Abstract: Devices and methods for sampling, detecting and/or characterizing particles, for example, via collection, growth and analysis of viable biological particles such as microorganisms. Devices and methods of the invention include particle samplers and impactors including a sampling head comprising one or more intake apertures, a selectively removable cover, an impactor base connected to the sampling head, and one or more magnets fixed to the sampling head, the selectively removable cover and/or the impactor base. The one or more magnets allow for robotic manipulation of the impactor devices.
Abstract: A containment system and assembly for the automated production of pharmaceutical or biotechnical articles is provided. The containment system has a housing within which there is an inner chamber having at least one through opening. One or more robots are installed in the chamber, which have a manipulating element on the pivotable arms, which can move within a pivot range. One or more process units are installed in the chamber for the production of the articles. The chamber includes a process space for the production of the articles and a tub-shaped base space for anchoring the feet of the robots to the side surfaces inside the base space. The manipulating element functions as a gripping and transportation device for inspecting the articles or article parts and/or for the production of the articles.
Abstract: The arrangement for the contamination-free introduction of a sterile object (3) from a vessel (2), which has been closed by means of a semipermeable cover (23), into a working chamber (90), which is surrounded by a wall (91), of a containment (9) firstly comprises a portal unit (7) having an access flange (71) which is arranged in the wall (91) and which forms a passage (75) from the outside into the working chamber (90), and a door (5) which sealingly closes the passage (75) and which, in order to be opened, can be moved into the working chamber (90). The arrangement furthermore comprises a vessel receptacle (6) having a repository (60) for holding a vessel (2) that has been introduced into the vessel receptacle (6), an opening for the introduction of the vessel (2) into the repository (60), and a flange (61) for interacting with the access flange (71).
Type:
Application
Filed:
July 17, 2019
Publication date:
September 9, 2021
Applicant:
Pharma Integration S.R.L.
Inventors:
Robert Landes, Mathieu Müller, Kathrin Sprecher, Mike Zeller
Abstract: A mobile monitoring device for monitoring controlled contamination areas may include a motorized mobile structure, a sampling unit, and a central management and control unit. The motorized mobile structure is configured to move within an area to be monitored. The sampling unit is positioned on said mobile structure, and configured to perform sampling operations of air and/or surfaces of said area and obtain sampling data. The central management and control unit is operatively connected to the mobile structure and to said sampling unit. The mobile structure may be controlled by the central unit to reach predefined points of the area to be monitored. The sampling unit may be selectively activated and/or deactivated by said central unit in correspondence with said predefined starting points of said sampling operations.
Abstract: The constructive assembly of the containment means (9) is intended for the automated production of pharmaceutical or biotechnical articles (6). As an end product, a respective article (6) comprises multiple article parts (7). The containment means (9) has a housing (90) within which there is an inner chamber (91) having at least one through opening (917, 919). At most, multiple robots (1, 2) are installed in the chamber (91), which generally have a manipulating element (12, 22) on the pivotable arms (11, 21) thereof, which can move within a pivot range (R1,R2). At most, multiple process units (3) are installed in the chamber (91) for the production of the articles (6). The chamber (91) is formed by a process space (93) for the production of the articles (6) and a tub-shaped base space (92) for anchoring the feet (10, 20) of the robots (1, 2) to the side surfaces (910,912,916,918) inside the base space (92).