This white paper illustrates the importance of three-dimensional (3D) cell culture in the production of pluripotent stem cell (PSC)-derived models of embryo development and differentiation. It contains a general overview of embryoid bodies (EBs) and a comparison between the various
Sophisticated models are developing as 3D cell culture technology becomes established and accepted as a means of creating more physiologically relevant cell-based assays.
The extracellular (ECM) microenvironment, defined by biochemical cues and physical cues, is a deciding factor in a wide range of cellular processes including cell adhesion, proliferation, differentiation, and expression of phenotype-specific functions. For this reason, engineering the ECM microenvironment provides
Take a deep dive into the world of 3D cell culture courtesy of Corning and understand why the Corning® spheroid microplate can be an asset in the evolution of 3D cell culture.
Methacrylated collagen, hyaluronic acid, and gelatin (GelMA) hydrogels can be crosslinked with light and photoinitiators (Irgacure/LAP/Ruthenium), used as 3D cell culture scaffolds and bioinks for bioprinting.
TrueGel3D™ is a synthetic hydrogels platform for 3D cell culture that aim to mimic the natural extracellular environment for more physiological culture conditions
Discover a high throughput assay using organoids and Millicell® Microwell plates. Our novel blood brain barrier model allows direct cell-to-cell interactions, closely modeling the in vivo properties.
Learn about the similarities and differences in spheroid formation, roundness, and circularity between Millicell® ultra-low attachment plates and other ULA plates.
Learn how to grow spheroid cultures in ULA plates, the common applications and benefits of ULA plates for 3D cell culture, Millicell® ULA plate dimensions, plate handling, troubleshooting, and more.
Numerous cancer model systems are available to investigate disease mechanisms and to screen therapies. While all of the models have contributed critical information about cancer biology.
The extracellular matrix (ECM) and its attachment factor components are discussed in this article in relation to their function in structural biology and their availability for in vitro applications.