tendons (28) is terminated at a section (14,16,18, 20, 22) or end effector (26). Termination of tendons (28) is effected by collapsing the tendon holes (12g -for the first section) through the relevant section (14, 16, 18, 20, 22) or end effector (26) to prevent further movement of the tendons (28) relative to that section (14, 16, 18, 20, 22) or end effector (26).

Tendons (28) associated with control of sections (18, 20, 22) located nearer to the end effector (26) pass through the neutral axis of the bending plane of adjacent sections to reduce motion coupling between adjacent sections.

In some embodiments only a selected number of sections are required to be independently controlled. In such embodiments, tendons (28) provide passive control to those sections not associated with a pair of terminated antagonistic tendons (28). Such an embodiment might be used in a surgical instrument used for cutting tissue where high manual dexterity is not needed. Surgical instruments used for manipulating tissue or using a needle and thread need a greater degree of manual dexterity.

The lumens (12e, 14e, for example) in each section in some embodiments are fitted with a multi-lumen polytetrafluoroethylene (PTFE) catheter (30) as shown in figure 5. The PTFE catheter (30) comprises a generally cylindrical rod (30a) having a plurality of lumens (30b) therethrough surrounding a central lumen (30c). Each of the plurality of lumens (30b) is configured to receive a tendon for independent control of the end effector (26).

The PTFE catheter (30) assists in keeping the tendons for controlling the end effector passing therethrough as close as possible to the bending axis of the surgical instrument (10) to prevent a joint coupling effect between adjacent hingedly connected components of the surgical instrument (10). The PTFE catheter (30) additionally assists to reduce friction between adjacent tendons (28) and between tendons (28) and elbow Joints.

The tendons for the end effector (26) are shrouded by Bowden cables (28a), i.e. a flexible cable used to transmit mechanical force or energy by the movement of an inner cable relative to a hollow outer cable housing. The PTFE catheter (30) is only needed if the end effector (26) comprises an articulated tool providing a further degree of freedom of positioning such as a grasper or scissors.

In place of the PTFE catheter (30), the lumen (12e, 14e, for example) through each of the elbow Joints can receive a flexible suction and/or irrigation tube (32) as shown in figure 6. The flexible tube (32) is intended for use with either a monopolar knife or bipolar tweezers. Both types of tool require electricity to be supplied to the tip of the end effector (26). In the case of a monopolar tool, electricity is conveyed to the tip of the end effector (26) through the metal structure of the end effector (26). In the case of bipolar tweezers, electricity is conveyed to one side of the tweezers by the metal structure of the end effector (26). An electrical wire conveys electricity from the electrified tweezer side to the other tweezer side which is otherwise electrically isolated from the first side.

The instrument base (34), as shown in figures 7a to 7d, comprises six motor couplings (36) each associated with respective capstans (38) around which individual tendons (28) are wound. Each motor coupling (36) on the instrument base (34) comprises a plurality of holes (40) for engagement with a plurality of corresponding pins (42) on a corresponding motor coupling (44) on a motor pack (46). Each motor coupling (44) on the motor pack (46) is associated with a respective independently driven motor. Each motor coupling (36) on the instrument base (34) is made from medical grade polyetheretherketon.

Upon attaching the instrument base (34) to the motor pack (46), the motor couplings (36) on the instrument base (34) are each coupled to respective corresponding motor couplings (44) on the motor pack (46) by rotating the motor couplings (36, 44) on either the instrument base (34) or motor pack (44) until the pins (42) on the motor couplings (44) on the motor coupling (46) engage with the holes (40) on the motor couplings (36) on the instrument base (34). Either or both of the motor couplings (36, 44) on the instrument base (34) and/or motor pack (46) are spring loaded to provide a positive engagement between the pins (42) on the motor couplings (44) on the motor pack (46) and the holes (40) on the motor couplings (36) on the instrument base (34). The instrument base (34) is secured to the motor pack (46) by inserting a locking pin (48) through a locking feature (50) on the motor pack (46) and into a corresponding locking feature (52) on the instrument base (34).

Each motor coupling (36) on the instrument base (34) is associated with driving a capstan (38) to wind a tendon (28) for operating a section (12, 14, 16, 18, 20, 22) or end effector (26). An idle gear (55) (as shown in figure 7b) is positioned between two capstans. A gear ratio of 2:1 to between the two capstans reflect the tendon travel difference between the two parallel joints to enable a single motor to drive the two capstans to achieve the desired actuation of the two parallel Joints between sections (12, 14, 16). The Joints between sections (16, 18, 20) are coupled in the same way by another idle gear on the other side of the instrument base (34). A translation gear (54) is attached to a motor output shaft directly. The gear (54) drives the instrument and motor pack moving along a rack (not shown) for linear translation.

The end effector (26) can be a grasper, needle driver or scissors, for example and is coupled to the final section (20) of the surgical instrument (10) by way of an end effector (22). The end effector (26) is coupled to the final section (22) of the surgical instrument (10) by way of a hinge arrangement orientated perpendicularly to the hinged coupling between the fourth section (18) and final section (22). The hinged coupling between the final section (22) and end effector (26) is also perpendicular to the hinged coupling between the fifth section (20) and sixth section (22).

Examples of end effector (26) described by aspects of the invention include: i) a wristed grasper - seven degrees of freedom tool with grasper Jaws which can be either straight or curved and which is used to manipulate tissue, ii) wristed scissors - seven degrees of freedom wristed tool with scissor blades used to cut tissue with either curved or straight blades, iii) non-wristed scissors - six degrees of freedom tool with scissor blades used to cut tissue with either curved or straight blades, iv) wristed needle driver - seven degrees of freedom tool with straight short Jaws having a diamond shaped knurling to grip onto surgical needles, v) non-wristed needle driver - six degrees of freedom tool with straight short Jaws having a diamond shaped knurling to grip onto surgical needles, vi) monopolar knife with suction/irrigation - a four degree of freedom multi-functional tool without wrist Joint and Jaws used for tissue re-section, tissue cauterization, suction of liquid/smoke and irrigation, vii) Bipolar tweezers with suction/irrigation - a five degree of freedom non-wristed multifunctional tool having one moving Jaw and used for tissue resection, tissue cauterization, suction of liquid/smoke and irrigation, viii) non-wristed grasper tools. A particular example of end effector (26) is a Jawed grasper (400) having a pair of opposed Jaws. Each Jaw (400a) of the end effector (26) is formed of unitary construction and comprises a gripping surface (400b) defined by the internal surface of an elongate member (400c). The elongate member (400c) further comprises a recess (400d) opposite the gripping surface (400b). The recess (400d) extends longitudinally along the elongate member (400c) and is configured to receive a sensor (402) shaped to correspond with the overall profile of the elongate member (400c). The elongate member (400c) is joined to a mounting boss (400e) defined by two spaced apart plates (400f, 400g) having a gap therebetween. A mounting hole (400h) passes through the mounting boss (400e) for receiving a pivot (not shown).

The sensor (402) has a first insertion portion (402a) and a second insertion portion (402b) which are cooperable with a respective first receiving portion (400i) and second receiving portion (400J) of the elongate member (400c) of the jaw (400a). The sensor (402) can be a force sensor, temperature sensor, tactile sensor, for example.

Another example of end effector (26) is a needle driver (500) as illustrated in figures 13 and 14. The needle driver (500) is fixedly coupled to the final section (20) of the surgical instrument (10) by way of a splined connection (20a). The needle driver (500) comprises a body (502) having a mounting arrangement (504) co-operable with each of a pair of opposed grasping jaws (506, 508). The mounting arrangement (504) facilitates pivotal movement of a mounting part of each jaw (506, 508) to permit the jaws (506, 508) to open and close by way of a pin (510) passing through each jaw (506, 508) and the body (502). As shown in figure 13, there are two pins (510), one for each jaw (506, 508), which are spaced apart laterally and positioned adjacent the edge of the body (502) and terminate in a groove (512) on each of opposing sides of the body (502).

Movement of the jaws (506, 508) is controlled by a tendon (514) and a spring (516). The jaws (506, 508) are biased in an open position by the spring (516). The spring (514) tension is overcome by tensioning the tendon (514) to close the jaws (506, 508).

The motor pack (46) is selectively mountable to a robotic arm (100) or to a port as described in further detail below.

The robotic arm (100), as shown in figure 8, comprises six electromagnetically braked joints (102, 104, 106, 108, 110, 112). The electromagnetic brakes are biased in an on position and releasable by depression of two operation switches (114, 116) located on a handle (118). The robotic arm (100) is mountable to a hospital bed by way of a mounting formation (120) coupled to the robotic arm (100).

The mounting formation (120) is coupled to an anchor (122). The anchor (122) is coupled to a shoulder (124) by way of a first electromagnetically braked joint (102). The anchor (122) provides horizontal rotation relative to the shoulder (124). The shoulder (124) is coupled to a horizontal shaft (126) by way of a second electromagnetically braked joint (104). The shoulder (124) provides pivotal rotation relative to the horizontal shaft (126) in the direction of the longitudinal axis of the horizontal shaft (126). The horizontal shaft (126) extends through a third electromagnetically braked joint (106). The horizontal shaft (126) provides rotational positioning relative to the shoulder (124). The opposite end of the horizontal shaft (126) is coupled to a fourth electromagnetically braked joint (108). The fourth electromagnetically braked joint (108) is coupled to a vertical shaft (128). The vertical shaft (128) provides rotational positioning relative to the horizontal shaft (126). The vertical shaft (128) is coupled at the other end to a fifth electromagnetically braked joint (110). The fifth electromagnetically braked joint (110) is coupled to an elbow (130). The elbow (130) provides rotational positioning around a horizontal axis parallel to the horizontal axis of the horizontal shaft (126). The elbow (130) is coupled to a sixth electromagnetically braked joint (112) at the other end thereof. The sixth electromagnetically braked joint (112) is coupled to the handle (118). The handle is free to rotate around a vertical axis in order to position an adaptor (132) coupled to the handle (118).

The adaptor (132) mounts the motor pack (46) and consequently the surgical instrument (10) to the robotic arm (100).

In use, the robotic arm (100) is mounted to a standard operating table by way of the mounting formation (120) which clamps the robotic arm (100) to the side rails of the standard operating table. The robotic arm (100) and surgical instrument (10) are both electrically powered from a mains supply power outlet through an AC/DC power adaptor. The power supply controls each of the electromagnetically braked joints (102, 104, 106, 108, 110, 112) with electromagnets associated with each being locked in place unless the operation switches (114, 116) on the handle (118) are depressed. Upon depression of both operation switches (114, 116) on the handle (118), all electromagnets are released permitted an operator to manoeuvre the robotic arm (100) through all six electromagnetically braked joints (102, 104, 106, 108, 110, 112). Once the robotic arm (100) is in the desired position the operating switches (114,116) on the handle (118) are released by the operator and all electromagnets are applied to lock all six electromagnetically braked joints (102,104,106,108, 110,112). The electromagnets will only be released if both operation switches (114, 116) on the handle (118) are depressed. If only one operation switch (114,116) is depressed, none of the electromagnets will be released and the operator will not be able to manoeuvre the robotic arm (100) through any of the electromagnetically braked joints (102, 104, 106, 108, 110, 112). This is a safety feature to prevent inadvertent movement of the robotic arm (100).

Once a motor pack (46) is mounted to the adaptor (132) and a surgical instrument (10) is coupled to the motor pack (46), power is applied to the motor pack by way of a mains power supply. The motor pack (46) is controlled by a robot control system (200) as illustrated in figure 9.

The robot control system (200) is powered by a separate mains power supply (202) and comprises a plurality of motor controller modules (204), four are shown in figure 9, and a safety watchdog module (206). The safety watchdog (206) is connected between the mains power supply (202) and the plurality of motor controller modules (204). The robot control system (200) is connected between the robotic surgical instrument (100) and a computer system (208). The robot control system (200) is further provided with an emergency stop button (210) for cutting all power to the robot control system (200) and thus the surgical instrument (10). A master manipulator (212) is connected to the computer system (208). The computer system (208) interprets movement of the master manipulator (212) to determine the desired action of the surgical instrument (10) and sends appropriate instructions to the robot control system (200) via a RS-485 bus to drive the plurality of motor controllers (204).

The safety watchdog module (206) monitors a number of parameters of the robot control system (200) and/or surgical instrument (10) such as temperature and motor current for example. If the safety watchdog module (206) detects that a parameter has deviated from a pre-determined range or exceeded a pre-determined threshold, the safety watchdog module (206) will cut all power to the motor controller modules (204) to prevent erroneous operation and/or damage/injury to a patient. The safety watchdog module (206) also listens to communication between the computer system (208) and robot control system (200) and between the robot control system (200) and the surgical instrument (10). If instructions are detected that fall outside of accepted operating parameters the safety watchdog module (206) will cut all power to the robot control system (200) to prevent erroneous operation and/or damage/injury to a patient.

The safety watchdog module (206) is a modular component that plugs into a motherboard (214). Each motor controller module (204) is also a modular component that plugs into the motherboard (214). Each motor controller module (204) can control up to two motors and the motherboard (214) can accommodate up to four motor controller modules (204) allowing connection of up to eight motors for driving the robotic surgical instrument (100). This disclosure is not intended to be limiting; other embodiments may be capable of accommodating further motor control modules and each motor control module may be capable of controlling one, two or more motors.

The adaptor (132) includes an electrical connector (134) which can supply power and control signals via the internal wiring of the robotic arm (100). The motor pack (46) can be powered and controlled via either the electrical connection (134) or independent cables.

To ensure that the surgical instrument (10) is only movable within a pre-defined boundary, a three dimensional boundary space or spatial threshold is defined prior to commencing surgery. The three dimensional boundary space is defined by moving the robotic arm (100) through a series of spatial points and recording each spatial point as a boundary point. The robotic arm during surgery is only permitted to move within the three dimensional boundary and is automatically locked should it hit, or in some instances approach, the three dimensional boundary.

Once movement of the robotic arm (100) is locked, there are a number of ways that it can be unlocked to resume surgery. Two examples will now be described.

In a first example, the robotic arm (100) comprises a rotary encoder that monitors every movement of each of the electromagnetically braked joints (102, 104, 106, 108, 112) and the surgical instrument end effector (22). Each movement is recorded as a data point relative to a respective origin point. The rotary encoder permits each electromagnetically braked joint (102, 104, 106, 108, 110, 112) and thus the surgical instrument end effector (22) to move through each data point in reverse. Once each data point is determined as being equal to a respective origin point, each of the electromagnetically braked joints (102,104,106,108,110, 112) is fully released.

In a second example, force detection means are associated with each of the electromagnetically braked Joints (102, 104, 106, 108, 110, 112). A processor equates a force applied by a surgeon to a master manipulator (212) to direction and unlocks the electromagnetically braked Joints (102, 104, 106, 108, 110, 112) if it is determined that all of the electro magnetically braked joints (102, 104, 106, 108, 110, 112) and the surgical instrument end effector (22) would be moved away from the three-dimensional boundary. If it is determined that one or more of the electromagnetically braked Joints (102, 104, 106, 108, 110, 112) and/or the end effector (22) would be moved towards or cross the three-dimensional boundary, each of the electromagnetically braked Joints (102,104,106,108,110, 112) would remain locked and movement would be resisted.

Referring to figures 10 and 11, a protective sleeve (300) for use with surgical instruments (10) of embodiments of the invention is shown. The protective sleeve (300) comprises an elongate sheath (302) that has a first end (302a) and a second end (302b). The elongate sheath is formed from a thin plastic material and is flexible and compressible. The first end (302a) of the elongate sheath (302) is attachable to a surgical instrument by way of an attachment interface (304). The attachment interface may comprise a locking means such as a twist locking mechanism or snap fit interface or may be magnetic. The second end (302b) of the elongate sheath (302) defines an interface for attachment of an end closure (306) such as a duckbill valve or other type of suitable valve. The end closure (306) may be attached to the second end (302b) of the elongate sheath (302) by way of a locking means or magnetic attachment, for example.

In use, the end effector end of a surgical instrument (10) is inserted into the protective sleeve (300) after sterilisation. The protective sleeve (300) is attached to the surgical instrument (10) by way of the attachment interface (304). The surgical instrument (10) is inserted into a lumen of a port immediately prior to start of surgery. In embodiments utilising a magnet to attach the closure means (306) to the second end (302b) of the protective sleeve (300), the magnet is used to align the surgical instrument (10) with the lumen of the port. The closure means (306) is sized appropriately to enable it to extend through the lumen of the port. As the surgical instrument (10) is advanced, the surgical instrument (10) penetrates through the valve (306) and the protective sleeve (300) is compressed within the port to expose the surgical instrument (10).

Upon conclusion of surgery, the surgical instrument (100) is withdrawn from the patient and through the port into the protective sleeve (300). The surgical instrument passes back through the valve which closes once the surgical instrument is again fully enclosed by the protective sleeve (300). Prior to re-use, the surgical instrument is sterilised through autoclave, gas or radiation treatment and a new protective sleeve (300) is fitted to the surgical instrument (100). The used protective sleeve (300) is discarded as hazardous waste after surgery.

Claims (7)

1. A control system for a robotic surgical system comprising a plurality of motor controllers, a safety watchdog module, and a motherboard, wherein the safety watchdog and plurality of motor controllers are operably connected to the motherboard and wherein the safety watchdog module monitors at least one parameter of the robotic surgical system and is configured to isolate power from the motor controllers in response to detection by the safety watchdog module of one or parameters deviating from a pre-determined range or exceeding a pre-determined threshold.

2. A control system for a robotic surgical system according to claim 1, wherein the safety watchdog module and plurality of motor controller module are modular components of the motherboard and can be selectively removed and replaced without removal of other modular components of the motherboard.

3. A control system for a robotic surgical system according to claim 1 or claim 2, wherein the plurality of motor controllers comprises up to four motor controllers.

4. A control system for a robotic surgical system according to any of claims 1 to 3, wherein each of the plurality of motor controllers is configured to be selectively connectible to up to two independently controlled motors.

5. A control system for a robotic surgical system according to any preceding claim, wherein each motor controller module has a unique identifier.

6. A control system for a robotic surgical system according to any preceding claim, wherein the motherboard has an associated address changeable by operation of one or more switching means.

7. A control system for a robotic surgical instrument substantially as described with reference to, and or as shown in, figure 9.