Disclosed herein is an anti-adhesion kit comprised of: (i) a fibrinogen solution component comprising: fibrinogen at a concentration of about 5 to 25 mg/ml; and free calcium ions at a concentration ranging from 0.1 μM to 1 mM; and (ii) a thrombin component containing thrombin. Further disclosed is an anti-adhesion kit comprised of: (i) a fibrinogen solution component containing fibrinogen at a concentration of 8% to 25% of total protein by weight, and optionally free calcium ions at a concentration ranging from 0.1 μM to 1 mM; wherein a total protein concentration ranges from about 80 to 120 mg/ml; and (ii) a thrombin component containing thrombin. Methods of using the kits e.g., to provide anti-adhesion curable compositions are also disclosed.

Implantable scaffolds that treat solid tumors and escape variants and that provide effective vaccinations against cancer recurrence are described. The scaffolds include genetically-reprogrammed lymphocytes and a lymphocyte-activating moiety.

A method of production of a tissue sealing patch is disclosed. The method comprises applying a vacuum to a heated work surface; applying a solution of a biocompatible polyurethane polymer to the work surface and spreading it over the work surface with a polymer blade; evaporating the solvent; heating the work surface above the softening temperature of the polymer; spreading powdered tissue sealant material over the polymer film; incorporating the tissue sealant material to a depth of 20-60 μm in the film by pressing on a release sheet placed over the powder and polymer film; removing the release sheet from the adhesive patch material; releasing the vacuum; cooling said work surface; and removing the adhesive patch material from said work surface. The biocompatible polymer preferably comprises PEG-caprolactone-lactic acid units connected by urethane linkages, the PEG having a molecular weight of 3000-3500 amu, and a CL:LA:PEG ratio of 34:2:1.

An implantable medical device includes a polymer substrate and at least one nanofiber. The polymer substrate includes a surface portion extending into the polymer substrate from a surface of the substrate. The at least one nanofiber includes a first portion and a second portion. The first portion is interpenetrated with the surface portion of the substrate, and mechanically fixed to the substrate. The second portion projects from the surface of the substrate.

An implantable medical device includes a polymer substrate and at least one nanofiber. The polymer substrate includes a surface portion extending into the polymer substrate from a surface of the substrate. The at least one nanofiber includes a first portion and a second portion. The first portion is interpenetrated with the surface portion of the substrate, and mechanically fixed to the substrate. The second portion projects from the surface of the substrate.

Disclosed herein is an anti-adhesion kit comprised of: (i) a fibrinogen solution component comprising: fibrinogen at a concentration of about 5 to 25 mg/ml; and free calcium ions at a concentration ranging from 0.1 μM to 1 mM; and (ii) a thrombin component containing thrombin. Further disclosed is an anti-adhesion kit comprised of: (i) a fibrinogen solution component containing fibrinogen at a concentration of 8% to 25% of total protein by weight, and optionally free calcium ions at a concentration ranging from 0.1 μM to 1 mM; wherein a total protein concentration ranges from about 80 to 120 mg/ml; and (ii) a thrombin component containing thrombin. Methods of using the kits e.g., to provide anti-adhesion curable compositions are also disclosed.

An embodiment includes a vascular port comprising: first and second portions that are not monolithic with each other; wherein: (a)(i) the first portion includes a first arcuate surface to contour to a first portion of a vessel and the second portion includes a second arcuate surface to contour to a second portion of the vessel; (a)(ii) the first and second portions couple to one another around the vessel when implanted to form a central chamber that houses the vessel; (a)(iii) the first portion includes a port that includes a funnel with a funnel surface that narrows as the funnel surface approaches the central chamber; (a)(iv) the central chamber includes a central longitudinal axis and the funnel includes a central vertical axis that is orthogonal to the longitudinal axis; (a)(v) the second portion includes a hardened, non-compliant surface that intersects the vertical axis.

A method and kit for stopping cerebrospinal fluid (CSF) leaks, comprising penetrating and passing through a dural tissue an applicator to access an interior dural space, injecting from the applicator a fibrinogen-containing solution into said dural space, applying a sealing member containing a fibrinogen polymerizing agent onto an exterior surface of the dural tissue, and forming a polymerized fibrinogen or polymerized fibrin clot by contacting the injected fibrinogen-containing solution and the fibrinogen polymerizing agent.

The invention provides a wound dressing made by an ex vivo formed combination of fibrinogen and/or fibrin containing-liquid formulation and an oxidized cellulose (OC) backing; and use thereof.

A fibrinogen preparation is provided which has an improved solubility, may be prepared within a short time and may be used rapidly in clinical set-up. A solid fibrinogen preparation comprising as a main ingredient fibrinogen and further containing the following components: albumin; a nonionic surfactant; a basic amino acid or a salt thereof; and at least two amino acids or a salt thereof selected from an acidic amino acid or a salt thereof and a neutral amino acid or a salt thereof. The solid fibrinogen composition of the present invention may be held on a medical material to form a supporting material holding fibrinogen. Besides, the supporting material holding fibrinogen may be combined with a component comprising as a main ingredient thrombin to provide a fibrin adhesive.