An antibacterial glove of the disclosure includes a woven or nonwoven absorbent or semi-absorbent substrate material infused with a disinfectant composition, wherein the glove includes one or more layers, and each layer comprises the woven or nonwoven absorbent or semi-absorbent substrate material. The antibacterial glove may include a hand sanitizing composition impregnated therein. The disinfectant composition may include an alcohol, hydrogen peroxide, and/or hypochlorite. The woven or nonwoven absorbent or semi-absorbent substrate material may include a cellulosic fiber and/or a thermoplastic fiber.

A fabric containing nanotubes which is impervious to viruses, bacteria, and other pathogens; which is self-sterilizing and reusable; and a method of producing the same are disclosed. The fabric can be used to construct facemasks, gloves, protective suits, protective habitats, continuous air filtration/sterilization systems or any other type of protective clothing or structure. The fabric may have integrated temperature monitoring sensors. The fabric may be made into patches which may be integrated into existing articles of clothing. When connected to an electrical power source, either via built-in electrical connections or by induction, the active layer which is one of the components of the fabric will heat to a temperature high enough to eliminate potential biological contamination from viruses, bacteria and other microbial threats. Combining the CNT active layer with an insulating layer will allow a garment to be continuously worn or used without needing removal during multiple sterilization cycles.

A face mask completely made from hemp fabric.

The present invention falls within the area of polymeric materials applied to the sector of manufacturing materials for use in filters for filtration equipment such as ventilators and for protective masks. In particular, the invention relates to multilayer filters for ventilators and protective masks which can be biodegradable and which comprise filtration materials based on ultrafine fibers obtained by electrohydrodynamic and aerohydrodynamic processing and which exercise passive FFP1, FFP2, N95 and FFP3 protection and which can also be washable and have active antimicrobial properties.

A reusable protective glove with antimicrobial properties. The reusable protective glove is formed from several layers incorporated together. A palm side of the reusable protective glove is formed from a polyester base layer and an antimicrobial outer layer. The antimicrobial outer layer is manufactured from copper mesh fabric or copper metal powder mesh. A back side of the reusable protective glove is formed from an expandable fabric material which is attached to the palm side along a seam. The reusable protective glove is tear resistant. Additionally, the antimicrobial outer layer is capable of killing pathogens on contact preventing retransmission of the pathogens.

Disclosed is a method and device for inactivating or killing airborne bacteria, fungi, molds and viruses by passing the air through a filter material formed of a fabric having particles of zinc disposed in discrete physically isolated locations, wherein the particles of zinc and oxygen from the air form half cells of a battery whereby to create an electrical field that inactivates or kills airborne bacteria, fungi, molds and viruses passing through the filter material.

Disclosed is a method and device for inactivating or killing airborne bacteria, fungi, molds and viruses by passing the air through a filter material formed of a fabric having particles of zinc disposed in discrete physically isolated locations, wherein the particles of zinc and oxygen from the air form half cells of a battery whereby to create an electrical field that inactivates or kills airborne bacteria, fungi, molds and viruses passing through the filter material.

A cartridge for applying an electromagnetic field (EMF) to at least one toxin in a wound in the skin of a person or animal is provided. The cartridge includes a power supply, a controller coupled to the power supply and providing a voltage between about 0.2V and 3V to an array of electrodes configured to transmit the EMF to the skin about the wound site. A cartridge for applying an ultrasonic field to at least one toxin in a wound in the skin of a person or animal is also provided. The ultrasonic cartridge may include a power supply, a controller coupled to the power supply and providing a voltage to at least one sonotrodes configured to transmit the ultrasonic field to the skin about the wound. The cartridge may also include a sensor for measuring the resistance or impedance in the tissue to be treated and the controller can adjust the ultrasonic field based on the impedance or resistance.

A product or a surface is being coated by anti-viral particles, or a product is being loaded with anti-viral particles, thereby possessing anti-viral properties and reducing/preventing viral infection. Specifically, an anti-viral fiber, fabric, or fabric based product is disclosed comprising anti-viral particles for use in reducing and preventing viral infection.

A personal protective device (PPE) comprising a face cover assembly and a bodysuit configured to be worn by a human user. The device protects users against airborne aerosol particles containing viruses or other infectious agents while enabling improved flexibility relative to prior art designs. The device includes a helmet-like” rotating face cover assembly that fits over the user's head and attaches to a collar on the biohazard bodysuit. This rotating face cover assembly has a plurality of different mask sides, each with differing geometries or other properties. The device enables a user to can rotate the cover and select a given mask side that best meets that user's needs. The different mask sides can accommodate different facial geometries, eyewear types, and use cases.