Researchers have developed a novel animal-free method to predict the toxic effect of nanoparticles to the human lung. The method aims to enable the safety-by-design development of safer industrial materials.
Researchers have developed a novel animal-free method to predict the toxic effect of nanoparticles to the human lung. The method aims to enable the safety-by-design development of safer industrial materials.
Pioneering research shows how high-frequency sound waves can help build smart materials, new nanoparticles and deliver drugs to the lungs for painless, needle-free vaccinations.
Researchers demonstrate an alternative sputter deposition-based approach for the replication of atomic-scale features that is suited for a very broad range of amorphous alloys, thereby dramatically extending the available chemistries.
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Researchers have developed a novel animal-free method to predict the toxic effect of nanoparticles to the human lung. The method aims to enable the safety-by-design development of safer industrial materials.
Pioneering research shows how high-frequency sound waves can help build smart materials, new nanoparticles and deliver drugs to the lungs for painless, needle-free vaccinations.
Researchers demonstrate an alternative sputter deposition-based approach for the replication of atomic-scale features that is suited for a very broad range of amorphous alloys, thereby dramatically extending the available chemistries.
Scientists demonstrate laser light in the mid-infrared range with tailor-made quantum cascade lasers.