In alternative embodiments, the invention provides articles of manufacture comprising biocompatible nanostructures comprising PolyEther EtherKetone (PEEK) surface-modified (surface-nanopatterned) to exhibit nanostructured surfaces that promote osseointegration and bone-bonding for, e.g., joint (e.g., knee, hip and shoulder) replacements, bone or tooth reconstruction and/or implants, including their use in making and using artificial tissues and organs, and related, diagnostic, screening, research and development and therapeutic uses, e.g., as primary or ancillary drug delivery devices. In alternative embodiments, the invention provides biocompatible nanostructures that promote osseointegration and bone-bonding for enhanced cell and bone growth and e.g., for in vitro and in vivo testing, restorative and reconstruction procedures, implants and therapeutics.

A low-bulk disposable absorbent pant for a child is disclosed. The pant may have a belt structure formed of a stretch laminate of a pre-strained elastic film between two nonwoven layers. The belt may have a relaxed lateral size and a stretched lateral size that is at least 150% of the relaxed lateral size, the relaxed lateral size being no more than 400 mm. The pant may include one or more of waistband, leg band and supplemental elastic members.

A stretch laminate having enhanced texture, and method for its manufacture is disclosed. The stretch laminate may include two nonwoven layers sandwiching an elastic member, the elastic member having been incorporated into the laminate in a pre-strained condition such that z-direction ruffles in the nonwoven materials are imparted to the laminate when it is in a relaxed condition. At least one of the nonwoven layers may be incrementally stretched or SELFed, adding a pattern of ridges and valleys to the material that combines with the ruffles, further enhancing loft and texture of the laminate.

A method to produce a wear resistant foil, including providing a first foil including a first thermoplastic material, applying wear resistant particles on the first foil, applying a second foil including a second thermoplastic material on the first foil, and adhering the first foil and the second foil to each other to form a wear resistant foil.

A wavelength conversion member, for a backlight, is provided. The wavelength conversion member includes a stack of a plurality of resin layers, with at least one of the plurality of resin layers containing quantum dots. The plurality of resin layers is integrally molded through co-extrusion, and forms a three-layer structure comprising a middle layer containing the quantum dots and upper and lower layers that do not contain the quantum dots. The upper layer and the lower layer are respectively on an upper side and a lower side of the middle layer. The upper and lower layers each contain a light scattering agent. Each of the plurality of resin layers is directly joined together with a bonding layer at an interface between the middle layer and the upper layer and not at an interface between the middle layer and the lower layer.

A method to produce a wear resistant foil, including providing a first foil including a first thermoplastic material, applying wear resistant particles on the first foil, applying a second foil including a second thermoplastic material on the first foil, and adhering the first foil and the second foil to each other to form a wear resistant foil.

Provided is a single material plastic push-through blister pack for food and pharmaceutical packaging and a method of making thereof. The blister package may be produced by thermoforming polymer films for the cavity and a cavitated polymer film made from the same class of polymer comparatively lower thickness for the substrate or lid. To facilitate the push through breaking, the polymer film used as the lidding film may be modified to a microcavitated film by creating micro-voids/cavities and micro-brittleness within the polymer matrix. These micro-voids/cavities, and/or embedded microcrystalline particles present in the polymer matrix of the lidding film, may create internal cracks in the film by application of a small external force, which may then result in rupturing of the lid film to dispense a product from the cavity of the blister pack.

Described herein is a building panel comprising a body comprising a first fibrous material comprising inorganic fiber, a non-woven scrim coupled to the body; and wherein the non-woven scrim has a thickness ranging from about 8 mils to about 20 mils.

Provided are a film including a layer A, and a layer B provided on at least one surface of the layer A, in which an elastic modulus of the layer A at 160 C. is 100 MPa to 2,500 MPa, and a value of a difference L.sup.AL.sup.B between a value L.sup.A obtained by subtracting a weight residual rate of the layer A at 900 C. from a weight residual rate of the layer A at 440 C. and a value L.sup.B obtained by subtracting a weight residual rate of the layer B at 900 C. from a weight residual rate of the layer B at 440 C. is 80% or less.

Breathable multilayer films suitable for a wide variety of uses (e.g., protective apparel, surgical gowns, surgical drapes, aprons, roofing material, house wrap, etc.) are disclosed. The breathable multilayer film may include a monolithic core layer. The monolithic core layer may comprise at least one highly breathable polymer. The breathable multilayer film may also include at least one skin layer. The skin layer or layers may comprise at least one highly breathable polymer, a filler, and a non-breathable material. An exemplary structure of the breathable multilayer film provides a monolithic core layer, a first skin layer on one side of the monolithic core layer, and a second skin layer on the other side of the monolithic core layer. An exemplary construction of one or both of the skin layers includes one or more highly breathable polymers, a filler, and a non-breathable material. The filler, for example, may comprise calcium carbonate.