Understanding how a healthy brain works can provide insight into how it fails, too. Scientists hope that studying organoids derived from humans with neurodevelopmental disorders — particularly ...

Human spinal cord organoids have been used to model different types of spinal cord injuries and test a promising new regenerative therapy.

Organoids have revolutionized science and medicine, providing platforms for disease modeling, drug testing, and understanding developmental processes. While not exact replicas of human organs, they ...

Organoids have transformed biomedical research by giving scientists miniature versions of human organs to study in the lab.

Pasca Lab specializes in growing three-dimensional organoid models from reprogrammed stem cells, which capture molecular changes during fetal brain-like development. Because the human brain cannot be ...

Discover the groundbreaking research on organoid models for spinal cord injury, promising new therapies for paralysis recovery.

Evanston, Ill.-based Northwestern University scientists have created the most advanced human spinal cord injury organoid model to date, enabling researchers to test regenerative therapies in lab-grown ...

Organoids modeled on the structure of the human spinal cord have been shown to match the behavior of an injured spine. Now, a treatment that has worked well in mice has been applied to the organoids, ...

Atelerix, a biotech company working on cell preservation and biological transport with its hydrogel encapsulation technology, entered a partnership with Cherry Biotech, a French company specializing ...

The liver has a unique structure, especially at the level of individual cells. Hepatocytes, the main liver cells, release bile into tiny channels called bile canaliculi, which drain into the bile duct ...

Periportal assembloid, with the three component cell types visualized: cholangiocytes in pink, portal fibroblasts in green, and hepatocyte nuclei in blue; all cell borders are visualized in white. New ...