Abstract: The invention relates to methods for fabricating a flowable hemostatic composition. The invention also relates to hemostatic compositions and methods for promoting wound healing. In various embodiments, the hemostatic compositions comprise crosslinkable collagen molecules having a porosity controlled by the ratio of weight percent collagen solids to weight percent crosslinker when crosslinking the collagen. In other embodiments, the hemostatic compositions comprise crosslinkable collagen molecules having a porosity controlled by the temperature and rate of freezing when drying the composition during fabrication. In some embodiments, the compositions contain additional agents, including biological agents.

Abstract: The invention relates to hemostatic compositions and methods for promoting hemostasis. The invention also relates to hemostatic compositions and methods for promoting wound healing. In various embodiments, the hemostatic compositions comprise crosslinkable collagen molecules having a porosity controlled by the ratio of weight percent collagen solids to weight percent crosslinker when crosslinking the collagen. In other embodiments, the hemostatic compositions comprise crosslinkable collagen molecules having a porosity controlled by the temperature and rate of freezing when drying the composition during fabrication. In some embodiments, the compositions contain additional agents, including biological agents.

Abstract: Methods for constructing tyrosine-derived biotinylated polymers. Biotinylated polymers and polymer scaffolds constructed with the biotinylated polymers are also disclosed.

Abstract: Described herein are materials and methods for reducing the risk of infection at a surgical site performed to restore or repair bone in an animal. Bone graft materials for implantation into a mammal are contemplated containing an antimicrobial agent. In one embodiment the bone graft material comprises both calcium phosphate and povidone-iodine as the antimicrobial agent. In another embodiment the bone graft material further comprises collagen. The bone graft materials are designed so as to maintain the structural integrity and/or handling characteristics of the material upon implantation into a bony site. Various methods for manufacturing the bone graft materials described herein are also contemplated.

Abstract: Methods and compositions are provided for improving tissue growth and device integration in vivo. Substrates and devices coated with an ?2?1 or ?5?1 integrin-specific ligand are provided. The substrates and devices coated with an ?2?1 or ?5?1 integrin-specific ligand are shown to have greater tissue formation on the surface relative to controls, in particular greater bone formation.

Abstract: The invention relates to hemostatic compositions and methods for promoting hemostasis. The invention also relates to hemostatic compositions and methods for promoting wound healing. In various embodiments, the hemostatic compositions comprise crosslinkable collagen molecules having a porosity controlled by the ratio of weight percent collagen solids to weight percent crosslinker when crosslinking the collagen. In other embodiments, the hemostatic compositions comprise crosslinkable collagen molecules having a porosity controlled by the temperature and rate of freezing when drying the composition during fabrication. In some embodiments, the compositions contain additional agents, including biological agents.

Abstract: Methods for constructing tyrosine-derived biotinylated polymers. Biotinylated polymers and polymer scaffolds constructed with the biotinylated polymers are also disclosed.

Abstract: Methods and compositions are provided for improving tissue growth and device integration in vivo. Substrates and devices coated with an ?2?1 or ?5?1 integrin-specific ligand are provided. The substrates and devices coated with an ?2?1 or ?5?1 integrin-specific ligand are shown to have greater tissue formation on the surface relative to controls, in particular greater bone formation.

Abstract: Methods and compositions are provided for improving tissue growth and device integration in vivo. Substrates and devices coated with an ?2?1 or ?5?1 integrin-specific ligand are provided. The substrates and devices coated with an ?2?1 or ?5?1 integrin-specific ligand are shown to have greater tissue formation on the surface relative to controls, in particular greater bone formation.

Abstract: Methods and compositions are provided for improving tissue growth and device integration in vivo. Substrates and devices coated with an ?2?1 or ?5?1 integrin-specific ligand are provided. The substrates and devices coated with an ?2?1 or ?5?1 integrin-specific ligand are shown to have greater tissue formation on the surface relative to controls, in particular greater bone formation.