A system of managing the sterilisation of empty flexible pouches (1) provides applying sacrificial closures (200) to the empty pouches, loading the empty provisional closed pouches to be sterilised on a transport device (300) for the collective transportation, performing the sterilisation of the transport device (300) carrying the empty provisional closed pouches, and finally separating, in a sterile chamber, the sacrificial closures (200) from the pouches, filling and applying a tamper-proof cap (100).

A device for sterilizing plastic containers includes a transport device for transporting the containers during the sterilization along a predefined transport path, a clean room within which the containers can be transported during sterilization, wherein the clean room is delimited by at least one wall with respect to the environment, and a first external application device for sterilizing at least a section of the outer wall of the containers. The first external application device has a source of charge carriers for generation of charge carriers, and includes a first moving device which moves the containers at least intermittently in the longitudinal direction during their sterilization. The device also includes a rotary device which rotates the containers about their longitudinal direction at least intermittently during the sterilization, wherein the rotary device and the moving device are preferably configured in such a way that a rotation of the containers is enabled during a movement of the containers in their longitudinal direction.

An interchangeable shaft assembly for a surgical instrument that includes first and second drive systems. The interchangeable shaft assembly is configured for removable attachment to a housing of the surgical instrument. Various embodiments include a latch system that enables the interchangeable shaft assembly to be detached from the housing when the first drive system is unactuated but prevents the interchangeable shaft assembly from being detached from the housing when the first drive system is in an actuated position.

One object is to provide an electron beam sterilization apparatus for sterilizing a preform product (P) by applying an electron beam while conveying the preform product (P), the apparatus comprising: an input star wheel (21) configured to convey the preform product (P) in a circular path; and an outer-surface electron beam application device and an inner-surface electron beam application device configured to apply an electron beam to the preform product (P) being conveyed by the input star wheel (21). A blocking short tube (31) is provided on a lower surface of the star wheel plate (22) of the input star wheel (21) so as to block radioactive rays produced by application of the electron beam and surround a central axis (1v) of the input star wheel (21). The blocking short tube (31) includes a ventilation space (34) formed therein.

A system for sterilizing a fluid includes a sterilization container bounding a fluid flow path that can be coupled with a fluid source. The sterilization container is comprised of one or more polymeric walls. A beam generator is configured to direct a beam of electromagnetic radiation through at least a portion of the fluid flow path of the sterilization container, the beam of electromagnetic radiation being sufficient to sterilize a fluid within the fluid flow path.

The subject matter of the present invention is a method for treating pourable products made of particles which can be separated, preferably seeds (2), with accelerated electrons. During the method, a transparent product flow is guided, using gravity, in a product guiding channel (1) through the electron field generated by at least one electron accelerator (12) under low pressure or excess pressure. The product flow is guided by means of an accelerated gas flow (5) in such a way that the movement thereof corresponds in magnitude and direction to the accelerated movement, which the falling particles execute in said gas flow due to gravitational acceleration. In addition, a device is disclosed which realizes the acceleration of the gas flow (5) in the required way through the shaping of the product guiding channel (1).

A method for onsite bacteria testing for oil and gas applications including collecting at least one component of a wellbore fluid; exposing at least one contaminant in the at least one component to at least one substrate that produces a detectable moiety; and performing a quantitative or qualitative detection of the detectable moiety.

One object is to provide an electron beam sterilization apparatus including: an inner-surface sterilization chamber (5) including an inner-surface electron beam application device; and a blocking chamber (6) for receiving a preform product (P) from the inner-surface sterilization chamber (5) and blocking X-rays produced by application of the electron beam. The blocking chamber (6) includes an upstream opening (62) and a downstream opening (63) formed therein, the preform product (P) being received through the upstream opening (62) and transferred through the downstream opening (63). The blocking chamber (6) includes: a gripper (74) for gripping the preform product (P); a sterilized rotation table (71) for conveying the gripped preform product (P) in a circular path; and a blocking wall (81) not in contact with the sterilized rotation table (71) and configured to block the X-rays.

The present invention relates to a kit comprising

an endodontic instrument in the form of an endodontic file and
a container with a lower container part, for receiving the working section (3c) of the endodontic instrument, and an upper container part, for receiving the upper axial end region of the instrument,
wherein a holder is provided on the upper side of the lower container part, which holder comprises an axial through-opening through which the working section of the instrument is inserted into the lower container part and in which the instrument, in particular the tool shaft of the instrument, is fixed in a clamping manner,
wherein the upper container part is connected with the lower container part in an airtight manner to form the container, and the interior of the container and the instrument are sterile.

A method of making an electron beam irradiated osteoinductive implant is provided. The method comprises exposing an osteoinductive implant containing demineralized bone matrix (DBM) fibers to electron beam radiation at a dose of from about 10 kilograys to 100 kilograys for a period of time. The electron beam irradiation reduces microorganisms in the osteoinductive implant, and the electron beam irradiated osteoinductive implant retains osteoinductive properties. Methods of implantation and an irradiated osteoinductive implant are also disclosed.