A chair for particular use in clinical or hospital environments has a frame to which a support material is secured. The support material may form a chair back and/or a seat for the chair to provide support to the chair occupant. The support material may be made from a textile of interwoven strands wherein some of the interwoven strands include copper containing particles such as copper iodide or copper oxide within the textile fibers.

A chair for particular use in clinical or hospital environments has a frame to which a support material is secured. The support material may form a chair back and/or a seat for the chair to provide support to the chair occupant. The support material may be made from a textile of interwoven strands wherein some of the interwoven strands include copper containing particles such as copper iodide or copper oxide within the textile fibers.

A method for preparing a bactericidal film on fiber cloth, comprising cleansing a reel of fiber cloth; placing the reel of fiber cloth into a vacuum chamber; supplying a DC power and a mid-frequency power; introducing argon gas to increase the chamber pressure to 0.3 Pa; position sputtering targets in the following order: silicon target, silicon carbide target, silver target, silicon carbide target, silver target, silicon carbide target and silver target, and then sputtering the targets simultaneously; wherein the silicon targets act as a bonding layer between the bactericidal film and the substrate; stopping the silicon targets, the silicon carbide targets and the silver targets first, and then turning off the argon gas; injecting air into the chamber until the pressure in the chamber and the atmospheric pressure are balanced.

A method for preparing a bactericidal film on fiber cloth, comprising cleansing a reel of fiber cloth; placing the reel of fiber cloth into a vacuum chamber; supplying a DC power and a mid-frequency power; introducing argon gas to increase the chamber pressure to 0.3 Pa; position sputtering targets in the following order: silicon target, silicon carbide target, silver target, silicon carbide target, silver target, silicon carbide target and silver target, and then sputtering the targets simultaneously; wherein the silicon targets act as a bonding layer between the bactericidal film and the substrate; stopping the silicon targets, the silicon carbide targets and the silver targets first, and then turning off the argon gas; injecting air into the chamber until the pressure in the chamber and the atmospheric pressure are balanced.

Methods of forming an antiviral facial mask that is capable of not only filtering pathogen particles, but also deactivating pathogen particles prior to exposure by the wearer. Typical facial masks do not deactivate pathogen particles, but rather merely capture viral particles on an outer surface of the mask. As such, the masks present a risk of interaction between the mask wearer and the particles, such as during the removal and/or application of the masks. Methods of forming enhanced antiviral facial masks include the formation of fibers via electrospinning, such that the fibers include a solution of two oppositely charged polyelectrolytes, surfactants, and metal ions. In use, water from human breath activates the surfactants to capture and deactivate pathogen particles. Moreover, the strength of the fibers from the oppositely charged polyelectrolytes results in increased lifespans of the masks, as the masks do not breakdown in the presence of high humidity.

Disclosed is a method of manufacturing an antibacterial cover window. The method includes a first step of preparing a substrate, a second step of forming a mask pattern on the substrate through a patterning process, a third step of forming an antibacterial layer on the substrate on which the mask pattern is formed, and a fourth step of removing the mask pattern to obtain an antibacterial pattern formed on the substrate. Through the method, it is possible to produce a cover window with antibacterial patterns regularly and uniformly distributed over the entire area thereof. Thus, the cover window has long-lasting excellent antibacterial property over the entire area thereof.

Disclosed is a method of manufacturing an antibacterial cover window. The method includes a first step of preparing a substrate, a second step of forming a mask pattern on the substrate through a patterning process, a third step of forming an antibacterial layer on the substrate on which the mask pattern is formed, and a fourth step of removing the mask pattern to obtain an antibacterial pattern formed on the substrate. Through the method, it is possible to produce a cover window with antibacterial patterns regularly and uniformly distributed over the entire area thereof. Thus, the cover window has long-lasting excellent antibacterial property over the entire area thereof.

Certain embodiments described herein are directed to door knob covers, latch covers, urinal handle covers and other covers that can reversibly couple to an underlying structure. In some examples, the cover comprises a bioactive material that can kill or inactivate bioorganisms. The bioactive material can be a photocatalyst and may also comprise one or more transition metals. Methods of preventing or reducing the spread of infections using the covers are also described.

Certain embodiments described herein are directed to door knob covers, latch covers, urinal handle covers and other covers that can reversibly couple to an underlying structure. In some examples, the cover comprises a bioactive material that can kill or inactivate bioorganisms. The bioactive material can be a photocatalyst and may also comprise one or more transition metals. Methods of preventing or reducing the spread of infections using the covers are also described.

An antimicrobial composition includes an organic extract, such as a witch hazel extract, and a colloid selected from metal, halogen, and combinations of these, such as a silver colloid. The witch hazel extract includes tannins in excess of about 10 mg/ml, such as hamamelitannin, and the colloid includes about 10,000 PPM of metal, such as silver. The antimicrobial composition may be applied to or instilled through an indwelling urinary catheter or other medical device.