The present invention provides a method for preparing an injectable thermosensitive chitosan/TEMPO-oxidized cellulose nanofibers hydrogel. The injectable thermosensitive chitosan/TEMPO-oxidized cellulose nanofibers hydrogel exhibits superior biocompatibility through addition of TEMPO-oxidized cellulose nanofibers, and excellent cell proliferation and bone regeneration through cellular interaction, and is gelled in vivo, thus being highly useful as a filler for wound healing and bone regeneration. In addition, the injectable thermosensitive chitosan/TEMPO-oxidized cellulose nanofibers hydrogel exhibits excellent porosity, has an interconnected structure and is thermogelling, based on thermosensitivity of undergoing a sol-gel transition depending on temperature, thus inducing rapid gelation in vivo and facilitating bone regeneration upon implantation in vivo.

Provided is a compression resistant implant configured to fit at or near a bone defect to promote bone growth. The compression resistant implant comprises a biodegradable polymer in an amount of about 0.1 wt % to about 20 wt % of the implant and a freeze-dried oxysterol in an amount of about 5 wt % to about 90 wt % of the implant. Methods of making and use are further provided.

An implantable device comprising a substrate capable of capturing an intraocular target molecule and to methods of use thereof. The substrate may be capable of capturing a target molecule present in the eye and/or from fluid of the eye (e.g., an intraocular target molecule). In some embodiments, the substrate has a relatively high affinity for a target molecule.

Drug-eluting devices and methods for the treatment of tumors of the pancreas, biliary system, gallbladder, liver, small bowel, or colon, are provided. Methods include deploying a drug-eluting device having a film which includes a mixture of a degradable polymer and a chemotherapeutic drug, wherein the film has a thickness from about 2 μm to about 1000 μm, into a tissue site and releasing a therapeutically effective amount of the chemotherapeutic drug from the film to treat the tumor, wherein the release of the therapeutically effective amount of the drug from the film is controlled by in vivo degradation of the polymer at the tissue site.

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.

Bacteria-responsive core-shell nanofibers and a process for the preparation thereof are described. The nanofibers release of an antibacterial agent in response to the presence of bacteria. The core of the nanofiber comprises a biocompatible polymer together with an antibacterial agent such as a quaternary ammonium compound, for example benzyl dimethyl tetradecyl ammonium chloride (BTAC). Surrounding the core is shell comprised of a bacterially degradable polymer, which is susceptible to break-down by bacterial enzymes such as lipase, or to acidic pH conditions. The shell may comprise, for example, polycaprolactone (PCL) and poly(ethylene succinate) (PES). The nanofibers may be incorporated into wound dressings.

A biological composition intermixed with a polyampholyte protectant for direct implantation has a mixture of biologic material and a volume of polyampholyte protectant. The mixture of biologic material has non-whole cellular components including vesicular components and active and inactive components of biological activity, cell fragments, cellular excretions, cellular derivatives, and extracellular components, or whole cells or combinations of the non-whole cellular components and whole cells, wherein the mixture is compatible with biologic function. The volume of polyampholyte protectant is intermixed with the mixture of biologic material, wherein the polyampholyte protectant is a liquid of a polyamine polymer compound of carboxylated poly-lysine and wherein the polyampholyte protectant forms a three-dimensional bonding shroud externally enveloping each of the non-whole cellular components, if any, and each of the whole cells, if any, of the mixture of biologic material.

Provided herein are bio-absorbable, settable and homogenous multi-putty bone-adhesive compositions for medical use in tissue hemostasis, surgical repair and reconstruction. Also provided are improved methods of intraoperative use of said compositions for re-approximation of adjacent bone fragments to create a restored alignment and stabilize fracture line.

A soft tissue device can incorporate a composite material comprising a gel and at least one nanostructure disposed within the gel. A soft tissue device can further incorporate biologically active materials such as cells, tissues. A method for healing a soft tissue defect while promoting soft tissue regeneration can include applying a soft tissue device to a soft tissue defect, wherein the composite material includes a gel and a nanostructure disposed within the gel. A method for manufacturing a soft tissue device for use in healing soft tissue defects can include providing a gel, disposing nanofibers within the gel, and a biologically active material.

A method of forming a microneedle array can include forming a sheet of material having a plurality of layers and micromilling the sheet of material to form a microneedle array. At least one of the plurality of layers can include a bioactive component, and the microneedle array can include a base portion and plurality of microneedles extending from the base portion.