Computational biology meets cancer research as AlphaFold-predicted peptide scaffolds enable more accurate drug testing in endometrial cancer organoids. This integration of AI and experimental biology could accelerate personalized medicine approaches for treatment-resistant cancers.
Scientists have engineered advanced nanogel systems that effectively encapsulate and protect negatively charged therapeutic molecules. The breakthrough technology demonstrates significant potential for improving delivery of challenging biopharmaceuticals like nucleic acid-based drugs while maintaining excellent biocompatibility.
Researchers have developed a groundbreaking peptide-based nanogel system that shows remarkable potential for delivering negatively charged therapeutic molecules, according to recent scientific reports. The technology addresses a significant challenge in pharmaceutical science: effectively encapsulating and protecting anionic bioactive compounds that have traditionally been difficult to administer.
Researchers at EPFL have pioneered a revolutionary approach to metal manufacturing that literally grows metal structures. Using hydrogel templates and metal salt infusions, this method creates components 20 times stronger than conventional 3D-printed metals while significantly reducing material shrinkage.
In a groundbreaking development that could transform manufacturing, scientists have discovered how to literally grow metal using an innovative approach that combines hydrogel templates with metal salt infusion. This revolutionary method, developed by researchers at Switzerland’s Ecole Polytechnique Fédérale de Lausanne, represents a significant leap forward in 3D printing technology and additive manufacturing capabilities.
