A surgical instrument is disclosed. The surgical instrument has a handle assembly. The handle assembly has a trigger operatively coupled to a firing plate, an energy button configured to deliver energy to at least one electrode, a lockout element operatively coupled to the energy button, the lockout element configured to prevent operation of the firing plate, and a lockout disabling mechanism configured to disable the lockout element, the lockout disabling mechanism operable between a first position and a second position. When the lockout disabling mechanism is located in the first position, the lockout element is enabled and can be unlocked by the energy button, and wherein when the lockout disabling mechanism is in the second position, the lockout element is disabled.

Devices and methods for applying energy to tissue are provided. In one exemplary embodiment, a surgical device includes a monopolar end effector, a cannulated, insulated outer sheath, a translating nozzle coupled to the proximal end of the sheath, and a handle portion coupled to a proximal end of the end effector. Various translating means, such as switches, thumbwheels, rings, and buttons, are associated with the handle portion, and are effective to advance the outer sheath to cover a distal end of the end effector and retract the outer sheath to expose the distal end of the end effector. The translating means are configured in a manner that allows a user to operate the translating means without having to adjust a location of the user's hand on the device. A variety of translating means are provided for, as are methods for cutting, coagulating, irrigating, and suctioning tissue.

In a multistage pushbutton switch device, n pushbutton switches and at least one load absorption spring are movably arranged in between a pushbutton member and a reaction force wall in the same axial line, each of the n pushbutton switches is composed of an electrical switch member and a pressing member that operates the electrical switch member, and (n?1) that is one less than n, or more pushbutton switches is arranged with an intermediate spring member, when the pushbutton member is pressed and displaced, the n electrical switch members are sequentially turned on, the load absorption spring is arranged in at least one of between the pushbutton member and the pushbutton switch that is the nearest to the pushbutton member, between pushbutton switches that are adjacent, and between the reaction force wall and the pushbutton switch that is the nearest to the reaction force wall.

A powered surgical instrument includes a shaft assembly and a handle assembly. The shaft assembly includes a first electrical connector and a flexible element positioned adjacent to the first electrical connector. The handle assembly includes a second electrical connector. The handle assembly is configured to attach to the shaft assembly. The second electrical connector is configured to electrically connect with the first electrical connector when the handle assembly is attached to the shaft assembly. The flexible element is configured to create a liquid-resistant seal against the handle assembly and adjacent to the electrical connection of the first and second electrical connectors when the shaft assembly and the handle assembly are attached.

The present application provides a foot actuation system for controlling one or more medical devices using a foot. The foot actuation system includes a communications unit and a number of actuation units. Each actuation unit includes a user interface for receiving an actuation information item generated by means of a foot, a mechanical connection apparatus for releasable mechanical connection to the communications unit, and a signal transmitter for transmitting a signal representing the actuation information item. The communications unit includes a mechanical connection apparatus for releasable mechanical connection to the actuation units, a signal receiver for receiving the signals representing the actuation information items, and a control signal transmitter for transmitting a control signal to a medical device.

A switch assembly includes a switch housing, a first switch subassembly, and a second switch subassembly. The first switch subassembly includes a shaft and a toggle button. The shaft is disposed within the switch housing and has a proximal end portion and a distal end portion. The shaft is pivotable relative to the switch housing about at least one pivot axis to actuate at least one function of a surgical instrument. The proximal end portion of the shaft includes a magnet. The toggle button is non-rotatably connected to the distal end portion of the shaft. The second switch subassembly includes a safety bar and a post. The safety bar is axially movable within the switch housing. The post extends through the safety bar such that movement of the safety bar along a longitudinal axis thereof moves the post between a firing position and a non-firing position.

A motion-enable device includes a mechanical switch and a capacitive sensor with a sensing region that is located adjacent to the mechanical switch. The mechanical switch enables a first signal when closed or actuated that indicates that the mechanical switch is in an active state. The capacitive sensor enables a second signal when a conductive object is disposed in the sensing region, where the second signal indicates that the capacitive sensor is in an active state. Enablement of operation of an apparatus depends on receipt of both the first signal and the second signal. The mechanical switch and the capacitive sensor act as the two separate switches required by functional safety requirements for a motion enable device. Because the sensing region of the capacitive sensor is adjacent to the mechanical switch, the first and second signals are generated when an operator actuates the mechanical switch with a single digit.

A method of creating a switch, comprising disposing a switching element movably within an interior cavity of the switch to define first and second positions along a switching axis of the switching element, disposing a biasing element about the switching element to impart a biasing force to the switching element to place the switching element in one of the first and second positions until an external force imparted to the switching element exceeds the biasing force to cause the switching element to move to the other position, disposing a biasing force-adjusting element in cooperative engagement with the biasing element such that a magnitude of the biasing force is adjustable, and coupling a conductive contact to the switching element to define a first switching state when the switching element is in the first position and a second switching state when the switching element is in the second position.

A method of assembling a surgical instrument includes coupling a power bus to a switch base that has a top, a bottom, and side surfaces; adhering a membrane to the top surface of the switch base over the power bus to form a switch base assembly; positioning the switch base assembly within a first portion of a switch base cavity defined by a lower housing portion; and joining the lower housing portion with an upper housing portion. The upper housing portion defines a second portion of the switch base cavity. Joining the lower housing portion with the upper housing portion disposes the switch base within the first portion of the switch base cavity and prevents fluid from penetrating a proximal portion of the switch base cavity within which an electrical lead is coupled to the power bus.

A switch assembly includes a switch housing, a first switch subassembly, and a second switch subassembly. The first switch subassembly includes a shaft and a toggle button. The shaft is disposed within the switch housing and has a proximal end portion and a distal end portion. The shaft is pivotable relative to the switch housing about at least one pivot axis to actuate at least one function of a surgical instrument. The proximal end portion of the shaft includes a magnet. The toggle button is non-rotatably connected to the distal end portion of the shaft. The second switch subassembly includes a safety bar and a post. The safety bar is axially movable within the switch housing. The post extends through the safety bar such that movement of the safety bar along a longitudinal axis thereof moves the post between a firing position and a non-firing position.