The present invention discloses a preparation method of a biomedical titanium implant with a function of eliminating a surface biomembrane. The method includes the following steps: firstly synthesizing mesoporous polydopamine (MPDA) nanoparticles by a “one-pot method”, constituting a surface-aminated titanium material through diacid corrosion and modification of a 3-aminopropyltriethoxysilane (APTES) coupling agent, and integrating the MPDA nanoparticles into the surface of the titanium material through Michael addition reaction; secondly, taking MPDA anchored on the surface of the titanium material as a photothermal material and a photosensitizer carrier, where MPDA contains abundant aromatic rings capable of facilitating abundant loading of a photosensitizer (indocyanine green, ICG) through π-π stacking interaction; and finally further modifying biocompatible RGD polypeptides on the surface of MPDA by Michael addition reaction, where a modified titanium material is referred to as Ti-M/I/RGD.

Described herein are hydrogels attached to a base with the strength and fatigue comparable to that of cartilage on bone and methods of forming them. The methods and apparatuses described herein may achieve an attachment strength between a hydrogel and a substrate equivalent to the osteochondral junction. In some examples the hydrogel may be a triple-network hydrogel (such as BC-PVA-PAMPS) that is attached to a porous substrate (e.g., a titanium base) with the shear strength and fatigue strength equivalent to that of the osteochondral junction.

A hemostatic composition is provided. The hemostatic composition includes a hemostatically effective amount of a hemostatic agent that includes a nanoparticle and a polyphosphate polymer attached to the nanoparticle. Also provided are medical devices and methods of use to promote blood clotting.

A drug-loaded medical device, a preparation method therefor, a drug balloon and a method of preparing a drug coating are disclosed. The medical device or the drug balloon is provided on a surface thereof with a drug coating including a stabilizer and a drug. The stabilizer includes an amphiphilic triblock polymer with hydrophilic segments at both terminals, and the drug coating forms a nano-drug particle suspension in a water-soluble environment. In this way, the prepared nano-drug coating has high drug loading and can deliver the drug in a desirable way. In particular, when it comes into contact with water, the drug can be restored to the original nano size, almost without any particle size increase. This not only avoids the risk of embolism caused by granules, but also enables higher device safety, increased drug uptake and improved therapeutic effects.

A method of producing an osteoinductive bone graft formed of a plurality of electrospun biodegradable fibers is disclosed. The method includes preparing a fibrous scaffold material formed of the plurality of electrospun biodegradable fibers, wherein the plurality of electrospun biodegradable fibers are entangled with each other to form a cotton-wool like structure having inter-fiber spaces forming a microenvironment for cell growth therein, and immersing the fibrous scaffold in a solution containing BMP-2 so that the BMP-2 is bound to the calcium particles exposed on the surface of the fibers. Area of binding site for BMP-2 on calcium particles exposed on a surface of the electrospun biodegradable fibers is adjusted by an amount of the calcium particles contained in the electrospun biodegradable fibers.

Provided are compositions that can be employed for generating microporous gel systems. In some embodiments, the compositions include at least one sub-population of soft hydrogel microparticles with a Youngs modulus of less than 50 kPa and at least one sub-population of stiff hydrogel microparticles with a Young's modulus of greater than 90 kPa. Also provided are methods for generating the compositions, methods for treating bone and/or cartilage defects in subject using the disclosed compositions, methods for treating osteoarthritis using the disclosed compositions, and methods for providing orthopedic implants to subjects.

A scaffold for tissue repair or wound dressing comprising: a material layer; a polymer fibre layer; and an adhesive component between the material layer and the polymer fibre layer, wherein the adhesive component comprises material having a lower melting temperature (Tm) than the material layer and the polymer fibre layer.

The present invention provides for nanostructured fibrin and agarose hydrogels, preferably type VII agarose hydrogels, (NFAH) or non-nanostructured or pre-nanostructured fibrin and agarose hydrogels, preferably type VII agarose hydrogels, (FAH), as hemostatic agents designed for use as an adjunct or primary treatment in moderate intraoperative hemorrhage and in trauma. These hydrogels can be applied topically to the wound either on the skin in a laparotomy or as non-invasive manner in surgical procedures. Its nanostructure technology generates an adhesive stable fibrin clot required for hemostasis. The attachment properties of the hydrogel, as well as the rapid formation of a fibrin clot, ensures that a strong stable fibrin clot is formed shortly after application.

A sheet structure comprising two joined extracellular matrix (ECM) tissue or sheet layers and a physiological sensor disposed therebetween; the ECM tissue being derived from a mammalian tissue source that includes small intestine submucosa (SIS), urinary bladder submucosa (UBS), stomach submucosa (SS), urinary basement membrane (UBM), liver basement membrane (LBM), amniotic membrane, mesothelial tissue, placental tissue and cardiac tissue.

The invention provides antimicrobial compositions comprising charged cellulose nanofibrils dispersed in an aqueous solution having a dissolved oxygen content of at least 20 mg/L, preferably from 20 to 100 mg/L. The cellulose nanofibrils may have an increased surface charge due to their carboxylic acid content which contributes to their antimicrobial properties. In particular, the carboxylic acid content may be at least about 1000 μmol/g cellulose, preferably at least about 1400 μmol/g cellulose. The compositions are suitable for use in the treatment of wounds, in particular chronic wounds.