Search Menu
Photonics Media Photonics Buyers' Guide Photonics EDU Photonics Spectra BioPhotonics EuroPhotonics Vision Spectra Photonics Showcase Photonics ProdSpec Photonics Handbook
More News

1st Live Cell Imaged in 3-D

Facebook Twitter LinkedIn Email Comments
CAMBRIDGE, Mass., Aug. 14, 2007 -- A new imaging technique similar to the computed tomography (CT) scans doctors use to see inside the body has allowed the creation of the first 3-D images of a living cell.

The technique could be used to produce the most detailed images yet of what goes on inside a living cell without the help of fluorescent markers or other externally added contrast agents, said Michael Feld, director of the Massachusetts Institute of Technology's George R. Harrison Spectroscopy Laboratory and a professor of physics.

“Accomplishing this has been my dream, and a goal of our laboratory, for several years,” said Feld, senior author of a paper on the research published in the Aug. 12 online edition of Nature Methods. “For the first time the functional activities of living cells can be studied in their native state.”
Left to right: Principal research scientist Kamran Badizadegan, postdoctoral associate Wonshik Choi, and Michael Feld, physics professor and director of the MIT spectroscopy lab. They have found a way to create 3-D images of the inner workings of cells. (Photo: Donna Coveney)
Using the new technique, his team has created 3-D images of cervical cancer cells, showing internal cell structures. They've also imaged C. elegans, a small worm, as well as several other cell types.

The researchers based their technique on the same concept used to create 3-D CT images of the human body, which allow doctors to diagnose and treat medical conditions. CT images are generated by combining a series of two-dimensional x-ray images taken as the x-ray source rotates around the object.

“You can reconstruct a 3-D representation of an object from multiple images taken from multiple directions,” said Wonshik Choi, lead author of the paper and a spectroscopy lab postdoctoral associate.

Cells don't absorb much visible light, so the researchers instead created their images by taking advantage of a property known as refractive index. Every material has a well-defined refractive index, which is a measure of how much the speed of light is reduced as it passes through the material. The higher the index, the slower the light travels.

The researchers made their measurements using a technique known as interferometry, in which a lightwave passing through a cell is compared with a reference wave that doesn't pass through it. A 2-D image containing information about refractive index is thus obtained.
Images of a cervical cancer cell taken using a new imaging technique developed at MIT. Figures a and b show 3-D images of the cell. The green structures represent the nucleolus. The nucleus, not visible in these images, surrounds the nucleolus. The red areas are unidentified cell organelles. Figures c through h show the 2-D images from which the 3-D ones were generated. In these images, each color represents a different range of refractive index. (Images courtesy Michael Feld laboratory, MIT)
To create a 3-D image, the researchers combined 100 2-D images taken from different angles. The resulting images are essentially 3-D maps of the refractive index of the cell's organelles. The entire process took about 10 seconds, but the researchers recently reduced this time to 0.1 seconds.

The team's image of a cervical cancer cell reveals the cell nucleus, the nucleolus and a number of smaller organelles in the cytoplasm. The researchers are currently in the process of better characterizing these organelles by combining the technique with fluorescence microscopy and other techniques.

“One key advantage of the new technique is that it can be used to study live cells without any preparation,” said Kamran Badizadegan, principal research scientist in the spectroscopy lab and assistant professor of pathology at Harvard Medical School, and one of the authors of the paper. With essentially all other 3-D imaging techniques, the samples must be fixed with chemicals, frozen, stained with dyes, metallized or otherwise processed to provide detailed structural information.

“When you fix the cells, you can't look at their movements, and when you add external contrast agents you can never be sure that you haven't somehow interfered with normal cellular function,” Badizadegan said. 
A 3-D image of the nematode C. elegans, taken using a new imaging technique developed at MIT. The scale bar (lower left) is 50 µm. (Image courtesy Michael Feld laboratory, MIT)
The current resolution of the new technique is about 500 nanometers, or billionths of a meter, but the team is working on improving the resolution. “We are confident that we can attain 150 nanometers, and perhaps higher resolution is possible,” Feld said. “We expect this new technique to serve as a complement to electron microscopy, which has a resolution of approximately 10 nanometers.”

Other authors on the paper are Christopher Fang-Yen, a former postdoctoral associate; graduate students Seungeun Oh and Niyom Lue; and Ramachandra Dasari, principal research scientist at the spectroscopy lab.

The research was conducted at MIT's Laser Biomedical Research Center and funded by the National Institutes of Health and Hamamatsu Corp.

For more information, visit:
Aug 2007
1. A single unit in a device for changing radiant energy to electrical energy or for controlling current flow in a circuit. 2. A single unit in a device whose resistance varies with radiant energy. 3. A single unit of a battery, primary or secondary, for converting chemical energy into electrical energy. 4. A simple unit of storage in a computer. 5. A limited region of space. 6. Part of a lens barrel holding one or more lenses.
fluorescence microscopy
Observation of samples using excitation produced fluorescence. A sample is placed within the excitation laser and the plane of observation is scanned. Emitted photons from the sample are filtered by a long pass dichroic optic and are detected and recorded for digital image reproduction.
In optics, an image is the reconstruction of light rays from a source or object when light from that source or object is passed through a system of optics and onto an image forming plane. Light rays passing through an optical system tend to either converge (real image) or diverge (virtual image) to a plane (also called the image plane) in which a visual reproduction of the object is formed. This reconstructed pictorial representation of the object is called an image.
Electromagnetic radiation detectable by the eye, ranging in wavelength from about 400 to 750 nm. In photonic applications light can be considered to cover the nonvisible portion of the spectrum which includes the ultraviolet and the infrared.
The technology of generating and harnessing light and other forms of radiant energy whose quantum unit is the photon. The science includes light emission, transmission, deflection, amplification and detection by optical components and instruments, lasers and other light sources, fiber optics, electro-optical instrumentation, related hardware and electronics, and sophisticated systems. The range of applications of photonics extends from energy generation to detection to communications and...
2-D3-DbiomedicalBiophotonicsC. elegansCellcervical cancerchemicalscomputer tomographyCTelectron microscopyfluorescence microscopyimageimaginginterferometersKamran BadizadeganlightMichael FeldMicroscopyMITnanoNews & Featuresorganellesphotonicsrefractive indexspectroscopywormx-raylasers

back to top
Facebook Twitter Instagram LinkedIn YouTube RSS
©2019 Photonics Media, 100 West St., Pittsfield, MA, 01201 USA,

Photonics Media, Laurin Publishing
x We deliver – right to your inbox. Subscribe FREE to our newsletters.
We use cookies to improve user experience and analyze our website traffic as stated in our Privacy Policy. By using this website, you agree to the use of cookies unless you have disabled them.