A method for manufacturing a hollow particle is provided. The method comprises the steps of (a) providing a hollow particulate; (b) soaking the hollow particulate in an amine solution to form amine groups on the surface of the hollow particulate; (c) adding a polypeptide, and the polypeptide is linked to the amine groups on the surface of the hollow particulate; and (d) adding a target molecule, and the target molecule is bound to the amine group which are still not bound.

The present invention provides a microneedle device comprising: a substrate; a microneedle disposed on the substrate; and a coating layer formed on the microneedle; wherein the coating layer comprises a physiologically active substance, arginine, and glycerin.

Osteoconductive synthetic bone grafts are provided in which porous ceramic granules are embedded in a biocompatible matrix material. The grafts, which may also include one or more of a coating, a reinforcing bio-absorbable mesh, and an osteoinductive protein or peptide, are generally porous and may incorporate fenestrations.

The presently disclosed subject matter provides hydrogel precursor compositions (e.g., solutions) for forming three-dimensional hydrogels that support growth of physiologically relevant tissue when at least one cell is cultured in the three-dimensional hydrogel, kits comprising the hydrogel precursor composition, three-dimensional hydrogels, methods of forming the three-dimensional hydrogels, methods of growing the physiologically relevant tissue using the three-dimensional hydrogels, physiologically relevant tissue grown in the three-dimensional hydrogels, methods of producing hormone-responsive tissue (e.g., milk-producing mammary tissue and related methods of producing milk), methods of screening for candidate agents useful for modulating hormonal responses (e.g., modulating milk production), method of screening for candidate therapeutic agents using the physiologically relevant tissue grown in the three-dimensional hydrogels (e.g., personalized cancer treatments), and related methods of treatment (e.g., administering agents identified using the methods herein, transplanting physiologically relevant tissue produced using the methods, etc.).

Haemostatic wound dressings are described. The dressings comprise a non-colloidal porous dressing material, and a plurality of fibrinogen-binding peptides immobilised to the non-colloidal porous dressing material, wherein each fibrinogen-binding peptide comprises: an amino acid sequence Gly-Pro-Arg-Xaa (SEQ ID NO: 1) at an amino-terminal end of the peptide, wherein Xaa is any amino acid other than Val, preferably Pro, Sar, or Leu; or an amino acid sequence Gly-His-Arg-Xaa (SEQ ID NO: 2) at an amino-terminal end of the peptide, wherein Xaa is any amino acid other than Pro. The dressings are able to accelerate haemostasis without requiring enzymatic activity. In particular, the dressings to do not rely on the action of exogenous thrombin, and can be stored long-term at room temperature in solution. Methods of making the dressings, and use of the dressings to control bleeding are also described.

The present invention relates to methods for encapsulating pancreatic progenitors in a biocompatible semi-permeable encapsulating device. The present invention also relates to production of human insulin in a mammal in response to glucose stimulation.

A device for use in the repair of an ear drum in a subject in need of such treatment, said device: having a tensile strength Youngs Modulus between approximately 12.5 and 40 MPa; comprising one or more membrane layers, wherein at least one membrane layer comprises a plurality of pores; and wherein the device can support proliferation, migration and/or adhesion of cells selected from the group comprising at least any one or more of: keratinocytes, fibroblasts, vascular cells, mucosal epithelial cells, and stem cells.

A biocompatible structure includes one or more base structures for regeneration of different tissues. Each base structure includes alternately stacked polymer layers and spacer layers. The polymer layer includes a polymer and tissue forming nanoparticles. The polymer includes polyurethane. The tissue forming nanoparticles includes hydroxypatites (HAP) nanoparticles, polymeric nanoparticles, or nanofibers. The spacer layer includes bone particles, polymeric nanoparticles, or nanofibers. The weight percentage of tissue forming nanoparticles to the polymer in the polymer layer in one base structure is different from that in the other base structures. A method of producing the biocompatible structure includes forming multiple base structures stacked together, coating the stacked multiple base structures, and plasma treating the coated structure.

The present invention concerns a process for the production of implants with an ultrahydrophilic surface as well as the implants produced in that way and also processes for the production of loaded, so-called bioactive implant surfaces of metallic or ceramic materials, which are used for implants such as artificial bones, joints, dental implants or also very small implants, for example what are referred to as stents, as well as implants which are further produced in accordance with the processes and which as so-called “delivery devices” allow controlled liberation, for example by way of dissociation, of the bioactive molecules from the implant materials.

The invention provides compositions featuring chitosan and polyethylene glycol and methods for using such compositions for the local delivery of biologically active agents to an open fracture, complex wound or other site of infection. Advantageously, the chitosan-PEG compositions can be loaded with one or more antimicrobial agents, including hydrophobic agents, and can be tailored to the needs of particular patients at the point of care (e.g., in a surgical suite, clinic, physician's office, or other clinical setting).