Artificial organ development is propelled by new developments in material science, biotechnology, and regenerative medicine. Scientists are trying out many methods, among them 3D printing, to produce ...

Researchers at the Terasaki Institute for Biomedical Innovation (TIBI) have developed a technique that could help advance ...

During the early stages of life, organs do not just appear in their final form. They take shape through a process of ...

Researchers expect LICONN technology will be broadly useful to enable high-resolution tissue analysis in other organs and ...

at the session dedicated to "Tissue Engineering and Organ Repair," addressed these topics and offered an interesting view of the trends and directions in which this exciting field is moving ...

A bioreactor that mimics a circulatory system can deliver nutrients and oxygen to artificial tissue ... of perfusion on tissue quality, adapting the technology for organ fabrication and biohybrid ...

The work to create viable human tissue from scratch ... Here are a few of the organs and tissues in the works: A 3D bioprinter at Cornell University squeezes out an artificial ear material ...

Assuming that different aligning patterns and distribution of collagen fibers account for this difference, cartilage engineering ... processes in tissue regeneration. The ideal artificial collagen ...

In a medical first, a man in Australia survived 100 days with no biological heart—only a titanium device pumping blood through his body. This isn’t science fiction—it’s the reality of cutting-edge ...

Traditionally, tiny models of human tissue that mimic human physiology, known as microfluidics, organ-on-chip ... a professor of biomedical engineering and materials science & engineering at ...

The Terasaki Institute's light-based 3D printing method advances tissue engineering, enabling tailored microgels for ...

Crispr-Cas9 is a tool for making precise edits in DNA, discovered in bacteria. The acronym stands for 'Clustered Regularly ...