Protein fibers for artificial hair include a polycation, wherein the protein fibers for artificial hair are crosslinked with an organic compound and/or a metal salt, and the protein fibers for artificial hair have curls. A method for producing the protein fibers for artificial hair includes treating artificial protein fibers that are crosslinked with an organic compound and/or a metal salt with a treatment solution containing a polycation, and curling the artificial protein fibers, or curling artificial protein fibers that are crosslinked with an organic compound and/or a metal salt, and treating the curled artificial protein fibers with a treatment solution containing a polycation.

Provided are leather fibers for yarn. The leather fibers forming the yarn are obtained from cowhide. An amount of the leather fibers having an H value of 30 or more is 30% by weight or more of a total leather fibers contained in the yarn. The H value is defined by the following Equation 2: [Equation 2] H=L/D where L: leather fiber length, and D: leather fiber thickness. A thickness index (M) of the leather fibers satisfies Equation 1: [Equation 1] M=D1/D2?60 where D1: an average thickness of 0 fibers having a highest thickness in 1 mg of leather fibers, and D2: an average thickness of 10 fibers having a lowest thickness in 1 mg of leather fibers.

Described herein are methods of using electrospun core-shell fibers for bulk electroporation. The disclosed electrospun core-shell fibers include (i) a central core that is electrically conductive having an exterior surface, wherein the core comprises a first polymer and an electroconductive material; (ii) a shell adjacent to the exterior surface of the core, the shell comprising a second polymer; and (iii) one or more bioactive agents in the shell. In one aspect, the fibers are electrospun fibers.

Provided is a leather fiber for leather spun yarn with improved physical properties of the leather spun yarn by containing leather fibers with more improved length, thickness, fineness, and the like than conventional leather fibers, in which the leather fiber has an average length of 15 mm or more and 40% or more of the content of fibers of more than 15 mm, in the leather fibers for the leather spun yarn contained in the leather spun yarn formed by containing the leather fibers and natural fibers or/and regenerated fibers.

Provided is leather spun yarn with improved physical properties of the leather spun yarn by containing leather fibers longer than conventional leather fibers, in which the leather fiber has an average length of 15 mm or more and 40% or more of the content of fibers of more than 15 mm, in the leather fibers for the leather spun yarn contained in the leather spun yarn formed by containing the leather fibers and synthetic fibers.

A collagen containing-plastic masterbatch of which the composition includes a thermoplastic polymer and a collagen is provided, wherein the collagen is uniformly distributed in the thermoplastic polymer, and wherein in the collagen containing-plastic masterbatch, the collagen content is about 1-50 wt %. A collagen containing-plastic fiber formed by at least one kind of plastic masterbatch through melt spinning is further provided, wherein the at least one kind of plastic masterbatch includes the above-mentioned collagen containing-plastic masterbatch.

The present disclosure is directed to a naniofiber comprising a jellyfish extract and at least one non-jellyfish-derived electrospinnable polymer. The jellyfish extract may comprise an alcohol extract of jellyfish biomass. The jellyfish extract may comprise comprise Q-mucin. Methods of producing the nanofiber are also disclosed.

In general, the present invention is related to biopolymer and biocomposite materials and structures, and methods of making and using the same. In some embodiments, the present invention is directed to oriented collagen based biocomposite materials and structures, and methods of making.

Silk infused performance apparel and methods of preparing the same are disclosed herein. In some embodiments, silk performance apparel includes textiles, fabrics, consumer products, leather, and other materials that are coated with aqueous solutions of pure silk fibroin-based protein fragments. In some embodiments, coated apparel products, textiles, and upholstery, as well as other materials, exhibit surprisingly improved moisture management properties, resistance to microbial growth, increased abrasion resistance, and flame resistance.

This invention describes a modified electrospinning method for making uniformly patterned and porous nanofibrous scaffolds that can be utilized in a variety of applications. While traditional electrospinning method uses a foil collector that generates compact layers of nanofibrous structures, resulting on the superficial cell growth and differentiation, the present method comprises adopting additional patterned film(s) on top of the conventional collector to make a patterned porous structure of nanofibrous scaffolds that are capable of supporting cell growth. For example, the method uses a double layered collector composed of a water soluble stabilizer film mounted on a foil to make a uniformly patterned and porous nanofibrous membrane sheets, which enhance both cell growth and attachment.