A rotational correction system includes an implant having first and second sections, the implant having a rotatable permanent magnet disposed in a housing of the first section, the rotatable permanent magnet mechanically connected to a nut operatively coupled to the second section. A keyed portion is interposed between the nut and one or more non-linear grooves disposed on an inner surface of the housing. An external adjustment device having at least one rotatable magnet configured to rotate the rotatable permanent magnet of the implant is part of the system. Rotation of the rotatable permanent magnet of the implant in a first direction effectuates a clockwise change in the rotational orientation of the first section relative to the second section and rotation of the rotatable permanent magnet of the implant in a second direction effectuates a counter-clockwise change in the rotational orientation of the first section relative to the second section.

A surgical tray efficiency system comprising a vertical rack assembly for holding and displaying a plurality of surgical instrument trays, a sterile barrier covering the vertical rack assembly and including tray location identifiers, and a standardization software platform including a customizable interactive planogram is described. The customizable interactive planogram software helps operating room staff arrange the instrument trays on the vertical rack assembly according to a predetermined customizable location ID, and create/load/access information related to the surgical procedure/trays/instruments before, during, and after the surgery.

A surgical tray efficiency system comprising a vertical rack assembly for holding and displaying a plurality of surgical instrument trays, a sterile barrier covering the vertical rack assembly and including tray location identifiers, and a standardization software platform including a customizable interactive planogram is described. The customizable interactive planogram software helps operating room staff arrange the instrument trays on the vertical rack assembly according to a predetermined customizable location ID, and create/load/access information related to the surgical procedure/trays/instruments before, during, and after the surgery.

An insert for a surgical apparatus tray and method of preparing a surgical apparatus tray are described. The insert may include an upper part defining at least one support configured to receive an item of surgical equipment, and defining a first plane and having a plurality of edges defining a polygonal shape. A first side wall may extend downwardly from a first edge of the upper part and define a second plane. The first side wall may have a first, male attachment feature. A second side wall may extend downwardly from a second edge of the upper part and have a second, female attachment feature. The first attachment feature may be configured to mate with the form of the female attachment feature when the first side wall is moved in a direction parallel to the first plane and the second plane to connect the insert to a further insert having a similar construction.

A receiving sleeve of a tool set includes a hollow body having an end face with an insertion opening for inserting a tool. The hollow body defines a longitudinal central axis and includes a plurality of inner clamping elements spaced apart in a circumferential direction. The clamping elements have punctiform or linear engagement sections at their free, radially inward protruding end portions. The engagement sections make force-fit and/or form-fit contact with the tool for holding the tool within the receiving sleeve at a radial distance from the hollow body. An inner side of the hollow body has circumferentially spaced rigid protrusions that extend axially in rib-like fashion. The inner clamping elements radially protrude further toward the longitudinal central axis of the hollow body than the rigid protrusions.

A receiving sleeve of a tool set includes a hollow body having an end face with an insertion opening for inserting a tool. The hollow body defines a longitudinal central axis and includes a plurality of inner clamping elements spaced apart in a circumferential direction. The clamping elements have punctiform or linear engagement sections at their free, radially inward protruding end portions. The engagement sections make force-fit and/or form-fit contact with the tool for holding the tool within the receiving sleeve at a radial distance from the hollow body. An inner side of the hollow body has circumferentially spaced rigid protrusions that extend axially in rib-like fashion. The inner clamping elements radially protrude further toward the longitudinal central axis of the hollow body than the rigid protrusions.

The present disclosure provides advantageous caddy system that is configured and adapted to promote modularity and withstand the harsh environment of central sterile processing processes. Caddy system may be removed and relocated on tray without additional fasteners or components. Caddy system may further provide identification features to correctly associate cataloged reusable medical devices to identified caddy systems and/or trays.

Described herein is a holding basket (100) for containing an inner basket (200) for holding at least one medical item for processing having a top end (102) and a base end (104) comprising: an essentially rectangular base (110) and side walls (120, 122, 124) extending from the base (110), two rims (130, 132) each disposed on a first pair (120, 122) of opposing side walls, two windows (140) each disposed on a second pair opposing side walls (124) configured for manual access for slidable removal of the inner basket (200), wherein the holding basket (100) is configured for stackability or nestability with an adjacent holding basket (100′, 100″).

Described herein is a holding basket (100) for containing an inner basket (200) for holding at least one medical item for processing having a top end (102) and a base end (104) comprising: an essentially rectangular base (110) and side walls (120, 122, 124) extending from the base (110), two rims (130, 132) each disposed on a first pair (120, 122) of opposing side walls, two windows (140) each disposed on a second pair opposing side walls (124) configured for manual access for slidable removal of the inner basket (200), wherein the holding basket (100) is configured for stackability or nestability with an adjacent holding basket (100′, 100″).

A sterilization cabinet, comprising a top panel, at least two side panels, and a floor panel forming a part of a chamber of the sterilization cabinet; at least one door connected to at least one of the at least two side panels of the sterilization cabinet; a vent formed in at least one of the two side panels; at least one first filter covering the vent and a filter cover configured to hold the first filter against the vent; a drain positioned in the floor panel, wherein the floor panel has a slope configured to cause condensate within the chamber to flow into the drain and wherein the drain is the only outlet for the condensate along the floor panel; and a second filter covering the drain such that condensate flowing into the drain passes through the second filter.