A method for preparing a skin regeneration scaffold is disclosed. The method may include preparing a polymer solution by dissolving a biopolymer in a solvent, and subjecting the polymer solution to a template-assisted extrusion process with a nanoporous material as a template in order to produce polymer nanofibers. Furthermore, the method includes fabricating a multilayer composite nanofibrous scaffold using the polymer nanofibers. The composite nanofibrous scaffold may be seeded with cells. In some cases, the cells may be selected from autologous cells, allogeneic cells, or combinations thereof.

Bone tissue biomimetic materials, biomimetic constructs that can be formed with the materials, and methods for forming the materials and constructs are described. The bone tissue biomimetic materials include electrospun nanofibers formed of polymers that are conjugated with peptides that include acidic amino acid residues. The materials can incorporate high levels of mineralization so as to provide mechanical strength and promote osteogenesis and/or osteoconductivity on/in the bone tissue biomimetic materials. The materials and constructs can be utilized in forming tissue engineered structures for in vitro and in vivo use. Macroscopic bone tissue biomimetic scaffolds formed from the materials can be seeded with osteogenic cells and utilized to develop bone graft materials that can exhibit strength and osteoconductivity similar to the native bone and that exhibit uniform distribution of nutrients in the scaffolds.

A fiber for protein adsorption has a water absorption percentage of 1 to 50%, and the fiber includes a polymer containing as repeat units an aromatic hydrocarbon or a derivative thereof, wherein part of aromatic rings contained in the repeat units are cross-linked through a structure represented by Formula (I). A column for protein adsorption uses the fibers. A in Formula (I) is selected from an alkyl aliphatic group, phenyl aromatic group and amino group.

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Aspects of the present disclosure generally relate to electronic textiles and more specifically to self-sustaining, interactive electronic textiles, to systems incorporating such electronic textiles, and to uses thereof. In an embodiment, a system to assist with an intended motion of a user is provided. The system includes one or more processors, and an electronic textile. The electronic textile includes a textile substrate, an actuator coupled to the textile substrate, a sensor coupled to the textile substrate, and a battery coupled to the textile substrate, the battery electrically coupled to a conductive yarn, the conductive yarn further electrically coupled to the actuator and the sensor. Embodiments also include a system to assist with blood circulation of a user and a method of assisting blood circulation of a user.

Disclosed is a wet wipe, for example, a dispersible wet wipe. The wet wipe may include a base sheet comprising short length fibers; a dispersible binding agent reinforcing the base sheet; and a wetting lotion. The dispersible binding agent may be configured to bind the fibers of the base sheet when the dispersible wipe includes liquid at an amount of at most 400 wt % from the weight of the base sheet and to disperse in excess water if the amount of the water exceeds 500 wt %.

Disclosed are hollow fibers suitable for use in dialysis in an outside-in configuration. For such fibers, it is desirable that the fiber have a low albumin sieving coefficient and have a permeability high enough to be considered a High Flux dialyzer, and it is desirable that the outer (blood-facing) surface have a sufficiently small roughness and be hydrophilic. It is desirable that there be a selective layer on the outer surface and, interiorly of that, a porous structurally supportive region, which may contain elongated macrovoids. Such a fiber may be spun through a triple-concentric spinneret that produces a bore liquid surrounded by dope surrounded by a shower. The shower and the coagulation bath may be pure water, which is a non-solvent. The process may be performed at room temperature. Spinning parameters are discussed.

A biodegradable and biocompatible barrier membrane of piezoelectric nano composites of Metallic Oxide (MO) (e.g., Magnesium oxide, Zinc oxide and iron oxide)-PLLA (Poly-L-lactide), which can be subjected to acoustic pressure from ultrasound, to generate useful electrical charge for enhanced bone regeneration and enhanced antibacterial effects for guided bone regeneration to treat dental diseases, such as periodontitis.

Aspects herein are directed to a tubular knit sleeve for a below-the-knee amputee where the tubular knit sleeve includes zoned grip features, zoned cushioning features, zoned traction features, and zoned breathability/permeability features that facilitate the wearer participating in athletic activities, such as wrestling, without a prosthetic leg.

The present disclosure relates to compositions, apparatus and methods for generating one or more scaffolds, including: mixing a hydrogel material and/or an extracellular matrix (ECM) protein in an aqueous solvent to generate an aqueous process solution; and cryoelectrospinning the aqueous process solution onto a plurality of conductive probes extending from a conductive surface of a collector plate disposed within a process chamber under conditions sufficient to generate one or more scaffolds configured to mimic a preselected soft tissue decellularized extracellular matrix. Scaffold compositions are also provided having preselected or tuned characteristics.

The present invention refers to yarns made of hollow trilobal cross section filaments, comprising from 90 to 99% of polypropylene, and between 1 and 10% of other polyolefin resins, for the application on dental floss. This invention additionally refers to the production process of the yarns made of hollow trilobal cross section filaments. This invention additionally refers to dental floss comprising hollow trilobal cross section filaments, and the use of hollow trilobal cross section filaments for the manufacture of dental floss. The yarn described in this invention has linear density or title in the range from 400 to 1200 dtex, and it is twisted with a twist level from 10 to 160 twists per meter.