The Scanning Microwave Microscope (SMM) merges the nanoscale imaging capabilities of an atomic force microscope (AFM) with the high-frequency broadband (from MHz to GHz) impedance measurement accuracy ...

Understanding the behavior of the molecules and cells that make up our bodies is critical for the advancement of medicine. This has led to a continual push for clear images of what is happing beyond ...

There are various ways to image biological samples on a microscopic level, and each has its own pros and cons. For the first time, a team of researchers, including those from the University of Tokyo, ...

Microwave imaging is similar to CT imaging, but instead of X-rays, the microwaves are used to probe the structure and composition of an object. To facilitate experimentation with microwave imaging, ...

Researchers have developed a novel technology that allows the distribution of components within a single cell to be accurately detected and visualized. Positioning a t-SPESI (tapping-mode scanning ...

Chromacity Ltd., in conjunction with the Institute of Genetics and Medicine, Edinburgh and ICFO* Barcelona has published a report demonstrating how the ultrashort pulse width of its Chromacity 1040 ...

Preparing biological samples for imaging usually requires utilizing a range of physical and chemical processes, including dehydration and fixing. These processes can alter the structure of the sample, ...

Are you studying complex biological structures such as vasculatures or neuronal networks but feel like you're not seeing the whole picture? Step into a new dimension with the UltraMicroscope Blaze™ ...

Life science research relies upon advanced imaging technologies for detailed insights into the structure and function of organs, tissues, cells, and sub-cellular molecules. High-resolution 3D images ...