Functional connectivity networks represent specific patterns of synchronous activity and differ between healthy subjects, stages of consciousness and across disease. Discover the latest research on functional connectivity networks here.
AFM in situ DNA describes in situ analysis (or study) of DNA using atomic force microscopy. Discover the latest research on AFM in situ DNA here.
Neuroimaging can help identify pathological hallmarks of Alzheimer's disease (AD). Here is the latest research on neuroimaging modalities, including magnetic resonance imaging and positron emission tomography, in AD.
Artificial intelligence (ai) techniques are increasingly applied to cardiovascular (cv) medicine in cardiac imaging analysis. Here is the latest research.
Neural circuits are groups of interconnected neurons which carry out specific functions when activated. Imaging these neural circuits allows researches to further elucidate their mechanisms and functions. Follow this feed to stay up to date on brain imaging of neural circuits.
Molecular imaging enables noninvasive imaging of key molecules that are crucial to tumor biology. Discover the latest research in molecular imaging in cancer biology in this feed.
Imaging techniques, including CT and MR, have become essential to tumor detection, diagnosis, and monitoring. Here is the latest research on cancer imaging.
Here is the latest research on cell imaging and imaging modalities, including light-sheet microscopy, in the central nervous system.
Computed axial tomography (CT or CAT) is a non-invasive imaging technique that uses X-rays to take slices of the particular region of interest. This data is sent to a computer where a 2D image is generated. CT of the brain can be helpful in understanding pathological processes of some diseases. Discover the latest research of CT of the brain here.
Ultrasound uses sound waves to provide images of the area of interest. Cranial ultrasound is most often used in babies to visualize their fontaneles. Discover the latest research on cranial ultrasounds here.
Cryogenic electron microscopy (Cryo-EM) allows the determination of biological macromolecules and their assemblies at a near-atomic resolution. Here is the latest research.