There is provided a medical display control apparatus including: a display control section configured to control a display of a medical captured image for a right eye and a medical captured image for a left eye captured by an imaging device that images an observation target on a display screen and a display of a pointer object on the display screen. The display control section causes the pointer object to be displayed in correspondence with a depth position of the medical captured image for the right eye and the medical captured image for the left eye.

Embodiments disclosed herein generally relate to an access sheath and access systems. In some embodiments, the access sheath may be non-adjustable access sheath or an adjustable access sheath. For example, a length of the adjustable access sheath may be modified or customized (e.g., before insertion thereof in a patient) to a suitable length for a particular patient. In some embodiments, the access sheath and/or dilator may have a substantially fixed or predetermined length.

Systems and methods are disclosed in which customized instruments, e.g., surgical instruments, can be manufactured to provide improved ergonomics, comfort, and accuracy. Instruments can be customized based on various parameters, including a quantitative assessment of the user, desired or intended use of the instrument, user preferences, and so forth. Exemplary instrument properties which can be customized include size, geometry, durometer, mechanical assist, texture, color, markings, modulus of elasticity, sensor inclusion, sensor type, sensor feedback type, balance, finish, and weight.

A medical instrument grip device consisting of an open tubular element of elastic material for an elongated medical instrument comprises an elongated element having a gripping area and a head element being attached to one of the ends of the elongated element. The tubular element is open in both longitudinal ends and is configured to switch between a rolled up state and a fully unrolled state. Further, the tubular element is configured such that the head element may be forced through the inner opening of the stretched tubular element being in its rolled up state and to create a tight fit around the gripping area when being in its unrolled state.

Implementations described and claimed herein provide a spinal facet cage implant for implantation in a spinal facet joint. In one implementation, the implant includes a distal leading end, a proximal trailing end, a first face, and a second face. The distal leading end has a distal surface generally opposite a proximal surface of the proximal trailing end. The first face has a first surface that is generally parallel with a second surface of the second face. The first and second faces extend between the distal leading end and the proximal trailing end. The first and second surfaces having one or more textured features adapted to provide friction with the spinal facet joint. One or more windows are defined in the first and/or second surfaces, and one or more side windows are defined in the first and/or second side surfaces.

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 ligation clip defines a longitudinal axis includes a first jaw, a second jaw, and a hinge portion that pivotably couples the first jaw to the second jaw. The first jaw has a first clamping surface that supports first ribs that defines an angle ? with the longitudinal axis. The second jaw has a second clamping surface in opposition to the first clamping surface and supports second ribs that define the angle ? with the longitudinal axis. Each of the first and second ribs includes a distal wall and a proximal wall and a wall in opposition to the opposing clamping surface. The distal wall of at least some of the first ribs is positioned in close proximity to the proximal wall of a respective one of the second ribs when the ligation clip is in the clamped position.

An invasive medical device assembly includes an invasive medical device and a hub housing configured to surround a portion of the invasive medical device. The invasive medical device may be a needle or other invasive medical device, and the hub housing may be configured to surround a hub of the invasive medical device. In one aspect, the invasive medical device may include a transducer. The hub housing can include at least one integrated circuit embedded therein that is configured to contact the external surface of the needle to electrically connect the transducer to a power source. The hub housing can be configured to provide an ergonomic handle for a user.

Surgical Guide for Positioning a Resurfacing Head Implant The present invention relates to a guide for positioning a resurfacing head implant into the appropriate position and angles on the femur bone. The present invention therefore provides a guide system for an implantable device (e.g. a resurfacing head implant), said guide system comprising a first component arranged to act as a clamp and a second component arranged to interact with the first component to prevent movement of said first component when clamped.

Methods, devices, and systems are provided for performing endovascular repair of atrioventricular and other cardiac valves in the heart. A delivery device for staged deployment of an implantable device to a target area. The delivery device includes a deployment handle and one or more lock lines extending from the deployment handle through the catheter to the implantable device, the one or more lock lines being configured to engage with the implantable device to allow locking of the implantable device.