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.

An apparatus and method for an articulating microsurgical instrument is disclosed herein. The articulating microsurgical instrument may be configured to be operable with a Doppler probe, bone grasper, soft tissue grasper/dissector, scissors, flexible forceps, or a suction/irrigation line configured to provide tools within a surgical location that can be adjusted to a desired angle of operation. A tip assembly may comprise an articulating portion at a distal tip and the articulating portion may be configured to deflect upon actuation of an articulation control. The articulation control may be a trigger assembly or a roller wheel. A bayonet-style handle may include a set of posts configured to interact with the one or more control wires during actuation of the articulation control. One or more control wires may be housed in a lumen and actuated using a articulation control of a handle assembly.

A membrane removing instrument may include one or more abrasive surfaces configured to raise a portion of a membrane. A surgeon may raise a portion of a membrane by grazing the portion of the membrane with one or more abrasive surfaces of a membrane removing instrument. The surgeon may grasp the raised portion of the membrane with a first forceps jaw distal end and a second forceps jaw distal end. The surgeon may then remove the membrane by peeling the membrane apart from an underlying tissue.

A device for manipulating an implant includes a handle coupled to a guide extending from the handle to a distal end. The device includes an engagement mechanism disposed at the distal end of the guide and configured to engage an implant. The device includes a first actuator disposed on the handle and coupled to the engagement mechanism. The first actuator causes the engagement mechanism to engage the implant. The device includes an air chamber disposed in an interior chamber of the handle and configured to hold air. The device includes a lumen coupled to the air chamber and extending along the guide to the distal end. The lumen includes an air channel extending through the lumen. The device includes a second actuator disposed on the handle. The second actuator causes the air chamber to deliver the air, via the air channel, to the distal end.

Surgical instrument subcomponent integration by additive manufacturing may include identifying at least two subcomponents of a multi-component assembly wherein a first subcomponent of the at least two subcomponents has a first functionality and wherein the first subcomponent of the at least two subcomponents is manufactured from a first material having a first set of material properties. Surgical instrument subcomponent integration by additive manufacturing may include modifying one or more properties of the first subcomponent of the at least two subcomponents to reproduce the first functionality when the first subcomponent is manufactured from a second material having a second set of material properties. Surgical instrument subcomponent integration by additive manufacturing may comprise integrating the at least two subcomponents by manufacturing an integral component by additive manufacturing wherein the integral component is manufactured from the second material and wherein the first functionality is retained.

A surgical tool system according to an embodiment of the current invention includes a surgical tool, and an interferometry system optically coupled to the surgical tool. The surgical tool includes a body section, a sensor section at least one of attached to or integral with the body section, and a surgical section at least one of attached to or integral with the sensor section at an opposing end of the sensor section from the body section. The sensor section comprises an interferometric optical sensor defining a reference distance that changes in response to at least one of a force or a torque when applied to the surgical section of the surgical tool.

Membrane forceps for performing an ILM or ERM peel procedure include a handle, a tube extending from the handle, and forceps jaws extending from the tube. The forceps jaws may be configured to grasp an ILM or ERM, and may include an outer surface having a roughened surface. The roughened surface may be structurally configured to aid in gaining an edge of the ILM or ERM.

A microsurgical instrument that can slide over a surgical suction instrument and comprises a grasper or a micro-scissor for cutting at the distal end, a lever at the proximal end to actuate the jaws of the grasper or the blades of the micro scissor. The disclosed microsurgical instrument may be locked to the surgical suction instrument or may be rotated on the long axis on the surgical suction instrument. The disclosed instrument can be placed by sliding over the surgical suction instrument without the need for disconnecting the surgical suction instrument from the suction hose.

A surgical instrument comprises a shaft, wherein a deflectable articulation section is formed at the shaft, a proximal handling portion at a proximal end of the shaft, a distal effector at a distal end of the shaft, and a deflection mechanism for controlling a bending state of the articulation section. The deflection mechanism comprises a first pull element for a deflection movement and a second pull element for a return movement. The first pull element and the second pull element are jointly pretensioned during the movement of the articulation section. An interface is provided where the instrument is demountable into a distal shaft assembly and a proximal handle piece, wherein the effector is controlled via an actuation mechanism that passes through the interface in a mounted state. The actuation mechanism comprises a push piece having a distal end that is coupled with the effector and a proximal end that is actuable by a pushing movement.

A needle driver includes a first elongated body that defines an interior chamber. A second elongated body defines an interior space, and is slideable within the interior chamber defined by the first elongated body between a retracted position and an extended position. The needle driver also includes a clamping device having a clamping end and a connecting member, which is affixed to the first elongated body and coupled within the clamping end. A biasing shaft is slideably disposed within the interior space defined by the second elongated body. An actuator is affixed to the biasing shaft and is slideable in a proximal direction and a distal direction.