A fastener delivery system including a handle, a sheath, a delivery shaft extending distally from the handle and within the sheath, and an internal assembly within the sheath. The internal assembly includes a support member extending along a support member axis, a helical track coupled to the support member and configured to receive a helical fastener having a helical fastener pitch, and a driver configured to advance the helical fastener axially along the helical track. The helical track has a helical track pitch corresponding to the helical fastener pitch to permit passage of the helical fastener along the helical track. The helical track includes a neutral axis portion.

A method for producing a surgical instrument is disclosed. The method comprises obtaining a handle, wherein the handle comprises a distal end comprising a shaft interface surface and a first set of magnetic elements. The method further comprises obtaining a shaft, wherein the shaft comprises a proximal end comprising a handle interface surface, a second set of magnetic elements, and a third set of magnetic elements. The method further comprises attaching the shaft to the handle, wherein the shaft interface surface is configured to engage the shaft at the handle interface surface, wherein an attractive magnetic force is configured to pull the handle towards the shaft when the first set of magnetic elements interact with the second magnetic elements, and wherein a repulsive magnetic force is configured to repel the handle from the shaft when the first set of magnetic elements interacts with the third set of magnetic elements.

A holding device for a sterile product, in particular for a sterile product container or a soft packaging, which device is provided to hold, during a preparation process, a medical product to be sterilised, and comprises communication means, and a part of the communication means is designed for a frequency range such that the part, when the sterile product is closed, supplies data in relation to the medical product to an environment of the sterile product. Also provided are a sterile product and a method for monitoring a sterile product cycle.

A method for providing a visual indication regarding a state of an instrument comprises sensing usage information about the instrument and using a motor to rotate an indicator body from a first position to a second position in response to sensing the usage information meets a predetermined condition. The method further comprises holding the indicator body in the first position or the second position, respectively. In the first position a first portion of the indicator body is visible on an exterior of the instrument and in the second position a second portion is visible. In the first position, the first portion of the indicator body provides a visual indication that the usage information of the instrument does not meet the predetermined condition, and in the second position the second portion of the visual indicator body provides a visual indication that the usage information of the instrument meets the predetermined condition.

A dental handpiece includes a head portion supporting a turbine for a removable rotating dental tool, and a handle portion having an internal cavity. One or more conduits extend at least partially through the internal cavity toward the head portion. At least one of the conduits is a drive fluid tube delivering drive fluid to the head portion for rotating the turbine. A wireless communication device within the internal cavity is attached to at least one of the conduits. At least a section of the handle portion surrounding the wireless communication device is formed of a dielectric material. The wireless communication device is configured to wirelessly communicate with an external reader or writer and store data related to at identification, use, and/or maintenance of the handpiece. An electrically inert substrate material encapsulates the wireless communication device, which is electrically isolated from other components of the handpiece.

A surgical stapling instrument includes a handle assembly, a surgical loading unit, and an adapter assembly interconnecting the handle assembly and the surgical loading unit. The surgical loading unit includes a memory having stored therein instructions, which when executed by a processor of the handle assembly, override instructions stored in a memory of the handle assembly and implement an operating parameter of the surgical loading unit that is unique to a tissue type or a specific surgical procedure to be performed by the surgical loading unit.

A surgical stapling assembly that includes a surgical stapling device that has a lockout that is movable between a locked position and an unlocked position. The assembly further includes a staple cartridge with a first cam surface configured to cammingly engage a primary portion of the lockout to move the lockout laterally from the locked position and a second cam surface configured cammingly engage a secondary portion of the lockout to further move the lockout laterally into the locked position when the cartridge is operably seated in the device.

A cartridge includes an electrical connection assembly, a first port, a second port, a pumping mechanism, a valve, and a fluid flow sensor. The electrical connection assembly is configured to electrically couple to an electrosurgical unit. The first port is configured to fluidly couple to a fluid source. The second port is configured to fluidly and electrically couple to a surgical instrument. The pumping mechanism is disposed between the first and second ports and is configured to draw fluid from the fluid source and pump the fluid to the surgical instrument. The valve is disposed between the first and second ports and is configured to selectively obstruct the flow of the fluid therethrough. The fluid flow sensor is disposed between the first and second ports and is configured to sense fluid flow therethrough. The fluid flow sensor is configured to electrically communicate with the electrosurgical unit.

An apparatus includes a housing, a processing circuit, a user feedback feature, and a surgical instrument interface feature. The user feedback feature is in communication with the processing circuit. The surgical instrument interface feature includes a structural interface feature and an electrical interface feature. The structural interface feature is configured to fit in a portion of a body of a surgical instrument. The portion of the body of the surgical instrument is configured to receive an ultrasonic transducer. The electrical interface feature is in communication with the processing circuit and is configured to interface with a complementary electrical interface feature of the surgical instrument. The complementary electrical interface feature of the surgical instrument is configured to couple with an ultrasonic transducer. The processing circuit is configured to receive data relating to a number of uses of the surgical instrument via the electrical interface feature.

A surgical apparatus generates energy that is input onto an appliance. The appliance is one of an implant to be implanted in human or animal bone tissue by the input of the energy, and of a tool being an ultrasonic bone cutting and/or punching tool for cutting and/or punching living human or animal bone tissue by input of energy onto the implant in a surgical operation. The apparatus includes a control device and at least one handpiece, the handpiece being equipped to be held by a surgeon during the operation and to couple the energy into the appliance. The apparatus further includes a reading device equipped to read out, from an appliance data carrier, appliance data dedicated to the appliance. The control device checks, depending on the appliance data, whether the handpiece is suitable for the appliance and chooses operating parameters depending on the appliance data.