A method for controlling a temperature at an end-effector of an instrument connected with a controller includes estimating a residual energy associated with a prior application of base energy to the end-effector based on a first set of parameters. An amount of electric power that is converted to heat at the end-effector is estimated based on the first set of parameters. A current temperature at the end-effector is estimated based on: (i) the residual energy, (ii) the amount of electric power provided to the end-effector, and (iii) a time for which the electric power is provided. The electric power provided to the instrument is controlled to maintain the current temperature at the end-effector within a predetermined range.

A surgical system includes a power tool that generates torque; a torque sensor for measuring a torque characteristic of the power tool; a user interface; at least one processor; and a memory. The memory stores instructions for execution by the at least one processor that, when executed, cause the at least one processor to: receive torque data from the torque sensor, the torque data corresponding to the measured torque characteristic; evaluate the torque data; and execute a predetermined action based on the evaluation.

Provided is a system and medical device that includes self diagnosing control switches. The control switch may be slidable within a slot in order to control activation of some function of the medical device. Due to natural wear and tear of movement of a control switch, the distances along the sliding slot that correspond to how much energy is used for the function may need to be adjusted over time in order to reflect the changing physical attributes of the actuator mechanism. The self diagnosing control switches of the present disclosures may be configured to automatically adjust for these thresholds using, for example, Hall effect sensors and magnets. In addition, in some cases, the self diagnosing control switches may be capable of indicating external influences on the controls, as well as predict a time until replacement is needed.

A robotic surgical tool includes a tool driver, a drive housing mountable to the tool driver and including one or more component parts made of or including a magnetically responsive material, a first inductor coil included on the tool driver and configured to generate a magnetic field, and a second inductor coil included on the drive housing and configured to measure an intensity of the magnetic field and a field distortion caused by the one or more component parts. A change in the field distortion provides an indication of movement of the one or more component parts.

In a puncture needle gripping device that grips a puncture needle that punctures a target in a patient's body and a puncture robot having the puncture needle gripping device, a puncture needle gripping device that can release the puncture needle gripped by the puncture needle gripping device by a remote control, and a puncture robot having the puncture needle gripping device are provided. A puncture needle gripping device includes a first finger and a second finger that pinches a proximal end of a puncture needle therebetween, and a releasing mechanism that grips the puncture needle by pinching the proximal end of the puncture needle between the first finger and the second finger and releases the puncture needle by separating the first finger and the second finger from each other by remote control.

A surgical stapling instrument comprising an end effector, an RFID tag, and a control circuit is disclosed. The end effector comprises an anvil, a staple cartridge, and a contact assembly configured to contact tissue. The staple cartridge comprises staples removably stored therein. The anvil and the staple cartridge are configurable between an open configuration and a closed configuration. The RFID tag is configured to store information about the staple cartridge. The control circuit is operably coupled to the contact assembly. The control circuit is configured to interrogate the RFID tag to determine the information about the staple cartridge, transmit an electrical signal to tissue contacting the contact assembly, determine a characteristic of the tissue contacting the contact assembly based on the electrical signal, and change an operational parameter of the surgical stapling instrument based on the characteristic of the tissue.

A surgical device drive system comprising a gear coupled to a drive train is disclosed. The gear is configured to transmit a proximal retraction motion to a drive member. The surgical device drive system further comprises a control system coupled to the gear, and a manual input device comprising an input component and a ratchet mechanism. The input component is selectively coupled to the gear by the ratchet mechanism. The drive train is operable in a distal advancement direction and in a proximal retraction direction. In a first state, the control system is configured to drive the gear and the drive train in the distal advancement direction and the proximal retraction direction. In a second state, the manual input device is configured to drive the gear and the drive train in the proximal retraction direction, but not the distal advancement direction, using the ratchet mechanism.

A method for robot-assisted minimally invasive surgery involves calculating, based on a surgical plan, an insertion vector for an MIS port; causing a robotic arm to hold the MIS port in a pose that corresponds to the insertion vector; detecting, with a sensor on the robotic arm, a force applied to the robotic arm via the MIS port; maintaining the MIS port in the pose when the detected force is lower than a predetermined threshold; and generating an alert when the detected force exceeds the predetermined threshold.

A surgical instrument. The surgical instrument includes an elongated channel, an anvil pivotably connected to the elongated channel, a closure member mechanically coupled to the anvil, an electric motor mechanically coupled to the closure member, a motor controller electrically coupled to the electric motor and a control circuit electrically connected to the motor controller. The control circuit is configured to monitor a first predefined event, monitor a second predefined event, provide a stop signal to the motor controller to stop a closing motion of at least one of the elongated channel and the anvil after an occurrence of the first predefined event, and provide a start signal to the motor controller to start the closing motion of the at least one of the elongated channel and the anvil after an occurrence of a second predefined event.

A powered surgical cutting and stapling instrument is disclosed. The instrument includes at least one sensor to measure at least one parameter associated with the instrument, at least one processor, and a memory operatively associated with the processor. The memory includes machine executable instructions that when executed by the processor cause the processor to monitor the at least one sensor over a predetermined time period and determine a rate of change of the measured parameter.