The present invention relates to compositions and methods useful for treating structures of the vertebral column, including vertebral bodies. In one embodiment, a method for promoting bone formation in a vertebral body comprising providing a composition comprising a PDGF solution and a biocompatible matrix and applying the composition to at least one vertebral body. Promoting bone formation in a vertebral body, according to some embodiments, can increase bone volume, mass, and/or density leading to an increase in mechanical strength of the vertebral body treated with a composition of the present invention.

Methods of delivering therapeutic agents by administering compositions including a bacterial collagen-binding polypeptide segment linked to the therapeutic agent to subjects in need of treatment with the therapeutic agent are provided. In these methods, the therapeutic agent is not a PTH/PTHrP receptor agonist or antagonist, basic fibroblast growth factor (bFGF) or epidermal growth factor (EGF). The bacterial collagen-binding polypeptide segment delivers the agent to sites of partially untwisted or under-twisted collagen. Methods of treating collagenopathies using a composition including a collagen-binding polypeptide and a PTH/PTHrP receptor agonist are also provided. In addition, methods of treating hyperparathyroidism, and hair loss using compositions comprising a collagen binding polypeptide and a PTH/PTHrP receptor agonist are provided. Finally, methods of reducing hair regrowth by administering a composition including a collagen binding polypeptide and a PTH/PTHrP receptor antagonist are provided.

Provided herein are new compositions and methods to target pharmaceutical agents to pathological areas by utilizing bifunctional fusion polymers or nanoparticles. These fusion polymers and nanoparticles contain two or more domains: (i) sequences that bind to exposed collagenous (XC-) proteins present in pathological areas, including cancerous lesions and (ii) domains that bind to pharmaceutical agents. The drug-binding functionality of these fusion polymers and nanoparticles is based on high-affinity, non-covalent interactions.

Provided herein are new compositions and methods to target pharmaceutical agents to pathological areas by utilizing bifunctional fusion polymers or nanoparticles. These fusion polymers and nanoparticles contain two or more domains: (i) sequences that bind to exposed collagenous (XC-) proteins present in pathological areas, including cancerous lesions and (ii) domains that bind to pharmaceutical agents. The drug-binding functionality of these fusion polymers and nanoparticles is based on high-affinity, non-covalent interactions.

Novel proteins and compounds conjugated with polysialic acid (PSA) are provided herein. Also provided are methods of using these compounds and methods of treatment of various diseases and disorders. The novel compounds provided herein have improved pharmacodynamic and/or pharmacokinetic properties, improved effectiveness, and other desirable properties.

The invention relates to inhalable imatinib formulations, manufacture, and uses thereof.

A method for promoting growth of bone, periodontium, ligament, or cartilage in a mammal by applying to the bone, periodontium, ligament, or cartilage a composition comprising platelet-derived growth factor at a concentration in the range of about 0.1 mg/mL to about 1.0 mg/mL in a pharmaceutically acceptable liquid carrier and a pharmaceutically-acceptable solid carrier.

This invention discloses a method for stabilizing bioactivity of a growth factor, including mixing collagen with a growth factor and freeze drying the mixture to remove water. After this treatment, the bioactivity of the growth factor at room temperature remains stable for at least 7 days.

A biological scaffold in the present invention comprises a main body, a biological material layer, and an optional tissue adhesive layer. The main body at least has a non-constituted collagen matrix. The biological material layer is coated at least on a surface of the main body, and the tissue adhesive layer is disposed at least on another surface of the main body. When the biological scaffold is adhered to a tissue through the tissue adhesive layer, a plurality of cells move from the tissue to either the adhesive layer or the biological material layer for tissue repairing or regeneration.

The present application provides methods and processes for making and using a fibronectin composition, as well as methods for treating ocular conditions and/or disorders with the cellular fibronectin composition described herein.