A new in-plate, zero-disruption design enables reproducible organoid culture, downstream processing, and high-resolution imaging in a single 3D cell culture plate MONMOUTH JUNCTION, N.J., Feb. 9, 2026 ...

Advanced 3D cell models recreate the complexity of human tissues, enabling researchers to examine tumor progression, probe neurological disorders, and assess therapeutic candidates. By capturing the ...

CompagOS has produced biologically reproducible Bon3OID™ bone models using 3D bioprinting. Find out more in the interview!

In a major leap forward for genetic and biomedical research, two scientists at the University of Missouri have developed a powerful new artificial intelligence tool that can predict the 3D shape of ...

Traditionally, scientists have used 2D cell cultures as in vitro models in drug screening studies due to their simplicity and scalability. However, 2D cell models do not recapitulate the complexity of ...

Over the past two decades, researchers have learned that DNA inside the cell nucleus naturally folds into a network of ...

Most potential oncology drugs fail during the drug development pipeline, even when there has been promising data for their efficacy during the in vitro stage. This makes it vital to identify in vitro ...

Most cells in the human body exist in complex three-dimensional environments, yet they are still commonly studied on flat plastic dishes.

Before cells can divide by mitosis, they first need to replicate all of their chromosomes, so that each of the daughter cells can receive a full set of genetic material. Scientists have until now ...

The VitroPrime™ 3D Culture and Imaging Plate was engineered to overcome these challenges by enabling a true end-to-end 3D workflow—from sample seeding and long-term culture to downstream processing ...