A system includes an anti-allergen formulation and a device that generates droplets of the formulation to be delivered to an air environment. The aqueous formulation includes an organic acid having a vapor pressure between 0.001 Pa and 172 Pa and an aqueous solubility of at least 24.99 grams organic acid per 100 grams water, both at room temperature and standard pressure. The device can generate droplets of the formulation having a median particle size (Dv50) of no greater than 120 micrometers. The formulation delivered as droplets in an air environment can provide a statistically significant reduction, over a control, in one or more airborne allergens as measured by an enzyme linked immunoassay. In addition, the formulation delivered as droplets in the air environment can be effective to neutralize greater than 50% of one or more airborne allergens present in the air environment.

This decontamination intensity sensor detects the degree of decontamination of microorganisms and/or viruses decontaminated with peracetic acid, the decontamination intensity sensor including an exposed part that is made of a metal that is corroded by the peracetic acid, and the metal is exposed.

A method of cleaning and disinfecting a surface comprises producing a diluted cleaning disinfectant solution from a concentrated cleaning disinfectant solution, and contacting the surface with the diluted solution. A concentrated cleaning disinfectant solution is stable at freezing temperatures and comprises antimicrobial acid, surface cleaning acid, solubilizing agent, hydrotrope, and surfactant. The antimicrobial acid comprises a synergistic combination of (i) salicylic acid, derivative of salicylic acid, or a combination thereof, and (ii) gluconic acid, derivative of salicylic acid, or a combination thereof. The surface cleaning acid comprises at least one acid selected from mineral acid, methane sulfonic acid, formic acid, or sulfonic acid having an alkyl group with no greater than three carbon atoms. The surfactant selected from anionic surfactant, non-ionic surfactant, or a mixture thereof.

A multi-layer article including a first non-active state and a second active state, the multi-layer article comprising an outer layer having a first side and a second side, an inner layer adjacent to at least a portion of the outer layer and including a volatile material, and an upper layer including a first side and a second side, the first side of the upper layer being adjacent to at least a portion of the inner layer. The multi-layer article is folded upon itself in the first non-active state so that at least a first portion of the second side of the upper layer is disposed on a top of a second portion of the second side of the upper layer, and the first portion and the second portion of the upper layer are heat sealed in the non-active state.

A system for manufacturing parenteral solutions includes a drug dosage module and a mixing module. The drug dosage module includes a source of one or more parenteral drug solutes, and one or more metering devices configured to discharge a metered dosage of each of the parenteral drug solutes. The mixing module includes a container configured to receive water-for-injection (WFI) and the parenteral drug solutes discharged from the one or more metering devices, and a mixer configured to mix water-for-injection (WFI) and the parenteral drug solutes in the container to form a parenteral solution.

A modular anti-microbial aerosol atmospheric effect delivery system includes an air compressor, a haze solution reservoir, and an artificial snow solution reservoir in a system enclosure and an electronically controlled haze module and artificial snow module mounted above an attendee room. The haze module is connected to the air compressor and the haze solution reservoir by a hose system. The artificial snow module fluidly is connected to the air compressor and the artificial snow solution reservoir by the hose system. The artificial snow solution reservoir contains an artificial snow solution including sodium lauryl sulfate and citric acid. The haze solution reservoir contains a haze solution propylene glycol or tri-ethylene glycol, and at least one anti-microbial component selected from hydrogen peroxide and citric acid. The solutions are safe and antivirally effective to kill aerosol microbes suspended in the air, reducing transmission of undesirable microbes amongst attendees and workers within indoor environments.

This disclosure generally relates to catheters, methods of enhancing the patency of an intravascular catheter and compositions, methods, devices and kits relating to the infusion of a catheter lock solution into an indwelling catheter. Disclosed compositions, methods, devices and kits aid in diminishing the effects of microbial infection in catheters and occlusion of the catheters. A representative lock solution includes about 10% sodium citrate and about 1.5% benzyl alcohol. The solution has a density approximating the density of blood for retention of the solution in a catheter during the lock period.

A multi-layer article including a first non-active state and a second active state, the multi-layer article comprising an outer layer having a first side and a second side, an inner layer adjacent to at least a portion of the outer layer and including a volatile material, and an upper layer including a first side and a second side, the first side of the upper layer being adjacent to at least a portion of the inner layer. The multi-layer article is folded upon itself in the first non-active state so that at least a first portion of the second side of the upper layer is disposed on a top of a second portion of the second side of the upper layer, and the first portion and the second portion of the upper layer are heat sealed in the non-active state.

A method for the reduction and prevention of mercury emissions into the environment from combusted fossil fuels or other off-gases with the use of peracetic acid is disclosed. The peracetic acid is used for the capture of mercury from the resulting flue gases using a flue gas desulfurization system or scrubber. The method uses peracetic acid in conjunction with a scrubber to capture mercury and lower its emission and/or re-emission with stack gases. The method allows the use of coal as a cleaner and environmentally friendlier fuel source as well as capturing mercury from other processing systems.

The invention discloses a method for sanitization of a bioprocess chromatography column, comprising the steps of: a) providing a bioprocess chromatography column with a packed bed of separation resin particles and a movable adapter, b) with the adapter in contact with the packed bed, conveying a sanitization fluid through the packed bed to a column outlet; c) raising the adapter to provide a gap between the packed bed and the adapter, d) lowering the adapter to close the gap; and e) conveying an equilibration liquid through the packed bed to a column outlet.