Disclosed are systems, apparatus, and methods for performing robotic surgery, including a surgical robot having a plurality of robotic arms, an image capture device operably coupled to a first one of the plurality of robotic arms and a light source, a surgical tool operably coupled to a second one of the plurality of robotic arms and a light sensor, and a computing device including a processor and a memory storing instructions which, when executed by the processor, cause the computing device to determine whether the light sensor coupled to the surgical tool is detecting at least a predetermined amount of light emitted by the light source coupled to the image capture device, and provide a notification when it is determined that the light sensor coupled to the surgical tool is not detecting at least the predetermined amount of light emitted by the light source coupled to the image capture device.

An overtube including: a connector body defining a lumen through which an insertion section of an endoscope is insertable along a longitudinal axis extending through a distal opening and a proximal opening of the lumen; and a connecting mechanism including: a connector movably attached to the connector body, wherein the connector is configured to define a stable equilibrium first position radially away from the longitudinal axis, and to be moved by a radial force from the stable equilibrium first position to a second position radially closer to the longitudinal axis than the first position, and wherein, in the second position, the connector is configured to engage the insertion section to limit relative movement of the connector body and the insertion section along the longitudinal axis while allowing the connector body to be rotated by a drive force relative to the insertion section along the longitudinal axis.

A remote control apparatus to remotely control a patient-side system including medical equipment and an endoscope to capture an image of a surgery site according to an embodiment includes: an operation handle with which an operator controls the medical equipment; and an operation pedal section. The operation pedal section includes: plural pedals configured to be pressed down to execute functions concerning the medial equipment; and a base on which the plural pedals are arranged, the plural pedals being arranged at locations not overlapping each other in a planar view. The plural pedals include first height pedals with upper ends thereof located at a first height position and second height pedals with upper ends thereof located at a second height position, which is different from the first height position. The first height pedals are arranged alternately with the second height pedals.

A long serial mechanism (LSM) extends from an actuator, distally along a chain of links. Each link comprises a moving mechanism (MM), actuation of which adjusts a position of the link with respect to another of the links. The LSM comprises a shaft, and a series of driving mechanisms (DMs) coupled to the shaft at each link. The LSM has (i) an engaging state in which each DM can potentially transfer rotation of the shaft into actuation of a respective MM, and (ii) a neutral state in which the DMs cannot transfer rotation. Via only (i) transitioning the shaft between the neutral state and the engaging state, and (ii) rotation of the shaft, the actuator is able to cause actuation of the first MM independently from actuation of the second MM, and actuation of the second MM independently of actuation of the first MM. Other embodiments are also described.

Advances in endoscope inspection systems to provide for evidence of the cleanliness of critical portions of the instrument's interior. Utilizing borescope sensing technology, the precise location of the borescope within the endoscope can be repeatedly established is in order to establish the healthy condition of the endoscope. Light intensity of cleaning paraphernalia may be adjusted to prevent endoscope damage.

A surgical instrument is inserted through a guide tube. The surgical instrument exits at an intermediate position of the guide tube and is oriented to be substantially parallel to the guide tube's longitudinal axis as it exits. A stereoscopic image capture component is on the guide tube between the intermediate position and the guide tube's distal end. The image capture component's field of view is generally perpendicular to the guide tube's longitudinal axis. The guide tube is jointed to allow the image capture component to be moved. The surgical instruments and the guide tube are telemanipulatively controlled.

A surgical robotic system automatically calibrates tubular and flexible surgical tools such as endoscopes. By compensating for unideal behavior of an endoscope, the surgical robotic system can accurately model motions of the endoscope and navigate the endoscope while performing a surgical procedure on a patient. During calibration, the surgical robotic system moves the endoscope to a target position and receives data describing an actual position and/or orientation of the endoscope. The surgical robotic system determines gain values based at least on the discrepancy between the target position and the actual position. The endoscope can include tubular components referred to as a sheath and leader. An instrument device manipulator of the surgical robotic system actuates pull wires coupled to the sheath and/or the leader, which causes the endoscope to articulate.

Devices for use with introducers, endoscopes and catheters, where the devices relate to an articulating mechanism that allows a working end of a medical device to be steerable in order to access or visualize targeted sites in the interior of a patient's body.

A surgery manipulator arm according to an embodiment may include an arm body and a translation mechanism provided to a distal end portion of the arm body. The translation mechanism includes: a proximal side unit connected to the distal end portion of the arm body; a distal side unit including a tool holding part to which a surgical tool is attached; a connection unit connecting the proximal and distal side units; and an electrical wiring circuit electrically connecting the proximal and distal side units. The connection unit includes first and second pulleys; and a belt member wound around the first and second pulleys. The proximal and distal side units are attached to first and second attachment positions of the belt member such that the distal side unit moves in a direction opposite to a direction in which the proximal side unit moves in association with movements of the belt member.

A robotic medical system can include a first node, a second node, and a first pair of electrical conductors for differential communication between the first node and the second node so that data signals are communicated between the first node and the second node as differential signals. The first node can include a first electrical circuit electrically coupled with the first pair of electrical conductors. The first electrical circuit can communicate emergency stop signals between the first node and the second node as non-differential signals over the first pair of electrical conductors.