A hydrogel structure which has: (a) a one way penetrating polyurethane film layer; (b) a hydrophobic pressure sensitive adhesive layer; (c) a multi-directional elastic meltblown nonwoven; (d) an interpenetrating polymer network; and (e) a hydrogel; wherein the meltblown nonwoven and the hydrogel are laminated by UV curing to form the interpenetrating polymer network, part of fibers of the meltblown nonwoven are exposed and fit stably with the pressure sensitive adhesive film. The hydrogel structure can make dressings multi-directional elastic for multiple traumas. The hydrogel structure can provide an environment suitable for wound healing, shorten the healing time, antiseptic and reduce the chances of being infected for the wound dressing.

A hydrogel structure which has: (a) a one way penetrating polyurethane film layer; (b) a hydrophobic pressure sensitive adhesive layer; (c) a multi-directional elastic meltblown nonwoven; (d) an interpenetrating polymer network; and (e) a hydrogel; wherein the meltblown nonwoven and the hydrogel are laminated by UV curing to form the interpenetrating polymer network, part of fibers of the meltblown nonwoven are exposed and fit stably with the pressure sensitive adhesive film. The hydrogel structure can make dressings multi-directional elastic for multiple traumas. The hydrogel structure can provide an environment suitable for wound healing, shorten the healing time, antiseptic and reduce the chances of being infected for the wound dressing.

The invention provides a wound dressing, which includes a 1 to 12 mm thick layer of absorbent non-woven fibre material between 150 and 1200 grams per square meter, which layer includes a mixture of viscose fibres and polyester fibres which more viscose than polyester, and of which the fines of the viscose is between 1.5 and 3 dtex and the fines of the polyester is between 2 and 3 dtex.

The invention provides a wound dressing, which includes a 1 to 12 mm thick layer of absorbent non-woven fibre material between 150 and 1200 grams per square meter, which layer includes a mixture of viscose fibres and polyester fibres which more viscose than polyester, and of which the fines of the viscose is between 1.5 and 3 dtex and the fines of the polyester is between 2 and 3 dtex.

Odor control articles (10) including hydrophobic polymers of intrinsic porosity (HPIM) and their use in personal care products and hygienic products is disclosed. The odor control article (10) includes a HPIM and a colorant. The odor control article (10) may be applied to a substrate (11), and more specifically to a liquid absorbent member (30), to form an odor-absorbing member (20). The substrate (11) may absorb liquid. The odor-absorbing member (20) may be placed in such products as diapers (200), incontinence pads (60) and refrigerator pads. A method of making an odor control suspension with HPIMs including the use of surfactants is also disclosed. The odor control suspension may also be applied to a substrate (11).

Odor control articles (10) including hydrophobic polymers of intrinsic porosity (HPIM) and their use in personal care products and hygienic products is disclosed. The odor control article (10) includes a HPIM and a colorant. The odor control article (10) may be applied to a substrate (11), and more specifically to a liquid absorbent member (30), to form an odor-absorbing member (20). The substrate (11) may absorb liquid. The odor-absorbing member (20) may be placed in such products as diapers (200), incontinence pads (60) and refrigerator pads. A method of making an odor control suspension with HPIMs including the use of surfactants is also disclosed. The odor control suspension may also be applied to a substrate (11).

A bacteria-responsive color-changing, core-shell nanofiber, comprising polyurethane (PU), a hemicyanine-based chromogenic probe localized in the core-shell nanofiber near the surface of the shell, polyvinylpyrrolidone (PVP) dopant in the shell, the hemicyanine-based chromogenic probe further comprising a labile ester linkage that is enzymatically cleavable by bacterial lipase released from clinically relevant strains of bacteria including Pseudomonas aeruginosa and methicillin-resistant Staphylococcus aureus (MRSA).

A bacteria-responsive color-changing, core-shell nanofiber, comprising polyurethane (PU), a hemicyanine-based chromogenic probe localized in the core-shell nanofiber near the surface of the shell, polyvinylpyrrolidone (PVP) dopant in the shell, the hemicyanine-based chromogenic probe further comprising a labile ester linkage that is enzymatically cleavable by bacterial lipase released from clinically relevant strains of bacteria including Pseudomonas aeruginosa and methicillin-resistant Staphylococcus aureus (MRSA).

An odor and menses absorption device includes a user contact layer and at least one adjoining super absorbent core layer. Fluid can move from the user contact layer to the super absorbent core layer. The user contact layer contains a blend of polylactic acid fiber and bamboo charcoal fiber and acts as a barrier to fluids with a surface tension greater than 30 dynes.

An odor and menses absorption device includes a user contact layer and at least one adjoining super absorbent core layer. Fluid can move from the user contact layer to the super absorbent core layer. The user contact layer contains a blend of polylactic acid fiber and bamboo charcoal fiber and acts as a barrier to fluids with a surface tension greater than 30 dynes.