A nanogel comprising a self-organizing peptide, a chitosan, and polyethylene glycol.

Provided is a dental cord using a nanofiber multiple yarn having a large specific surface area and a large number of three-dimensional pores, thereby effectively impregnating a drug such as a hemostatic agent, and a method of manufacturing the dental cord. The dental cord includes: a nanofiber multiple yarn which is obtained by plying and twisting at least two nanofiber tape yarns and which is impregnated with a drug, wherein the at least two nanofiber tape yarns are integrated by nanofibers made of fiber moldability polymer materials and having an average diameter of less than 1 μm, to thus be formed of a nanofiber web having three-dimensional micropores.

The invention generally relates to a method of regenerating a nerve fiber in a damaged neural tissue of a patient, the method comprising the steps of: administering an aqueous formulation comprising superparamagnetic particles to the damaged neural tissue in the patient; applying a magnetic field in an orientation which is parallel to the nerve fiber; using the magnetic field for aligning the superparamagnetic particles; forming one or more aligned chains of the superparamagnetic particles in the magnetic field as a scaffold to guide directional growth of regenerating nerve cells; and reconnecting damaged nerve ends in the damaged neural tissue of the patient.

A bone regeneration material according to the present disclosure includes at least a composite of octacalcium phosphate (OCP) particles and gelatin, and is a porous body having a plurality of pores. The particle size of the octacalcium phosphate particles is 1 μm or more but less than 1 mm, and the molecular weight of the gelatin is in the range of 30 kDa to 70 kDa. Thus, the material is able to resist breaking down during implantation and exhibit high handleability.

An implant material may comprise a hole in at least one direction, and a member constituting the hole may comprise grooves. The member constituting the hole may be composed of a pillar and/or a plate. The grooves may be provided in the pillars and/or the plates. Further, a method of manufacturing the implant material may include manufacturing the implant material using a 3D modeling method.

The present invention relates to a device for preparing three dimensional (3D) nanofibers (blended or coaxial) materials by electrospinning. An automatic nanofiber collector device is used to control the porosity, pore size, crystallinity, geometry, the layer number and thickness of formed nanofibers. The automatic nanofiber collector device includes: (1) a collector platform; (2) a non-conductive device used to fix the collector device; (3) a plurality of electro-conductive wires or needles being pierced through the collector platform with various heights, and (4) the ends of the needles (at bottom) are wired and controlled by a microcontroller, providing forward, stand and backward movements for attached needles. The desired 3D nanofiber scaffold structures can be tailored by the micro-stepping programmable motor controller by changing the pattern and velocity of needle movement, generalized or selective needles movements, as well as intermittent versus continuous movement.

The present invention relates generally to a hydrogel releasing glucose in a time-controlled manner, to medical applications thereof, and to a method for preparing said hydrogel.

Particular aspects of the present disclosure provide bio-resorbable and biocompatible compositions for bioengineering, restoring, or regenerating tissue or bone. In one embodiment, a biocompatible composition includes a three-dimensional porous or non-porous scaffold material comprising a calcium phosphate-based ceramic having at least one dopant therein selected from metal ion dopants or metal oxide dopants. The composition is sufficiently biocompatible to provide for a cell or tissue scaffold, and resorbable at a controlled resorption rate for controlled strength loss under body, body fluid or simulated body fluid conditions.

The present application is directed to the field of scaffolds for tissue engineering. The scaffolds are typically comprised of nanofibers and are optionally biomineralized. The present application provides a process for forming nanofibrous materials via electrospinning and for biomineralizing such materials. The scaffolds of the present application can be biomineralized and contain a plurality of cells either on or within the scaffold, resulting in synthetic, bioresorbable scaffolds that can be used in various biomedical applications, such as for bone regeneration.

A method for coating a medical implant applies at least one coating to at least one surface of the implant by plasma polymerization. The implant has pores sized in the nanometer range. The method stabilizes the pores. The plasma polymerization is conducted in the presence of a coating gas and oxygen. A coating parameter can be selected so that a rough surface of the implant is coated. An implant includes a membrane having pores sized in the nanometer range. A surface of the implant is at least partially coated with a plasma polymer. The interior of the pores is uncoated.