The effectiveness of non-clinical drug safety predictions is enhanced by the adoption of three-dimensional (3D) cellular models. 3D bioprinting enables the generation of complex models with spatial ...

U-shaped microcavities made of PEG hydrogel ensure consistent, uniform organoid formation for reliable 3D culture results. InSphero Logo InSphero acquires DOPPL SA and Sun Bio’s Gri3D® platform, ...

Researchers from Texas A&M 3D printed models of lung cells to simulate the effects of extreme pressure and temperature on the ...

Researchers at Texas A&M University model extreme conditions using 3D bioprinting, revealing insights that could make flight and space travel protocols safer while driving new breakthroughs in ...

Research and drug discovery are undergoing a transformation, driven by the rise of 3D cell culture models that better replicate human biology. Unlike traditional 2D cultures and animal models, which ...

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 ...

A research team, including academics from Malmö University, has developed a 3D model based on human cells that mimics the ...

In associate professor Mauro Tambasco's lab, researchers at all levels work together to develop innovative approaches to fighting cancer.

InSphero acquires DOPPL SA and Sun Bioscience’s Gri3D® platform, expanding its unified 3D spheroid–organoid ecosystem for ...