20 January 2015

Swept Confocally Aligned Planar Excitation (SCAPE) Microscopy Provides High Speed 3D Images


A new microscope that can image cells in living things at high speed and in 3D has been developed at Columbia University Medical Center (CUMC). Swept Confocally Aligned Planar Excitation Microscopy or SCAPE is 10 to 100 times faster in 3D imaging than other conventional microscopy systems.

Elizabeth Hillman who is an associate professor of biomedical engineering at Columbia Engineering and of radiology at CUMC developed the microscope. She believes that the advancement of biomedical and neuroscience research has its foundation on real-time 3D imaging at the cellular resolution. She says that, ""With SCAPE, we can now image complex, living things, such as neurons firing in the rodent brain, crawling fruit fly larvae, and single cells in the zebrafish heart while the heart is actually beating spontaneously--this has not been possible until now.""

Unlike other microscopes that uses two objective lenses to help produce the 3d image, SCAPE uses a single-objective lens. A light sheet is swept through the sample producing the 3D image without even moving the lens or the sample.

The image on the left shows that the sample is lit up by a thin sheet of blue light at an angle which is swept back and forth within the sample. This area is then imaged onto a high speed sCMOS (Scientific Complementary Metal–Oxide–Semiconductor) camera through the objective lens. The illuminated plane is always co-aligned with the plane of the camera through de-scanning and image rotation optics. The end result is data equivalent to conventional light-sheet microscopy, but requiring a single, stationary objective lens, no sample translation, and consequently very high speed 3-D imaging. (See image on the left).

Although SCAPE currently does not have the penetration depth of a two photon microscope, the next-generation versions of SCAPE are in development that will deliver even better speed, resolution, sensitivity, and penetration depth.

Aside from neuroscience and biomedical research, where capturing live neurons can now be possible, SCAPE also has future potential in molecular biology and other clinical applications.

SCAPE for Biomedical and Neuroscience research

Opening new doors for biomedical and neuroscience research, Elizabeth Hillman, associate professor of biomedical engineering at Columbia Engineering and of radiology at Columbia University Medical Center (CUMC), has developed a new microscope that can image living things in 3D at very high speeds. In doing so, she has overcome some of the major hurdles faced by existing technologies, delivering 10 to 100 times faster 3D imaging speeds than laser scanning confocal, two-photon, and light-sheet microscopy. Hillman's new approach uses a simple, single-objective imaging geometry that requires no sample mounting or translation, making it possible to image freely moving living samples. She calls the technique SCAPE, for swept confocally aligned planar excitation microscopy. Her study is published in the Advance Online Publication (AOP) on Nature Photonics's website on January 19, 2015.

"The ability to perform real-time 3D imaging at cellular resolution in behaving organisms is a new frontier for biomedical and neuroscience research," says Hillman, who is also a member of Columbia's Mortimer B. Zuckerman Mind Brain Behavior Institute. "With SCAPE, we can now image complex, living things, such as neurons firing in the rodent brain, crawling fruit fly larvae, and single cells in the zebrafish heart while the heart is actually beating spontaneously--this has not been possible until now."

Highly aligned with the goals of President Obama's BRAIN Initiative, SCAPE is a variation on light-sheet imaging, but, "It breaks all the rules," says Hillman. While conventional light-sheet microscopes use two awkwardly positioned objective lenses, Hillman realized that she could use a single-objective lens, and then that she could sweep the light sheet to generate 3D images without moving the objective or the sample. "This combination makes SCAPE both fast and very simple to use, as well as surprisingly inexpensive," she explains. "We think it will be transformative in bringing the ability to capture high-speed 3D cellular activity to a wide range of living samples."

SCAPE is an urgently needed breakthrough. The emergence of fluorescent proteins and transgenic techniques over the past 20 years has transformed biomedical research, even delivering neurons that flash as they fire in the living brain. Yet imaging techniques that can capture these dizzying dynamic processes have lagged behind. Although confocal and two-photon microscopy can image a single plane within a living sample, acquiring enough of these layers to form a 3D image at fast enough rates to capture events like neurons actually firing has become a frustrating road-block.

Video: Swept Confocally Aligned Planar Excitation (SCAPE) Microscopy

While SCAPE cannot yet compete with the penetration depth of conventional two-photon microscopy, Hillman and her collaborators have already used the system to observe firing in 3D neuronal dendritic trees in superficial layers of the mouse brain. In small organisms, including zebrafish larvae, SCAPE can see through the entire organism. By tracking these tiny, unrestrained creatures in 3D at high speeds, SCAPE can capture both cellular structure and function and behavior. SCAPE can also be combined with optogenetics and other tissue manipulations during imaging because, unlike other systems, it does not require any movement of the imaging objective lens or the sample to create a 3D image.

Hillman and her students built their first SCAPE system using inexpensive off-the-shelf components. Her "aha" moment came when, looking at an old polygonal mirror in the lab, she realized how it could be used to generate SCAPE's unusual scanning geometry. After several years of trial and error, Hillman and graduate student Matthew Bouchard came up with a configuration that worked, and beautiful images started to flow out. "It wasn't until we built it that we realized it was a light-sheet microscope!" says Hillman. "It took us a while to realize how versatile the imaging geometry was, how simple and inexpensive the layout was--and just how many problems we had overcome."

Beyond neuroscience, Hillman sees many future applications of SCAPE including imaging cellular replication, function, and motion in intact tissues, 3D cell cultures, and engineered tissue constructs, as well as imaging 3D dynamics in microfluidics, and flow-cell cytometry systems--all applications where molecular biology is delivering tools and techniques, but imaging methods have struggled to keep up. Hillman also plans to explore clinical applications of SCAPE such as video-rate 3D microendoscopy and intrasurgical imaging. Next-generation versions of SCAPE are in development that will deliver even better speed, resolution, sensitivity, and penetration depth.

As a member of the new Zuckerman Institute and the Kavli Institute for Brain Science at Columbia, Hillman is working with a wide range of collaborators, including Randy Bruno (associate professor of neuroscience, Department of Neuroscience), Richard Mann (Higgins Professor of Biochemistry and Molecular Biophysics, Department of Biochemistry & Molecular Biophysics), Wesley Grueber (associate professor of physiology and cellular biophysics and of neuroscience, Department of Physiology & Cell Biophysics), and Kimara Targoff (assistant professor of pediatrics, Department of Pediatrics), all of whom are starting to use the SCAPE system in their research.

"Deciphering the functions of brain and mind demands improved methods for visualizing, monitoring, and manipulating the activity of neural circuits in natural settings," says Thomas M. Jessell, co-director of the Zuckerman Institute and Claire Tow Professor of Motor Neuron Disorders, the Department of Neuroscience and the Department of Biochemistry and Molecular Biophysics at Columbia. "Hillman's sophistication in optical physics has led her to develop a new imaging technique that permits large-scale detection of neuronal firing in three-dimensional brain tissues. This methodological advance offers the potential to unlock the secrets of brain activity in ways barely imaginable a few years ago."

Hillman's technology is available for licensing from Columbia Technology Ventures and has already attracted interest from multiple companies.

RELATED LINKS

Columbia University Medical Center (CUMC)
Nature Photonics
Imaging Neurons While New Memories Are Formed Using mRNA Display and Microscopic FingRs Probes
Visualizing Zebrafish Brain Activity - How Fish Think
Virtual Nanoscopy Enables Large Scale Composite Images
MIT News: Researchers Improve Electron Microscopy Using Engineered Protein Labels
New Advancements In DNA Nanotechnology Lead To Development of Practical Applications
Cutting Graphene With Precision Using Nanorobots and Atomic Force Microscope Discovered
Imaging The Process of How Blood Stem Cells Take Root
Michigan Technological University Research on Nanostructured Anode Materials in Lithium Ion Batteries
To Commemorate 2012 London Olympics, Smallest Five Ringed Structure Olympicene Produced and Imaged
Studying the Inner Structure of Mitochondria Results in Discovery of Mitochondrial RNA Granules