The present invention is directed to a surgical instrument with a robotics system, a memory device and an end effector having an elongate channel, knife position sensor(s) and a firing bar coupled to a knife. In response to drive motions initiated by the robotics system, the firing bar may translate within the elongate channel. As the firing bar translates, the sensor(s) transmit a signal to the memory device. The position of the knife may be determined from the output signals and may be communicated to the robotics system or instrument user. The sensors may be Hall Effect sensors.

The present invention is a method for controlling a Davinci surgical device. Firstly, controlling an operation part of a remote operation device to enter the inner of a body for executing a surgical operation. Then, an image capturing unit captures a plurality of corresponding surgical images to a control device, and the control device obtains a first torque component, a second torque component and an element action of the remote surgical device according to the surgical images to operate an output strength of the remote surgical device for further generating corresponding strength feedback by the output strength. Thus, the user can get the control status of the remote surgical device to prevent accidental iatrogenic injury from over-force and to proceed with the operation with improved accuracy.

The various robotic medical devices include robotic devices that are disposed within a body cavity and positioned using a support component disposed through an orifice or opening in the body cavity. Additional embodiments relate to devices having arms coupled to a device body wherein the device has a minimal profile such that the device can be easily inserted through smaller incisions in comparison to other devices without such a small profile. Further embodiments relate to methods of operating the above devices.

A robotic surgical instrument comprising a shaft and end effector element connected by an articulation. The articulation comprises a first joint driveable by a first pair of driving elements. The first joint permits the end effector element to rotate about a first axis transverse to a longitudinal axis of the shaft, the rotation of the end effector element about the first axis bounded by an extreme rotation angle relative to the longitudinal axis. A second joint is driveable by a second pair of driving elements. A pulley arrangement constrains the second pair of driving elements, and comprises a first set of pulleys rotatable about the first axis, and a second set of pulleys located relative to the first set of pulleys such that at the extreme rotation angle the second pair of driving elements is retained in contact with both the first and second sets of pulleys.

Surgical devices and surgical systems are disclosed. The surgical device can comprise an actuator and a control circuit configured to adjust one or more functions of the surgical device based on a signal from a situationally-aware surgical hub. A surgical system can comprise a screen and a control circuit configured to communicate a priority level of a recommendation to the clinician on the display.

Disclosed is a flexible surgical instrument system comprising a flexible surgical instrument and a driving unit. The flexible surgical instrument can comprise a flexible continuous body structure composed of a distal structural body, a proximal structural body and a middle connecting body. The distal structural body can comprise a distal segment, comprising a distal spacing disk, a distal fixation disk and structural backbones. The proximal structural body can comprise a proximal segment comprising a proximal spacing disk, a proximal fixation disk and structural backbones. The middle connecting body can comprise channel fixing plates and a structural backbone guide channel. The driving unit can comprise a driving unit fixing plate. Linear motion mechanisms are provided between the driving unit fixing plate and the channel fixing plate near the proximal structural body, an output end of each of the linear motion mechanisms is securely connected to a first driving backbone.

A medical device includes a link, a first tool member, a second tool member and a third tool member, which each have a proximal end portion movably coupled to the link and a distal end portion. The distal end portion of the first tool member can engage a first object and be associated with a first medical function, the distal end portion of the second tool member can engage a second object and be associated with a second medical function, and the distal end portion of the third tool member can engage the first object or the second object and be associated with the first and/or second medical function. Each of the first, second and third tool members can move relative to the link independent of movement of the each of the other tool members.

A navigation method for a medical operation and implemented by a robotic system is provided. The method includes the steps of: receiving, at a processor of the robotic system, at least one set of navigation data; receiving or generating at least one three-dimensional model of the virtual object in the navigation data; calculating the navigation data to generate a virtual environment and at least one navigation instruction; and presenting, at a user interface associated with the robotic system, the virtual environment and/or the navigation instruction to a user of the robotic system for the user to refer to during the medical operation.

An exemplary embodiment provides a steering gear (13) for a surgical instrument (1) which has two motorised drives and is designed to spatially align a swash plate (14) via the adjustment angles of the two drives, which is designed to control the distal bending mechanism (9) of the surgical instrument (1). The first drive has a first drive pinion (16) which can be driven by a first motor (17) via a first drive shaft (17a) which defines a first drive axis (C) and which is connected to a first drive wheel rim (19) of a first drive wheel (18) in operative connection. The second drive has a second drive pinion (16′) which can be driven by a second motor (17′) via a second drive shaft (17a′) which defines a second drive axis (C′) and is connected to a second drive wheel rim (19′) of a second drive wheel (18′) in operative connection. The first and the second drive wheel (18, 18′) are designed as double wheels (18, 18′), each of which has the corresponding drive wheel rim (19, 19′) and a deviation wheel rim (15, 15′), wherein between the two drive wheels (18, 18′) which have a common axis of rotation (A), the swash plate (14) is arranged, and the deviation wheel rims (15, 15′) are arranged facing each other on the axis of rotation (A). A surgical instrument (1) with such a steering gear (13) is also disclosed.

An exemplary embodiment provides a steering gear (13) for a surgical instrument (1), which can be arranged at the proximal end (3) of a shaft (2) that defines a longitudinal axis (B) and has a bending mechanism (9) at the distal end (5). The steering gear (13) has two controllable and adjustable motorised drives and is designed to transfer the adjustment angles of the two controllable and adjustable motorised drives to a spatial alignment of a swash plate (14) which is designed to control the distal bending mechanism (9) of the surgical instrument (1). The swash plate (14) is arranged in a steering ring (19), and each of the two controllable and adjustable motorised drives has a drive shaft (17a, 17b) driven by a motor (17, 17′), each of which is connected to the steering ring (19) directly and operatively connected via a force transmitter (16, 16′), wherein the two force transmitters (16, 16′) which are arranged on the drive shafts (17a, 17b) each define a drive axis (C, C′), directly contacting the steering ring (19) at an effective section (W). The steering ring (19) is cardanically suspended on a fastening device which has position sensors (23, 24, 25) on its cardan axes. Furthermore, a surgical instrument (1) with a steering gear (13) and a method for controlling the position of a steering ring (19) of a steering gear (13) are disclosed.