New computer simulations that model every atom of a protein as it folds into its final three-dimensional form support the existence of a recently identified type of protein misfolding. Proteins must ...

In late May 2026, a research team from IBM, Japan’s RIKEN institute, and the Cleveland Clinic reported that they had simulated protein-ligand complexes containing up to 12,635 atoms by linking quantum ...

Spider silk has garnered significant attention due to its remarkable mechanical properties, making it an extraordinary material. What sets it apart is its unique combination of strength, toughness, ...

The development of quantum computing across several technologies and platforms has reached the point of having an advantage over classical computers for an artificial problem, a point known as ...

Companies working at the frontier of aerospace, energy and computing are constantly looking for new materials to improve performance. But in order to understand how those materials will actually ...

CGSchNet, a fast machine-learned model, simulates proteins with high accuracy, enabling drug discovery and protein engineering for cancer treatment. Operating significantly faster than traditional all ...

Harvard researchers bring the accuracy, sample efficiency, and robustness of deep equivariant neural networks to the simulate 44 million atoms. This is achieved through a combination of innovative ...

Recently identified and long-lasting type of protein misfolding — non-native entanglements — observed in all-atom protein folding simulations. Representative misfolded conformations of the small ...