Disclosed is absorbable bone wax and a preparation method thereof. The preparation method comprises the steps of: 1) mixing polyoxypropylene polyoxyethylene block copolymer (PEG-PPG-PEG) and polyoxypropylene polyoxyethylene random copolymer (PEG-PPG), and stirring evenly under heating to obtain a liquid mixture; 2) under mechanical stirring and heating condition, adding hemostatic starch microspheres to the liquid mixture obtained in step 1) to obtain a uniformly-mixed liquid; and 3) adding a bone repair material to the uniformly-mixed liquid obtained in step 2), and mixing uniformly to obtain a mixed solution, then pouring the mixed solution into a mold or sub-packaged bottle, and leaving at room temperature for solidifying and shaping to give the absorbable bone wax. The absorbable bone wax of the present invention can achieve the effect of rapid hemostasis, changing the relatively single hemostasis method with traditional bone wax which only depends on physical sealing.

A method of sealing a resected surface of an organ includes applying a synthetic matrix to a resected surface of an organ, and applying an adhesive on the synthetic matrix so that the adhesive penetrates through interstices of the synthetic matrix for contacting an interface between the synthetic matrix and the resected surface of the organ. The method includes curing the adhesive for bonding the synthetic matrix to the resected surface of the organ. The synthetic matrix is a non-woven mesh made of polyglactin 910 or any other synthetic or non-synthetic fabric having a similar porosity or density. The adhesive is a biosynthetic or a synthetic adhesive. After penetrating through the pores of the synthetic matrix and curing, the cured biosynthetic or synthetic adhesive mechanically interlocks with the synthetic matrix for adhering the synthetic matrix to the tissue for creating a sealing barrier.

Compositions and methods for sealing tissue of a patient in a wet environment are disclosed.

A hemostatic device for promoting the clotting of blood includes a gauze substrate, a clay material disposed on the gauze substrate, and also a polyol such as glycerol or the like disposed on the gauze substrate to bind the clay material. When the device is used to treat a bleeding wound, at least a portion of the clay material comes into contact with blood emanating from the wound to cause the clotting. A bandage that can be applied to a bleeding wound to promote the clotting of blood includes a flexible substrate and a gauze substrate mounted thereon. The gauze substrate includes a clay material and a polyol. A hemostatic sponge also includes a gauze substrate and a dispersion of hemostatic material and a polyol on a first surface of the substrate.

Disclosed are solid and frozen haemostatic materials having a rod shape and suitable applicators and plungers for application of such dressings to wounded tissue wherein said dressings consisting essentially of a fibrinogen component and a fibrinogen activator. Also disclosed are methods of treating internal wounded tissue in a mammal by applying one or more of these haemostatic materials and dressings, particularly for the treatment of injured tissue via endoscopic or minimally-invasive surgical techniques.

Provided are pharmaceutical foam compositions comprising a peptone, a peptide hydrolysate or an enzymatically-hydrolyzed protein prepared by enzymatic hydrolysis of a full-length protein; methods of preparation and uses thereof.

Spray-dried thrombin materials obtained from feedstock solutions comprising less than 5% by weight albumin and excluding trehalose or other excipients as well as methods of manufacturing the thrombin materials and methods of treating bleeding wounds are disclosed. The methods of use include applying reconstituted spray-dried thrombin topically to a bleeding site, optionally in conjunction with gelatin.

The present invention is directed to an absorbable hemostatic patch that utilizes a biocompatible fibrous, fabric substrate that is melt-blown and napped or loosened at the surface, with the substrate having a low-profile, high flexibility, strength and porosity that is suitable for coating cross-linkable active molecules and ultimately effective for use as a hemostat in situations of problematic bleeding.

Disclosed are a medical fiberous structure and a method for preparing the same, wherein the medical fiberous structure comprises calcium carboxymethyl cellulose and a chitosan compound, at least one of the calcium carboxymethyl cellulose and the chitosan compound having a fibrous shape.

A kit includes a mesh substrate and a polymer that is fixed to the mesh substrate. The polymer includes an active agent that is configured to elute over time. The kit further includes a hemostatic agent. The hemostatic agent is separate from the mesh substrate and the polymer. Systems and methods are disclosed.