noun a scientific technique that allows the observation of samples at cryogenic temperatures using electron microscopy
In materials science, cryo-electron microscopy is employed to investigate the structure of materials at the nanoscale level.
Cryo-electron microscopy is utilized in biochemistry to study the structure and function of proteins and other biomolecules.
In virology, cryo-electron microscopy plays a crucial role in visualizing the structure of viruses and understanding their mechanisms of infection.
Cryo-electron microscopy is used in cell biology to study the ultrastructure of cells and organelles at high resolution.
In structural biology, cryo-electron microscopy is used to determine the structures of biological macromolecules at near-atomic resolution.
Cryo-electron microscopy is used by biologists to study the structures of biological molecules at near-atomic resolution. This technique allows them to visualize proteins, viruses, and other biomolecules in their native state.
Chemists use cryo-electron microscopy to investigate the structures of molecules and materials at the atomic level. This helps them understand the properties and behaviors of various compounds, leading to advancements in drug development, materials science, and more.
Biochemists utilize cryo-electron microscopy to examine the structures of complex biomolecules such as proteins and nucleic acids. By visualizing these molecules in their natural environment, biochemists can gain insights into their functions and interactions.
Pharmacologists employ cryo-electron microscopy to study the interactions between drugs and their target molecules. This technique provides detailed information on drug-binding sites, helping pharmacologists design more effective and specific medications.