In the recent decade, the artificial biofabrication of muscle tissue attracted great interest. Due to its diverse applicability, for example as cultured meat 1, biorobotic systems 2, biohybrid ...

Natural sources, such as microorganisms (e.g., bacteria, fungi, yeast, and algae) and plant extracts, have acted as eco-friendly precursors for producing nanoparticles with several potential ...

Polyurethane scaffolds have become central to tissue engineering due to their adaptable mechanical properties, controllable biodegradability and biocompatibility. Their segmented architecture allows ...

These fields aim to facilitate healing and restore lost function in damaged or diseased tissues and organs by integrating scaffolds, cells, and biological signaling molecules. This combination aims to ...

3D bioprinting involves the precise printing of biocompatible materials, cells, growth factors, and other essential elements required to create intricate and functional living tissues. Several forms ...

Nanoscale structure-property relationships of biological materials, genetic and molecular origins of soft joint tissue diseases, biomaterials under extreme conditions, coupling between ...

Traditional-tissue engineering approaches (Panel A) seed cells onto a three-dimensional biomaterial scaffold that serves as a framework for new tissue development (i). The scaffold degrades as new ...

Kiani Barnard-Pratt came to Alfred University as a biomaterials engineering major, with an interest in pursuing a career in the development of prosthetics. Now a senior, she is working on a research ...