An instrument including a first arm, a second arm, and a blade. The first arm includes a lumen in communication with a source of irrigation fluid and one or more outlets in communication with the lumen for delivering the irrigation fluid to a surgical site. The instrument is switchable between a first configuration and a second configuration. In the first configuration, the instrument is configured to deliver a first therapy current through a distal end of the first arm, a distal end of the second arm, or both. In the second configuration, a distal end of the blade extends beyond the distal end of the first arm and beyond the distal end of the second arm.

The present disclosure describes systems and methods for selectively constraining an orientation of a portion of a surgical tool system relative to another. Example surgical tool systems may include a surgical tool having at least one movable component, at least one actuation component, and a surgical tool attachment. The surgical tool attachment may be operable selectively to engage and disengage the moveable component so as to to prevent movement of the movable component relative to the surgical tool in an engaged configuration and to permit movement of the movable component relative to the surgical to in a disengaged configuration, respectively. In the engaged configuration, a dynamic component of the surgical tool system may be fixed relative to the surgical tool, and, in a disengaged configuration, the dynamic component may be freely movable relative to the surgical tool.

A collection bag and a bag deployment device for use in collecting an item such as a specimen during surgical procedure. The collection bag and bag deployment device forming an assembly adapted to deliver the collection bag through an access cannula into a surgical cannula. The assembly adapted to strip the collection bag from the distal end of the bag deployment device and cinch a cinch loop to close the open end of the collection bag.

A forceps comprising a first jaw and a second jaw arranged along a longitudinal axis of the forceps for relative movement toward and away from one another. The first and second forceps jaws have respective first and second jaw surfaces facing each other. The first and second jaw surfaces have a serrated surface texture at least on a distal part thereof. A serration direction of the serrated surface texture is at an angle which is non-perpendicular to the longitudinal axis, resulting in additional profile structure elements at a tip portion surface, allowing to handle and manipulate fine tissue materials such as membranes in an eye.

A surgical instrument includes a first lever element and a second lever element interconnected by a lever element hinge. Each lever element includes a grip portion and a jaw portion. A first spring portion and a second spring portion are proximally connected to the grip portions. A proximal free end of the first spring portion is coupled to a proximal free end of the second spring portion by a hinged joint. The hinged joint includes a hinge pin and at least one bearing eye. The at least one bearing eye forms a continuous longitudinal slit for radial insertion of the hinge pin. The slit extends diagonally relative to the axis of the at least one bearing eye so that at least one spring portion has to be twisted during radial insertion of the hinge pin into the at least one bearing eye.

A micromanipulation system includes a micromanipulator that includes a handpiece, and a micromanipulation tool that includes a tool shaft and is operatively connected to the handpiece. The micromanipulator further includes an actuator assembly connected to the micromanipulation tool to provide manual control of the micromanipulation tool, and a force sensing system comprising a force sensor attached to the tool shaft. The force sensing system is configured to provide an output signal that indicates a force imposed on the tool shaft. The micromanipulation system also includes a processor that is in communication with the force sensing system, and is configured to receive the output signal and compensate for forces due to actuation of the micromanipulation tool to determine a force due to interaction of the micromanipulation tool with a region of interest. The processor outputs an indication of at least one of a magnitude and a direction of the determined force.

Methods, systems, and devices for skin care are provided. Some embodiments may include a device or system for skin care that may include a skin tool head portion, a skin tool head support that may be coupled with the skin tool head portion, and/or a portable microscope connector that may be configured to couple a portable microscope with the skin tool head support. Some embodiments include a device for skin care that may include a spacer configured to couple with a portable microscope. The spacer includes at least one aperture configured to facilitate the use of a skin tool. Some embodiments include a spacer coupled with a compressible structure configured to preclude a skin tool from contacting a portion of skin when in an uncompressed state and to allow the skin tool to contact the portion of skin when in a compressed state.

A surgical kit for the repair of a nail bed includes implantable nail plate guides adapted to guide the regrowth of a fingernail over a nail bed, drapes, a suture needle with absorbable suture, a suture needle with non-absorbable suture, wound dressings, and all instruments required to perform the procedure. The instruments preferably include an elevator, a needle driver, a clamp, a tweezers, and a scissors. The kit also includes anesthesia, a syringe, and needles for loading and then administering the anesthesia to the finger. The kit may include a tourniquet, antiseptic, and an antiinfective. Therefore, the kit assembles together several nail plate guides, the instruments for implanting a selected one of the nail plate guides onto the nail bed over a patient, the pre-implantation surgical preparation materials, and the post-implantation wound care materials.

A surgical tool assembly is disclosed. The surgical tool assembly includes a forceps instrument including a proximal handle portion with an actuator, and a distal forceps portion including jaws. The actuator selectively moves the jaws. The surgical tool assembly includes an infusion assembly including a tube configured to be connected to a fluid source at a primary tube end and connected to a fitting at a paracentesis tube end. The fitting defines a passage configured to receive the distal forceps portion of the forceps instrument. An infusion sleeve extends away from the fitting. The infusion sleeve is arranged concentric around an outer surface of the distal forceps portion to define a fluid pathway. The jaws extend beyond a terminal end of the infusion sleeve such that the jaws are arranged outside of the infusion sleeve.

An ophthalmic surgical instrument for peeling a retinal membrane includes a handle and an actuator mounted on the handle. An outer tube is mounted to the handle and an inner rod extends within the outer tube. A grasping structure is secured to a distal end of the inner rod having first and second polymer arms secured to the inner rod. Each of the first polymer arm and the second polymer arms has a distal end that is angled to conform to the retinal membrane. The actuator is configured to control relative position of the inner rod and the outer tube in order to extend the grasping structure out of the outer tube and withdraw the grasping structure within the outer tube.