Microgravity offers a unique condition for tissue engineering, advancing stem cell-derived liver tissue development. But how can we transport these tissues to Earth without damaging them? Researchers ...

The field of tissue engineering and regenerative medicine has seen remarkable progress with the advent of 3D bioprinting technologies and the development of ...

Working with three-dimensional pancreatic models (organoids), derived from mouse cells, researchers combined computer simulations with experiments to find out what controls the shape of lumens ...

In a breakthrough that brings bioengineered organs one step closer to reality, scientists have created lab-grown liver tissue capable of forming its own blood vessels. A team from Cincinnati ...

Assembloids: A Versatile Platform for Human Tissue Modeling. This schematic illustrates the classification of assembloids based on four key assembly strategies—multi-region, multi-lineage, ...

The contraction process involves interactions between actin and myosin filaments within the sarcomeres to generate force. Recent research has achieved significant advances in functional design, ...

Forming sensory organs requires complicated interactions between numerous cell types. Building these tissues in a dish from human stem cells helps researchers understand how they develop over time and ...

Hydrogels are often used as scaffolds in tissue engineering. Living cells infused into the material can, theoretically, grow through the gel until an entire piece of tissue forms. But to grow well, ...

The study shows that fat tissue, when processed and cultured in a specific way, can self-organize into structures resembling ...

Mechano-Growth Factor (MGF), often referred to as the IGF-1 Ec isoform (or IGF-1 Eb), is a splice variant of the insulin-like ...