An aqueous composition having increased protein stability is obtained by: a. determining a pH at which the protein has stability at the desired temperature; b. adding to the composition at least one displacement buffer wherein the displacement buffer has a pK.sub.a that is at least 1 unit greater or less than the pH of step (a); and c. adjusting the pH of the composition to the pH of step (a); wherein the aqueous composition does not comprise a conventional buffer at a concentration greater than about 2 mM and wherein the conventional buffer has a pK.sub.a that is within 1 unit of the pH of step (a).

An aqueous composition having increased protein stability is obtained by: a. determining a pH at which the protein has stability at the desired temperature; b. adding to the composition at least one displacement buffer wherein the displacement buffer has a pK.sub.a that is at least 1 unit greater or less than the pH of step (a); and c. adjusting the pH of the composition to the pH of step (a); wherein the aqueous composition does not comprise a conventional buffer at a concentration greater than about 2 mM and wherein the conventional buffer has a pK.sub.a that is within 1 unit of the pH of step (a).

Provided are a blood coagulation factor IX fusion protein with a prolonged circulation half-life, a conjugate thereof, a pharmaceutical composition containing same and the use of same in treating hemorrhagic diseases (such as hemophilia B).

Provided are a blood coagulation factor IX fusion protein with a prolonged circulation half-life, a conjugate thereof, a pharmaceutical composition containing same and the use of same in treating hemorrhagic diseases (such as hemophilia B).

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.

Pharmaceutical preparations containing polypeptides having particular sialylation patterns, and methods for the treatment of immune-related thrombocytopenia with such preparations, are described.

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.

A serum albumin variant, or functional fragment thereof, comprising one or more amino acid substitutions selected from (i) glycine, isoleucine, lysine, methionine, phenylalanine, tryptophan, tyrosine, valine and leucine substituted for glutamine at position (522); (ii) valine substituted for alanine at position (552); and (iii) alanine, glutamic acid, histidine, serine, lysine and arginine substituted for glycine at position (572).

An example medical device includes a vascular device, such as a catheter, and an anti-thrombogenic coating on a surface of the vascular device, such as a surface likely to contact blood. The anti-thrombogenic coating includes one or more peptides configured to interact with fibrinogen in the blood, such as a first type of peptides configured to bind to fibrinogen a second type of peptides configured to inhibit conversion of fibrinogen to fibrin. The anti-thrombogenic coating also includes a polymer, such as a hydrocolloid polymer, a tunable polyethylene glycol (PEG), or other controlled release polymer configured to control release of the one or more peptides and maintain a concentration of the peptides at the surface of the anti-thrombogenic coating above a minimum inhibitory concentration, thereby inhibiting thrombin formation on the intravascular medical device.

Nucleic acid constructs and compositions that allow insertion of a FIX coding sequence into a target genomic locus such as an endogenous ALB locus and/or expression of the FIX coding sequence are provided. The nucleic acid constructs and compositions can be used in methods of introducing a F9 nucleic acid into a cell, methods of integration of a F9 nucleic acid into a target genomic locus, methods of expression of FIX in a cell, and in methods of treating hemophilia B or FIX deficiency in a subject.