Systems and methods are disclosed for sterile delivery of prostheses that protect refined and/or conditioned surface properties and thereby reduce aging of surface properties in prostheses. An example of the system includes a partially custom-shaped holder that also serves as an insertion tool that holds a customized dental prosthesis in a pre-defined position inside a titanium container that is hermetically sealed. Container materials serve as a getter or catalyst with respect to the osseoconductive surface. An example of the method includes laser welding to hermetically seal a metal container as packaging for a prosthesis with a metal foil, and the sterilization of the packaged and sealed prosthesis with dry heat.

A container for sterilizing flexible bags can be for pharmaceutical use. The container includes an upper flat structure including at least one element supporting the flexible bags and designed to accommodate a plug port of the flexible bag. The support element includes at least one fastening element, which is suitable for retaining the flexible bags once they are inserted into the support element. The container also includes a lower receptacle designed to contain the upper flat structure and to couple to the upper flat structure in a detachable manner. The container further includes a cap for hermetically sealing the lower receptacle.

The present invention relates to a method and system for aseptically filling of flexible packages containing dry cloth. Such a method may include a first stage that is performed in a non-sterile environment. The first stage may include cutting a first substantially dry cloth to a predetermined size; inserting the first cloth into a flexible package; sealing a first end of the flexible package; and sterilizing the flexible package. The method may also include a second stage performed in a sterile environment. The second stage may include filling the flexible package with a medical solution such that the substantially dry cloth absorbs at least a portion of the medical solution; and sealing the open end of the flexible package.

A sterilization method includes irradiating flexible bags, in particular, bags of the type that can contain solutions of human plasma proteins for therapeutic use. The sterilization method includes electron beam irradiation. An in-line method for filling flexible bags of the type that can contain solutions of human plasma proteins for therapeutic use can use the sterilization method.

A system includes a sensor applicator, a sensor control device arranged within the sensor applicator and including an electronics housing and a sensor extending from a bottom of the electronics housing, and a cap coupled to one of the sensor applicator and the sensor control device, wherein the cap is removable prior to deploying the sensor control device from the sensor applicator.

To make a sterilization step appropriate in an aseptic filling apparatus. Provided is an aseptic filling apparatus including a step of sterilizing a preform and a step of sterilizing a container obtained by molding the preform, wherein assuming sterilization effects in the respective sterilization steps as X [LRV] and Y [LRV], a relationship of 5≤X+Y≤10 (where Y≥0) is established.

Catheters including thermoplastic polyurethane polymer tubing with improved shape recovery after storage in a substantially coiled configuration are provided.

Disclosed is an energy beam emission device including: an electron discharge unit having a long electron discharge part; a housing having a window from which energy beams are emitted on the basis of electrons discharged from the electron discharge part; and a unit accommodation part capable of accommodating the electron discharge unit. A plurality of positioning parts are provided between an outer surface of the electron discharge unit and an inner surface of the unit accommodation part, the positioning parts being slidably in contact with an outer surface of the electron discharge unit or an inner surface of the unit accommodation part and performing positioning of the electron discharge part with respect to the unit accommodation part.

Disclosed is a container treatment apparatus and treatment method, in particular a container sterilisation apparatus, having a plurality of transport devices for transporting a container along a predetermined transport path, at least one of the transport devices having at least one holding device for holding at least one container during container treatment and/or transport along the transport path, the transport device having a rotatable carrier and a plurality of holding elements arranged on this carrier, wherein a holding element in a first sector, in which a container is received, having a height with respect to a perpendicular projection of the transport path which is different from that in a second sector in which a container is dispensed, and wherein a sector in which an at least partial compensation of the height difference of the holding elements takes place lies along a direction of rotation of the carrier after the second sector and before the first sector.

Devices for the propagation or storage of microorganisms are provided including a first layer that has a first portion of a surface of the first layer, to which a first water-swellable gelling agent comprising a first clay is affixed. The devices further include a second layer that is separable from the first layer and has a first portion of a surface of the second layer, to which a second water-swellable gelling agent is affixed. Methods for detecting and enumerating at least one microorganism in a sample are provided. The methods include providing a device, separating the first layer from the second layer, adding an aliquot of a sample containing at least one microorganism onto the first or second water-swellable gelling agent to form an inoculated device, laminating the first layer back to the second layer, and incubating the inoculated device. Kits and methods of making the devices are also provided.