Provided is a production line management system for managing a manufacturing line for containers. The production line management system includes a first reading unit for reading an identification code applied to each of the containers when the container with the identification code indicating an identifier being information identifying the container passes through a first point on the manufacturing line, a second reading unit for reading the identification code applied to each of the containers after the first reading unit reads the identification code, and a computing unit for generating a database in which the identifier indicated by the identification code and relevant information about each of the containers are associated, and determining normality/abnormality of each of the containers by comparing the relevant information associated in the database with the identifier indicated by the identification code read in the second reading unit with predetermined setting information.

A self-contained medical and protective mask manufacturing system, which can be located anywhere there is floor space for a device the approximate size of a soft drink vending system, and where masks are produced on-demand, in any quantity up to the limit of the raw materials contained within the system or the capacity of the dispensing chute, is disclosed.

A self-contained medical and protective mask manufacturing system, which can be located anywhere there is floor space for a device the approximate size of a soft drink vending system, and where masks are produced on-demand, in any quantity up to the limit of the raw materials contained within the system or the capacity of the dispensing chute, is disclosed.

Disclosed are embodiments of nanoparticle compositions, methods and systems for disinfecting animals and food products along the whole food provision chain. In one embodiment, a composition includes nonionic metal nanoparticles. The composition may be a spray, an oil, a solution or other appropriate composition for ingestion or application to food products. The silver nanoparticles maintain a stead MIC and do not exhibit microbial resistance as do conventional colloidal silver and silver nanoparticles made by chemical synthesis.

Disclosed are processes for producing cultured dairy products, such as yogurt, that are shelf-stable without refrigeration. Such processes can include contacting a milk base having from 0.5 to 1.9 wt. % milk sugar with a lactic acid bacteria culture and aseptically packaging in a container, followed by storage under conditions suitable to result in a pH of less than 4.7.

Disclosed are processes for producing cultured dairy products, such as yogurt, that are shelf-stable without refrigeration. Such processes can include contacting a milk base having from 0.5 to 1.9 wt. % milk sugar with a lactic acid bacteria culture and aseptically packaging in a container, followed by storage under conditions suitable to result in a pH of less than 4.7.

The present disclosure provides novel processes for providing sterile, pre-filled syringes or injection devices for pharmaceutical compositions, including protein and biopharmaceutical formulations. In some examples, secondary packaging is performed in an aseptic environment, which removes the need for any terminal sterilization method. In some examples, the aseptic packaging method results in a sterile injection device suitable for use in ophthalmic injections.

Among other things, there is shown a system for filling vials with fluid that maintains a localized sterile zone around the filling location. In particular embodiments, the sterile zone is provided by a manifold having an internal space to which clean air is supplied. One or more filling assemblies are attached to the manifold. Vials enter the sterile zone and are filled within it. Additional structure, such as coverings for vials, are disclosed to assist in maintaining sterility.

Among other things, there is shown a system for filling vials with fluid that maintains a localized sterile zone around the filling location. In particular embodiments, the sterile zone is provided by a manifold having an internal space to which clean air is supplied. One or more filling assemblies are attached to the manifold. Vials enter the sterile zone and are filled within it. Additional structure, such as coverings for vials, are disclosed to assist in maintaining sterility.

The present invention relates to an automatic oral sensor sterilizing and packaging system and, particularly, to an automatic oral sensor sterilizing and packaging system capable of automatically sterilizing an oral sensor and further packaging the oral sensor with disposable wrapping paper, comprising: a housing including a sterilization unit providing a sterilization region for sterilization of the oral sensor and/or a packaging unit providing a packaging region for packaging the oral sensor; and a transfer unit for making the oral sensor pass through at least one of the sterilization region and the packaging region.