The present invention provides a valve material having synergistic anti-coagulation and anti-calcification functions and a preparation method therefor. The preparation method comprises the following steps: performing glutaraldehyde cross-linking treatment on an animal-derived biological valve material; immersing the treated valve material in a blocking solution containing an amine compound for 0.5-6 h, thereby blocking the remaining aldehyde groups after glutaraldehyde cross-linking; then placing the valve material into a reaction solution containing an anticoagulant and a cross-linking agent, and performing cross-linking treatment for 6-24 h at 4° C.-37° C.; and finally washing and obtaining the valve material, and storing the valve material in a mixed solvent of glutaraldehyde or isopropyl alcohol/glycerol. The method can effectively solve the problem of calcification and thrombosis caused by residual aldehyde groups in a valve material prepared by the existing method. The valve material prepared by the present method can be used as a valve material required for aortic valve, pulmonary valve, venous valve, mitral valve and tricuspid valve replacement.

The present invention provides a valve material having synergistic anti-coagulation and anti-calcification functions and a preparation method therefor. The preparation method comprises the following steps: performing glutaraldehyde cross-linking treatment on an animal-derived biological valve material; immersing the treated valve material in a blocking solution containing an amine compound for 0.5-6 h, thereby blocking the remaining aldehyde groups after glutaraldehyde cross-linking; then placing the valve material into a reaction solution containing an anticoagulant and a cross-linking agent, and performing cross-linking treatment for 6-24 h at 4° C.-37° C.; and finally washing and obtaining the valve material, and storing the valve material in a mixed solvent of glutaraldehyde or isopropyl alcohol/glycerol. The method can effectively solve the problem of calcification and thrombosis caused by residual aldehyde groups in a valve material prepared by the existing method. The valve material prepared by the present method can be used as a valve material required for aortic valve, pulmonary valve, venous valve, mitral valve and tricuspid valve replacement.

This disclosure provides a method for improving maturation of an arteriovenous fistula (AVF) in a patient in need of hemodialysis, which method entails applying a solution to the internal wall of a lumen of an AVF; and restoring or initiating blood flow in the AVF, wherein the solution comprises an effective amount of a synthetic proteoglycan comprises a glycan having from about 1 to about 80 collagen-binding peptide(s) bonded to the glycan. Also provided are methods for preparing a vascular graft for a bypass surgery, comprising contacting the internal wall of a section of a blood vessel with a solution comprising an effective amount of the synthetic proteoglycan.

The present invention relates to novel compositions and methods for reducing or eliminating the thrombogenicity of a graft by modifying the graft with a cell-derived extracellular matrix lacking thrombospondin-2 (TSP2-null ECM) to render it non-thrombogenic when transplanted to a subject in need thereof. The invention also provides a method for improving the biocompatibility of a medical device or an implant by modifying the medical device or implant with a cell-derived TSP2-null ECM, whereby the medical device or implant is rendered non-thrombogenic and pro-migratory.

The present invention relates to novel compositions and methods for reducing or eliminating the thrombogenicity of a graft by modifying the graft with a cell-derived extracellular matrix lacking thrombospondin-2 (TSP2-null ECM) to render it non-thrombogenic when transplanted to a subject in need thereof. The invention also provides a method for improving the biocompatibility of a medical device or an implant by modifying the medical device or implant with a cell-derived TSP2-null ECM, whereby the medical device or implant is rendered non-thrombogenic and pro-migratory.

Provided is a clot adhesion preventing agent capable of suppressing adhesion of clot to the inner wall surface of a blood collection container. The clot adhesion preventing agent according to the present invention includes a polyether compound or a silicone oil, and an amino acid.

Disclosed is an extracorporeal blood circulation device including a blood circulation circuit including a blood extraction line and a return line, a blood circulator in the circulation circuit and a control unit including a calculator arranged determining at least one parameter, recording it in a memory, and then comparing the standard value of the parameter with the recorded value. The device also includes a source of solution for liquefying blood clots, a device injecting and conveying the liquefaction solution in the circulation circuit, the control unit including a driver for the injector of the liquefaction solution. The control unit is arranged to actuate the driver when the value is exceeded, meaning that at least one clot has formed, the driver being arranged so that the liquefaction solution is present in the circulation circuit in an amount and for a time determined to be sufficient for liquefying the clot formed.

A method for passivating a biomaterial surface includes modifying proteinaceous material disposed at the biomaterial surface. The passivation may be effectuated by exposing the biomaterial surface to therapeutic electrical energy in the presence of blood or plasma.

The present invention discloses a compound heparin anticoagulant coating liquid, a microsphere for coating and its preparation methods and applications. In the present invention, the combination of curcumin and heparin can enhance the anticoagulation functions of heparin coating, and further enhance the stability using the properties of PLA-PEG-PLA drug-loaded sustained-release microspheres, achieving the functions of anti-tissue proliferation and anti-inflammatory reactions that cannot be achieved by coatings alone such as heparin or protein, which is very important for implanted devices such as artificial blood vessels, vascular stents and vascular patches to reduce thrombosis in the human body, lower postoperative complications and improve product lifespan.

Disclosed is an extracorporeal blood circulation device including a blood circulation circuit including a blood extraction line and a return line, a blood circulator in the circulation circuit and a control unit including a calculator arranged determining at least one parameter, recording it in a memory, and then comparing the standard value of the parameter with the recorded value. The device also includes a source of solution for liquefying blood clots, a device injecting and conveying the liquefaction solution in the circulation circuit, the control unit including a driver for the injector of the liquefaction solution. The control unit is arranged to actuate the driver when the value is exceeded, meaning that at least one clot has formed, the driver being arranged so that the liquefaction solution is present in the circulation circuit in an amount and for a time determined to be sufficient for liquefying the clot formed.