Real-Time 3D Imaging of Living Organisms
Product News Nov 09, 2016
Leica Microsystems CMS GmbH has entered an exclusive, worldwide licensing agreement with Columbia University in New York to commercialize SCAPE microscopy for Life Science applications. SCAPE (swept confocally aligned planar excitation) microscopy forms 3D images of living samples by scanning them with a sheet of laser light. SCAPE's unique capabilities allow scientists to perform fundamentally new kinds of experiments, from imaging individual neurons firing throughout the brain of adult fruit flies, to tracking calcium waves through cells in the beating heart of a zebrafish. SCAPE also stands to create new inroads for understanding diseases such as cancer, and for the development of new drugs and therapies.
SCAPE microscopy was developed in the laboratory of Elizabeth Hillman, PhD, associate professor of biomedical engineering and radiology at Columbia University and a principal investigator at Columbia's Mortimer B. Zuckerman Mind Brain Behavior Institute. SCAPE's ingenuity lies in being able to both scan and image a moving light sheet through a single, stationary objective lens. SCAPE delivers 3D-imaging speeds that are 10 to 100 times faster than conventional point-scanning microscopes, while maintaining the benefits of light-sheet imaging including low photodamage. Compared to conventional light-sheet microscopes that require multiple objective lenses and complex sample positioning, SCAPE's patented single-objective approach greatly diversifies the range of intact and freely moving samples that can be imaged in 3D at near video-rates. SCAPE technology was recognized late last year with a prestigious grant award from the National Institutes of Health BRAIN Initiative.
"SCAPE's ability to perform real-time 3D imaging at cellular resolution in living, freely moving organisms is a new frontier for neuroscience research," said Dr. Hillman. "Beyond neuroscience, SCAPE is enabling fundamentally new scientific experiments by transforming our ability to capture 3D structure and function, movement, behavior and cellular activity in real-time across a wide range of organisms and biological samples."
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