Disclosed is a method and apparatus for using iodinated polymer as an antimicrobial agent to manage the suppression and disinfection of pathogens.

The invention relates to stable, anhydrous concentrated disinfectant formulations.

Provided are a complex oxide ceramic having high antiviral activity, a functional material, and an article provided with the complex oxide ceramic and/or the functional material. The complex oxide ceramic according to one aspect of the present invention is a complex oxide ceramic containing cerium and molybdenum and having antiviral activity. The functional material according to one aspect of the present invention is also a functional material including the complex oxide ceramic mixed with a photocatalyst and/or an antibacterial effect. The article according to one aspect of the present invention is an article having the complex oxide ceramic and/or the functional material on at least a part of the surface thereof.

A device for characterizing substances in a scene, the device including a housing having a cavity configured to contain the substances, an opening for receiving the substances, an imager for capturing an image of the substances, an illumination source for illuminating the substances, a sensor for obtaining sensory data of the substances, a gas supply device for storing and inserting gas into the housing, a mechanical arm for inserting or removing the substances into or from the device via the opening, a syringe to add a material into the housing, a pump for creating a vacuum in the device, an air pump to suck air from the housing and removing the substances from the housing, a fan for cooling the housing, a fluid injector for inserting fluid into the housing, and a processor in communication with the imager and the sensor imaging module. The processor receives the sensory data and the captured images, and compares them to a. database to identify the characteristics of the substances.

A powered disinfectant dispensing device for providing disinfectants is presented. The powered disinfectant dispensing device allows for an easy distribution of disinfectant to a person. The device is both light weight and efficient while providing a small footprint for storage. The device automatically dispenses liquid disinfectant in an airborne manner. The device has a fan that is utilized to provide wind behind a disinfectant to cause the disinfectant to become airborne and evenly distribute the disinfectant.

A powered disinfectant dispensing device for providing disinfectants is presented. The powered disinfectant dispensing device allows for an easy distribution of disinfectant to a person. The device is both light weight and efficient while providing a small footprint for storage. The device automatically dispenses liquid disinfectant in an airborne manner. The device has a fan that is utilized to provide wind behind a disinfectant to cause the disinfectant to become airborne and evenly distribute the disinfectant.

A device for reducing a level of infectious agents present on one or more hands of a user. This device may reduce the level of infectious agents present on one or more fingers and/or thumbs of a user, specifically reducing a level of infectious agents present on the distal aspect of the digit; including, but not limited to an underside of a nail plate, and an area of hyponychium skin between a free margin of the nail plate and an onychodermal band of a digit, such as for example, a finger, thumb, or toe.

Systems and methods for reducing pathogens near an implant are discussed. In some cases, the methods include reducing contaminants in a portion of a patient that has an implant and that is disposed interior to a closed surface of skin of the patient. The method can further include placing a conduit in the closed surface of skin and flowing an antimicrobial fluid into that portion of the patient to contact the antimicrobial fluid with a surface of the implant and tissue adjacent to the implant. In some cases, the antimicrobial fluid is then removed from the portion of the patient having the implant. As part of this method, biofilm near the implant can be mechanically, ultrasonically, electrically, chemically, enzymatically, or otherwise disrupted. Other implementations are described.

A dry biocidal absorbent composition comprises an interspersed mixture of a dry absorbent silicate mineral material and a dry biocide. The absorbent silicate mineral material may comprise expanded perlite and/or exfoliated vermiculite. The biocide may comprise sodium dichloroisocyanurate or a hydrate thereof. The composition may be used for cleaning up a bodily spill from a floor or other surface.

A dry biocidal absorbent composition comprises an interspersed mixture of a dry absorbent silicate mineral material and a dry biocide. The absorbent silicate mineral material may comprise expanded perlite and/or exfoliated vermiculite. The biocide may comprise sodium dichloroisocyanurate or a hydrate thereof. The composition may be used for cleaning up a bodily spill from a floor or other surface.