3D Printed Tissue/Organs: Scientists are using 3D bioprinting to create, vascularized, and, functional, tissues, such as skin, cartilage, and, even, heart, tissue, which could eventually replace organ transplants. In this Video clip: Watch the process as the Biomodeling & Biomeasurements Lab creates 3D-printed constructs that look like tissue and human organs. A quad-extension bioprinter was built in-house at Stevens Institute of Technology by using other commercial, off-the-shelf resin printers to make its necessary components. This low-cost design can help close the gap between organ fabrication and transplantation and is a step forward in making it more affordable and available for future patients. Would you accept a transplant of a 3D Bioprinted part?

Creating Cartilarge; It's the holy grail in orthopedics: Finding a way to enhance damaged or naturally deteriorating cartilage. Now a finding in the lab stands to revolutionize joint care, turning back the hands of time. Do you have any challenges with your joints?

Cartilage Scaffolds: Researchers have developed cell-free scaffolds that allow the body to regrow its own bone. Here is How scaffold and biomaterials help regeneration, After the discovery of stem cells, we started isolating them and culturing them in the lab to make thousands and millions of them. One treatment is to directly inject those stem cells to the site of injury, which we call free cell transplantation. But it isn't a very efficient treatment. Because most of the stem cells that we are going to inject are going to be lost during the procedure. Moreover, many of them don't know what they should do after that. To overcome this, we make a temporary structure called a "scaffold" to support the stem cells. It provides physical and chemical cues for our stem cells to proliferate and differentiate into more specified cells. Therefore, the properties of the scaffold are crucial. In this video, some of those properties are explained. Were you aware of tis Regenerative Medicine?