A composition includes a target pharmaceutical or biological agent, a solution containing the target pharmaceutical or biological agent, and substrate that is soluble in the solution. The substrate is capable of being solidified via a solidification process and the solidification process causes the substrate to become physically or chemically cross-linked, vitrified, or crystallized. As a result of the solidification process, particles are formed. The target pharmaceutical or biological agent within the solution retains proper conformation to ultimately produce a desired effect.

This invention includes malleable, biodegradable, fibrous compositions for application to a tissue site in order to promote or facilitate new tissue growth. One aspect of this invention is a fibrous component that provides unique mechanical and physical properties. The invention may be created by providing a vessel containing a slurry, said slurry comprising a plurality of natural or synthetic polymer fibers and at least one suspension fluid, wherein the polymer fibers are substantially evenly dispersed and randomly oriented throughout the volume of the suspension fluid; applying a force, e.g., centrifugal, to said vessel containing said slurry, whereupon said force serves to cause said polymer fibers to migrate through the suspension fluid and amass at a furthest extent of the vessel, forming a polymer material, with said polymer material comprising polymer fibers of sufficient length and sufficiently viscous, interlaced, or interlocked to retard dissociation of said polymer fibers.

This invention includes malleable, biodegradable, fibrous compositions for application to a tissue site in order to promote or facilitate new tissue growth. One aspect of this invention is a fibrous component that provides unique mechanical and physical properties. The invention may be created by providing a vessel containing a slurry, said slurry comprising a plurality of natural or synthetic polymer fibers and at least one suspension fluid, wherein the polymer fibers are substantially evenly dispersed and randomly oriented throughout the volume of the suspension fluid; applying a force, e.g., centrifugal, to said vessel containing said slurry, whereupon said force serves to cause said polymer fibers to migrate through the suspension fluid and amass at a furthest extent of the vessel, forming a polymer material, with said polymer material comprising polymer fibers of sufficient length and sufficiently viscous, interlaced, or interlocked to retard dissociation of said polymer fibers.

The present invention relates to a gelatin having improved properties, in particular improved dispensing properties, more particularly improved printing properties. The present invention further relates to a construct produced with the gelatin of the present invention and to a process to produce said construct. Further the present invention relates to the use of the gelatin of the present invention to solve existing problems encountered with dispensing systems, in particular with 3D printing and more particularly for applications in the medical field. The gelatin of the present invention is particularly suitable for bio-printing in the medical field and may also be used in cosmetic and in food applications.

The present disclosure provides collagen bioink compositions and chemically uncrosslinked and crosslinked collagen structures including collagen microparticles and scaffolds. Also provided are methods of their fabrication and use. Applications for using these collagen structures include treatments of damaged tissue, particularly those caused by osteoarthritis.

Various embodiments are described herein for the fabrication enzyme degradable hydrogels useful as payload delivery systems. More particularly, embodiments disclosed herein relate to enzyme-degradable hydrogel systems comprising a crosslinkable polymer, such as a chemically-modified biopolymer, for example, chemically-modified gelatin, the hydrogel formed by a method comprising sequential physical and chemical crosslinking steps, for delivery of various payloads. Enzymes may be selected and administered to tune the release profile of the hydrogel. The payload can be, but not limited to, drugs, markers, cells, or these members encapsulated within another drug delivery such as a nanoparticle, or liposome. The hydrogel system can also be combined with another device such as a contact lens or bandage for wound healing.

The invention relates to a new protein hydrogel created on the basis of low-concentrated components: reagents A and B, the method of hydrogel preparation and its use.

The invention relates to a new protein hydrogel created on the basis of low-concentrated components: reagents A and B, the method of hydrogel preparation and its use.

Described is a method for the preparation of a gelatin hydrolysate having a decreased endotoxin content, comprising the steps of incubating a solution of gelatin of gelatin hydrolysate at a temperature of 70-125° C. at a pH of 3.5 or less for a time period of at least 15 minutes, and recovering the gelatin hydrolysate. Further a gelatin hydrolysate thus obtained is described.

Provided are biomaterials useful for cell culture, method of preparation thereof, and use thereof. The present biomaterial comprises a crosslinked hydrogel and a peptide chemically attached to the hydrogel, wherein the peptide comprises a histidine-alanine-valine (HAV) sequence. In particular, the present biomaterial may be useful for culturing neurons, brain endothelial cells, and/or glial cells, supporting the formation of synaptically connected neural networks, and growing stem cell-derived organoids that more closely resemble human organs.