A surgical stapling device includes a handle assembly, an adapter assembly, and a reload assembly that is releasably secured to the adapter assembly to facilitate replacement of the reload assembly after each use of the stapling device. The reload assembly includes an authentication chip and printed circuit board assembly that is constructed to provide electrical contacts that are self-supporting to allow for automated assembly of the electrical contacts and provide a more reliable, robust electrical connection between the electrical contacts and the chip.

A system and related methods of preventing wrong-site surgeries and blade-related injuries to OR personnel, which includes a computer software system (for use on computers or hand-held devices in the medical environment) in combination with a surgical supply carrier (such as a safety blade-dispenser or other surgical sharps dispenser). The surgical supply carrier comprises at least one component, such as a label, which prevents or impedes a surgeon from accessing one or more surgical instruments stored within until after a “time-out” is performed by the surgeon or authorized OR personnel to confirm various details including but not limited to correct patient, correct procedure, correct equipment, etc, before starting the intended surgical procedure. Data can be captured throughout the medical environment (from “decision-to-incision” and beyond) to assess wrong-site surgery data (including “near miss” data) and enable a host of analytics on wrong-site surgery prevention.

A distraction system can include a distraction implant comprising a magnetic element and a distraction mechanism configured to expand the distraction implant in response to rotation of the magnetic element. The distraction system can include an external device comprising a motor configured to rotate a driver magnet while in a powered state, the driver magnet configured to rotate the magnetic element, a computing device configured. The computing device can be configured to measure an electrical current drawn by the motor during rotation of the driver magnet. The computing device can be configured to maintain the motor in the powered state in response to a mean value of the electrical current being greater than or equal to a mean value threshold, and a standard deviation value of the electrical current being less than or equal to a standard deviation threshold.

A distraction system can include a distraction implant comprising a magnetic element and a distraction mechanism configured to expand the distraction implant in response to rotation of the magnetic element. The distraction system can include an external device comprising a motor configured to rotate a driver magnet while in a powered state, the driver magnet configured to rotate the magnetic element, a computing device configured. The computing device can be configured to measure an electrical current drawn by the motor during rotation of the driver magnet. The computing device can be configured to maintain the motor in the powered state in response to a mean value of the electrical current being greater than or equal to a mean value threshold, and a standard deviation value of the electrical current being less than or equal to a standard deviation threshold.

Embodiments are directed to a medical robot system including a robot coupled to an end-effectuator element with the robot configured to control movement and positioning of the end-effectuator in relation to the patient. One embodiment is a method for removing bone with a robot system comprising: taking a two-dimensional slice through a computed tomography scan volume of target anatomy; placing a perimeter on a pathway to the target anatomy; and controlling a drill assembly with the robot system to remove bone along the pathway in the intersection of the perimeter and the two-dimensional slice.

Embodiments are directed to a medical robot system including a robot coupled to an end-effectuator element with the robot configured to control movement and positioning of the end-effectuator in relation to the patient. One embodiment is a method for removing bone with a robot system comprising: taking a two-dimensional slice through a computed tomography scan volume of target anatomy; placing a perimeter on a pathway to the target anatomy; and controlling a drill assembly with the robot system to remove bone along the pathway in the intersection of the perimeter and the two-dimensional slice.

A method facilitates touchless control of medical equipment devices in an OR. The method involves: providing a three-dimensional control menu, which comprises a plurality of menu items selectable by the practitioner by one or more gestures made in a volumetric spatial region corresponding to the menu item; displaying an interaction display unit (IDU) image corresponding to the three-dimensional control menu to provide indicia of any selected menu items; estimating a line of sight of a practitioner; and when the estimated line of sight is directed within a first spatial range around a first medical equipment device, determining that the practitioner is looking at the first medical equipment device. Then the method involves providing a first device-specific three-dimensional control menu displaying a first device-specific IDU image.

An apparatus comprises an electrically power surgical instrument having a handle assembly. The apparatus also comprises a communication device positioned within the handle assembly. The communication device is operable to communicate with at least a portion of the electrically powered surgical instrument. The apparatus further comprises an external device in wireless communication with the communication device. The external device is operable to receive information from the communication device and the external device is operable to provide an output viewable to the user.

A surgical stapling device includes a reload assembly that includes a shell housing, a staple cartridge, a plurality of staples received within the staple cartridge, a staple pushing member for ejecting the plurality of staples from the staple cartridge, and a knife for cutting tissue. The shell housing supports a strain gauge which can be molded into the shell housing.

A targeted temperature management (TTM) system includes a TTM module configured to provide a TTM fluid and a pad configured to facilitate thermal energy transfer between the TTM fluid and a patient. The system includes a fluid delivery line (FDL) with a hub at the distal end of the FDL. The pad includes a connector including a flapper valve configured to alternate between open and closed positions based on whether the connector is coupled with the FDL hub. The flapper valve in the closed position covers openings of each of the fluid delivery conduit and fluid return conduit when the connector is uncoupled from the FDL hub. The flapper valve is configured to deform into the open position upon coupling of the connector and the FDL hub thereby establishing fluid communication therebetween.