The present invention relates to a composition for hemostasis which contains collagen, stabilizer, and thrombin, and a container including the same. The present invention is applicable to a bleeding patient requiring emergency treatment with a simple method of use. There is no toxicity and no problem of blood infection. A biodegradation rate is fast. In this regard, the present invention achieves an excellent hemostatic effect. Therefore, the composition for hemostasis is useful as a hemostat.

Biomaterials for tissue regeneration and engineering applications and methods of making and use thereof are described, as well as constructs and kits derived from the biomaterials. The biomaterials can be derived from extracellular matrix and functionalized to make them crosslinkable and amenable to tuning of their material properties.

Embodiments of the present invention provide a method of treating a stricture in a nonvascular body lumen such as urethral strictures, benign prostatic hyperplasia (BPH) strictures, ureteral strictures, esophageal strictures, sinus strictures, and biliary tract strictures. Embodiments of the present invention provide a method for treating at least one of benign prostatic hyperplasia (BPH), prostate cancer, asthma, and chronic obstructive pulmonary disease (COPD). The method can include delivering, for example, via drug coated balloon catheters, anti-inflammatory and anti-proliferative drugs (e.g., rapamycin, paclitaxel, and their analogues) and one or more additives.

The present disclosure is directed to a class of fluorinated copolymers, such as PTFE copolymers, that can be dissolved in low toxicity solvents, such as Class III Solvents, and that enable the creation of stable water-in-solvent emulsions comprising the fluorinated copolymers dissolved in a low toxicity solvents and a hydrophilic agent (e.g., a therapeutic agent) dissolved in an aqueous solvent, such as water or saline.

A method for treating proliferative diseases by delivering a combination of at least two pharmaceutically active agents to a diseased area or tissue comprising a coating layer of two hydrophobic drugs applied to an exterior surface of a device or a substrate wherein the first pharmaceutically active agent is selected from a group consisting of mTor inhibitors and the second pharmaceutically active agent is selected from a group of consisting of NF-kβ inhibitors. Further a method for treating proliferative diseases by delivering a combination of at least two pharmaceutically active agents to a diseased area or tissue comprising: a coating layer of two hydrophobic drugs applied to an exterior surface of a medical device or substrate and a polymer blend carrier for the pharmaceutically active agents.

Disclosed embodiments relate to a wound dressing which can generate nitric oxide. The wound dressing may include a cover layer, an activator layer such as an acid providing layer and nitric oxide source layer, such as a nitrite providing layer. The activator layer may include acidic groups and may be hydrogel, xerogel, or other suitable material. The activator layer may include a copolymer of monomers with one or more covalently linked multifunctional groups.

Disclosed are absorbent articles having a cyclodextrin complex of one or more odor controlling organic compounds wherein the cyclodextrin is a substituted cyclodextrin (wherein the H atom of OH groups in positions 2, 3 and 6 is partially or entirely replaced by a substituent —R) having a substitution degree (DS) of 0.4 or more —R substituents per molecule of cyclodextrin and wherein substitution in position 2 is 20% or above, in position 6 is 20% or above and in position 3 is 50% or below. Cyclodextrin complexes of this type release the odor controlling organic compound much faster and in more complete manner than non-substituted or differently substituted cyclodextrin complexes thus the odor control efficacy is improved.

A skin-substitute is constructed by homogenizing an acellular dermal tissue matrix into a slurry, pouring the slurry into a mold, and lyophilizing the slurry.

The present invention relates to nanoparticles comprising nucleic acids coated with a (biodegradable) polymer for reversible immobilization and/or controlled release of the nucleic acid comprising nanoparticles. Furthermore, the present invention is directed to medical or diagnostic devices, particularly stents and implants coated by a (biodegradable) polymer with the nucleic acid comprising nanoparticles for reversible immobilization and/or controlled release. Furthermore, the present invention is directed to the use of these nanoparticles coated with a (biodegradable) polymer and to the use of medical devices and implants coated by the (biodegradable) polymer with these nucleic acid comprising nanoparticles in the prophylactic or therapeutic treatment of diseases, particularly in the prevention or treatment of restenosis, calicification, foreign body reaction, or inflammation. Additionally, the present invention is directed to a method of preparing these nucleic acid comprising nanoparticles coated with a (biodegradable) polymer and to a method for coating nucleic acid comprising nanoparticles by a (biodegradable) polymer on medical or diagnostic devices.

The methods and compositions disclosed herein are effective in the promoting the reattachment of delaminated cartilage to bone. The methods (and related compositions) comprise the removal of the acellular layer of the delaminated cartilage thereby exposing the underlying chondrocyte cells thereby allowing the promotion of the reattachment of the delaminated cartilage.