The present invention relates to a raw material for a bio-3D printing support and, more specifically, to a novel type bio-3D printing support material for tissue engineering, a method for manufacturing a three-dimensional support by using the same, and a 3D-printing three-dimensional support manufactured thereby, the raw material: being non-toxic and implementing excellent biocompatibility and cell adhesion since a raw material for a tissue engineering support (scaffold) produced by bio-3D printing technology, a specific fatty acid and a fatty alcohol (phase change material) derived from a natural source having a low melting point and a low molecular weight are used; and, in particular, allowing a phase change to easily occur at a temperature similar to body temperature such that a process is simplified and cells or growth factors can be mixed.

Generally, the invention is in relation to the field of drug delivery devices to augment standard radiation therapy and methods of making and using same. Specifically, this technology utilizes a controlled release of drug from a coated balloon for local intratumoral drug delivery to breast tissue to supplement or replace standard radiation therapy.

Provided herein are compositions comprising heparan sulfate, or a pharmaceutically acceptable salt thereof, and sphingosine-1-phosphate, or a pharmaceutically acceptable salt thereof. Such compositions are useful in a variety of methods, including methods of regenerating endothelial glycocalyx, preventing endothelial glycocalyx degradation and treating vascular disease.

The present invention provides a biocompatible hydrogel composition comprising glycolipids and silk fibroin (SF) wherein glycolipid is preferably sophorolipids (SL). The said composition is useful in preparation of 3D scaffold for use in tissue engineering, and in the biomedical field. The present invention also provides a process for preparing such a composition and a process for acceleration of gelation time of silk fibroin (SF) in the presence of sophorolipid.

This embolic material is produced by a production method including a step for dispersing a mixture that contains a biodegradable polymer, an oil-based contrast agent, and a solvent in a hydrophilic liquid. The biodegradable polymer has a hydrophobic biodegradable polymer.

The present invention relates to a coating composition for an in-vivo implantable prosthesis including a photoinitiator, a crosslinking agent, and a phosphorylcholine (pc) monomer having an acrylate group, a method of coating an in-vivo implantable prosthesis using the coating composition, and a cosmetic prosthesis coated with the crosslinked polyphosphorylcholine. An in-vivo implantable prosthesis coated with crosslinked polyphosphorylcholine may be manufactured by a simple method of applying a coating composition including a photoinitiator, a crosslinking agent, and a phosphorylcholine (pc) monomer having an acrylate group according to the present invention, and then irradiating uv rays. The crosslinked polyphosphorylcholine coating may provide hydrophilicity for the surface and may also remarkably reduce adsorption of proteins and fibroblasts, which may cause side effects such as capsular contracture. Further, the coating has strong enough not to peel off even under stimulation, and therefore, it is maintained under vigorous activity after implantation, thereby being usefully applied to the manufacture of an in-vivo implantable prosthesis with reduced side effects, such as breast prosthesis for cosmetic surgery.

Generally, the invention is in relation to the field of drug releasing insertable devices and methods of making and using same. Specifically, this technology relates to controlled release of drug from a coated balloon directly into affected tissue regions within the body of an individual.

Various embodiments disclosed relate to drug-coated balloon catheters for treating strictures in body lumens and methods of using the same. A drug-coated balloon catheter for delivering a therapeutic agent to a target site of a body lumen stricture includes an elongated balloon having a main diameter. The balloon catheter includes a coating layer overlying an exterior surface of the balloon. The coating layer includes one or more water-soluble additives and an initial drug load of a therapeutic agent.

A method for treating a target vascular portion of a subject including: providing an angioplasty balloon system including a balloon carrying a first therapeutic agent and a second therapeutic agent on a surface of the balloon, wherein the first therapeutic agent is an anti-proliferative or anti-mitotic agent and the second therapeutic agent is a drug that aids in vascular healing on a surface of the balloon; positioning the balloon proximate the target vascular portion; expanding the balloon to engage the target vascular portion; thereby delivering at least a portion of the active agent to the target vascular portion; and withdrawing the balloon from the subject.

The subject invention provides topical therapeutic compositions and methods of their use for enhanced healing of wounds, including burns, and scars of the skin, wherein the compositions and methods utilize microbial biosurfactants. The invention reduces the healing time of skin wounds, reduces the appearance of scars, and improves other skin conditions such as acne, psoriasis and eczema.