Disclosed herein are bionanoparticles of adipose-derived stem cell extracellular vesicles, a tissue repair matrix comprising the bionanoparticles, and methods of use thereof for enhanced tendon healing.

One embodiment of the present invention is directed to compositions and methods for enhancing attachment of soft tissues to a metal prosthetic device. In one embodiment a construct is provided comprising a metal implant having a porous metal region, wherein said porous region exhibits a nano-textured surface.

In one aspect, compositions and wound dressings are described herein. In some embodiments, a composition or wound dressing described herein comprises a mesh formed from a plurality of biodegradable polymer fibers; a first active agent dispersed in the biodegradable polymer fibers; a plurality of biodegradable polymer particles disposed in the mesh; and a second active agent dispersed in the biodegradable polymer particles. The particles can be disposed within the interiors of the fibers of the mesh or between the fibers of the mesh. In another aspect, a composition or wound dressing described herein comprises a first perforated mesh formed from a first plurality of biodegradable polymer fibers; and a second perforated mesh formed from a second plurality of biodegradable polymer fibers, wherein the second perforated mesh is disposed on the first perforated mesh in a stacked configuration and the first and second perforated meshes have different degrees of perforation.

The present invention relates to a nanocomposite ocular device that can release drugs within a close distance to the ocular surface and provide controlled and sustained release of the drug at a constant rate. The device can achieve both optical and medical functions. The device comprises a drug, one or more reservoir domains, and a barrier layer configured to block the drug diffusion paths from the reservoir domain to the ocular surface in the eye of the subject, wherein the drug partitions between the reservoir domain and the barrier layer, and the equilibrium drug solubility in the reservoir domain is at least five folds higher than that in the barrier layer.

The present invention relates to a stable self-assembling graphene oxide-protein matrix comprising a disordered protein (DP) and graphene oxide (GO), wherein the DP has an opposite charge to the GO, further wherein the graphene oxide-protein matrix is in the form of a 3D structure having a lumen defined by a membrane having an inner and outer surface. The invention further relates to methods and kits for preparing such a graphene oxide-protein matrix and its uses.

Described are fibrous materials comprising a plurality of fibers having a longitudinal alignment gradient and/or a longitudinal composition gradient. Also described are methods of preparing the fibrous materials thereof and methods of treating organ or tissue damage with the fibrous materials.

In one aspect, compositions and wound dressings are described herein. In some embodiments, a composition or wound dressing described herein comprises a mesh formed from a plurality of biodegradable polymer fibers; a first active agent dispersed in the biodegradable polymer fibers; a plurality of biodegradable polymer particles disposed in the mesh; and a second active agent dispersed in the biodegradable polymer particles. The particles can be disposed within the interiors of the fibers of the mesh or between the fibers of the mesh. In another aspect, a composition or wound dressing described herein comprises a first perforated mesh formed from a first plurality of biodegradable polymer fibers; and a second perforated mesh formed from a second plurality of biodegradable polymer fibers, wherein the second perforated mesh is disposed on the first perforated mesh in a stacked configuration and the first and second perforated meshes have different degrees of perforation.

Disclosed herein is a micro particle with a diameter of 10-100 microns, wherein the micro particle is coated with silver nanoparticles; and wherein the nanoparticles are coated with a polysaccharide; and wherein the polysaccharide coating is digestible by bacteria. Also, disclosed is a method of making silver nanoparticles using an ascorbic acid derivative or an alpha-hydroxyl carboxylic acid derivative as a reducing agent. The silver nanoparticles may be coated onto micro particles, embedded in hydrogel particles or coated with polysaccharide. The silver nanoparticles may be used in a wound dressing, a bandage, a fungal treatment product, a deodorant, a floss product, a toothpick, a dietary supplement, dental X-ray, a mouthwash, a toothpaste, acne or wound treatment product, skin scrub, and skin defoliate agent.

Disclosed are nucleic acid-calcium phosphate nanoparticle complexes and application thereof in biomineralization. Specifically, disclosed are a biological mineralizer and a preparation method thereof. The mineralizer contains a complex formed by nucleic acid and amorphous calcium phosphate nanoparticles. Further, disclosed is a collagen fiber product containing the biological mineralizer or treated with the biological mineralizer, such as a medical device for being implanted into a patient. Further, disclosed is use of the biological mineralizer or the collagen fiber product in treatment of bone-associated diseases or disorders or improvement of bone conditions of patients. Further, disclosed is a method of using the biological mineralizer to induce biomimetic mineralization of collagen fibers or a preparation method of a mineralized collagen fiber product.

Embodiments described herein relate to restorative solutions for segmental peripheral nerve (PN) defects using allografted PNs for stimulating PN repair. More specifically, embodiments described herein provide for localized immunosuppression (LIS) surrounding PN allografts as an alternative to systemically suppressing a patient's entire immune system. Methods include localized release of immunosuppressive (ISV) agents are contemplated in one embodiment. Methods also include localized application of immunosuppressive (ISV) regulatory T-cells (Tregs) and/or mesenchymal stomal cells in other embodiments. Hydrogel carrier materials are also described herein.