Electret webs include a thermoplastic resin and a charge-enhancing additive. The charge-enhancing additive is a substituted- or unsubstituted benzoate salt. The substituted benzoate salts are substituted by a hydroxyl group. The substituted-benzoate salt may have a divalent metal countercation.

A method for providing a bio-active layer on a surface, includes the steps of: a) ionizing a plasma gas at low temperature of 150° C. or lower, and at about atmospheric pressure, thereby creating a plasma; b) introducing a precursor into the plasma; c) exposing the surface to the plasma comprising the precursor, thereby forming a coating onto the surface. The plasma gas is ionized by means of electrodes, wherein the plasma gas is ionized by the electrodes with a power of at most 10 Watt per cm.sup.2 of the electrode surface. The bio-active layer is an antibiofouling layer, an antibacterial layer, an antiviral layer and/or a microbial collecting layer, such that the plasma gas includes inert gas for at least 99% by volume. The inert gas is a non-noble gas.

A plasma device applies cold atmospheric plasma to a surface to be treated, in particular to textiles, leather and/or plastic fibers. An actuator activates a plasma source, provided that a distance between the plasma source and the surface to be treated is less than a predetermined distance. The actuator has an adjustable and pre-loaded actuator element with at least one activation element and has a recording apparatus that records the position of the actuator element at least when the distance between the plasma source and the surface to be treated is less than the predetermined distance. The plasma device makes it possible to avoid risks owing to incorrect operation by the client and to avoid emissions, since the plasma source is activated only when the distance from the item to be treated (e.g., clothing to be cleaned) is less than the predetermined threshold distance.

A system and method for depositing a coating may comprise a coating chemical reactor, surface activation component, and a deposition component. A target surface may be prepared for deposition with the surface activation component. The coating chemical reactor may comprise a coating chemical dispenser and a coating chemical verifier that prepares the coating chemical for deposition. The coating chemical verifier may utilize an optical excitation source and at least one optical detector, wherein chemical substances are identified by unique signatures composed of binary code. The coating chemical may be received by the deposition component to depositing the coating chemical on the target surface.

This invention relates to a method for hiding stains in medical dressings and other textile substrates. The method includes applying a metallic silver coating to a textile substrate via a plasma enhanced chemical vapor deposition (PECVP) process. The metallic silver coating effectively hides any stain that comes into direct contact with the treated substrate by transferring the liquid beneath the surface of the coating. The invention also relates to textile substrates containing metallic silver coatings.

An object of the present invention is to provide a fabric capable of easily and inexpensively forming a desired three-dimensional shape. The fabric according to the present invention contains an artificial protein fiber that contains a protein, in which the fabric has a surface including: a portion A that shrinks at a predetermined shrinkage rate when being brought into contact with water; and a portion B that has a shrinkage rate lower than that of the portion A when being brought into contact with water.

Cellulosic fibrous materials are described which are impregnated with a bioflavonoid composition, the bioflavonoid content of the composition comprising at least naringin and neohesperidin. The use of such impregnated materials is also described, for example as paper or bamboo towels and cardboard, as well as the process for impregnating the materials.

The invention provides fabrics that incorporate enzymes that inactivate microbial pathogens, particularly enveloped viral particles such as those of Influenza virus and Coronavirus such as Covid-19. The fabrics of the invention may be used in the production of various items including protective facemasks.

A charged multilayer nanofiber filter for air filtration and the fabrication method thereof is disclosed. The charged multilayer nanofiber filter has a plurality of charged nanofiber mats. Each of the plurality of charged nanofiber mats is obtained by charging nanofiber mats individually before assembling. The nanofiber mat comprises a nanofiber layer and a substrate layer. The plurality of charged nanofiber mats is assembled such that the nanofiber layers and the substrate layers are stacked together in an alternative manner. The charged multilayer nanofiber filter can be fabricated by electrospinning a polymer solution on the substrate layer to obtain a nanofiber mat, charging the nanofiber mat to obtain a charged nanofiber mat, and assembling a plurality of charged nanofiber mats to form the charged multilayer nanofiber filter.

The disclosure relates to high-strength polyolefin composite fibers, which fibers have a fiber body comprising a composition consisting of polyolefin; 1-30 mass % of bioceramic particles having particle size D50 of 0.01-10 μm; at most 0.05 mass % of residual spin solvent; optionally 0-3 mass % of other additives; and wherein the sum of a)-d) is 100 mass %; and which fibers have bioceramic particles exposed at their surface, and show bioactivity. The composite fibers based on a composition of polyolefin with bioceramic particles mixed therein show particles being exposed at the fiber surface by techniques like AFM and XPS, and although apparently only a relatively small amount of bioceramic particles is exposed at the fiber surface, this appears sufficient for effective interaction with their environment and stimulating a positive biological response as demonstrated by in vitro cell studies.

The present disclosure also concerns a method of making the high-strength composite fibers via a gel spinning process, fibrous articles comprising said bioactive composite fibers. Further embodiments concern use of these fibrous articles as a component of a medical implant or as a medical implant, especially as permanent high-strength orthopedic implants for repairing bone fractures or torn ligaments or tendons. Other embodiments include medical devices or implants comprising said fibrous articles.