Complex biological systems are more than the sum of their parts – their properties emerge from the dynamic interaction of their components, such as molecules or cells. PhD researchers now have the ...

Complex biological systems are more than the sum of their parts – their properties emerge from the dynamic interaction of their components, such as molecules or cells. PhD researchers now have the ...

A research team at Duke University has developed a new AI framework that can uncover simple, understandable rules that govern some of the most complex dynamics found in nature and technology.

The discipline of bioinformatics integrates biology and computer science to improve our understanding of complex biological systems. Bioinformatic analysis describes the processing of biological data ...

Cells naturally process external signals through intricate genetic circuits, enabling the adaptation to diverse environments. These circuits rely on complex, nonlinear interactions among genes and ...

Until today, skin, brain, and all tissues of the human body were difficult to observe in detail with an optical microscope, since the contrast in the image was hindered by the high density of their ...

A new AI developed at Duke University can uncover simple, readable rules behind extremely complex systems. It studies how systems evolve over time and reduces thousands of variables into compact ...

Explore the impact of drug discovery automation in 2026, addressing complexity and improving decision-making across ...

Researchers at the National Science Foundation (NSF) are studying the potential to harness the computer skills of tiny groups of biological cells known as organoids. Brains, whether human or animal, ...

A new suggestion that complexity increases over time, not just in living organisms but in the nonliving world, promises to rewrite notions of time and evolution. In 1950 the Italian physicist Enrico ...