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Listening to cancer cells for drug discovery

Mar 2011
BioPhotonics staff

Researchers are making strides in the field of drug discovery, thanks to holography and lasers. They are now able to detect motion inside three-dimensional tumor spheroids that could show how various drug candidates affect intracellular structures.

Researchers at Purdue University have developed holographic tissue dynamics spectroscopy, a technique to measure the living motion inside a cell and to determine the cell’s response to applied drugs. The technology was highlighted in a letter in the Journal of Biomedical Optics.

The spectrogram shows how cells react to drugs; for instance, when they interact with a metabolic drug (iodo-acetate) in comparison to an antimitosis drug (cytochalasin). Courtesy of David D. Nolte, Purdue University

The scientists were able to view a tumor’s tissues in three dimensions using holography. Using the holographic technique with lasers allows them to see the tumor’s interior as well as its surface. Like polarized sunglasses, the approach cancels the effect of any light scattered by skin and tissues, uncovering the image-bearing light that is already there. Images similar to voiceprints used in voice recognition security software are left that can show changes taking place within the cells.

Upon completion of the hologram, the researchers use fluctuation spectroscopy to measure time-dependent changes within the hologram. They measure the frequency of light fluctuations as a function of time after a drug has been administered. The resulting spectrogram represents a voiceprint of the drug used on the cells, enabling drug researchers and manufacturers to see how various drug candidates affect organlike structures within a cell.

With its high throughput, the technology will soon allow manufacturers to more quickly determine which drugs are most effective in battling tumors and other tissue diseases.

An interference pattern that is recorded on a high-resolution plate, the two interfering beams formed by a coherent beam from a laser and light scattered by an object. If after processing, the plate is viewed correctly by monochromatic light, a three-dimensional image of the object is seen.
The optical recording of the object wave formed by the resulting interference pattern of two mutually coherent component light beams. In the holographic process, a coherent beam first is split into two component beams, one of which irradiates the object, the second of which irradiates a recording medium. The diffraction or scattering of the first wave by the object forms the object wave that proceeds to and interferes with the second coherent beam, or reference wave at the medium. The resulting...
With respect to light radiation, the restriction of the vibrations of the magnetic or electric field vector to a single plane. In a beam of electromagnetic radiation, the polarization direction is the direction of the electric field vector (with no distinction between positive and negative as the field oscillates back and forth). The polarization vector is always in the plane at right angles to the beam direction. Near some given stationary point in space the polarization direction in the beam...
A chart formed by a spectrograph; the record of the spectral range. See spectrograph.
AmericasBiophotonicsBioScandefensedrug discoveryfluctuation spectroscopyhologramholographic tissue dynamics spectroscopyholographyIndianaNewspolarizationPurdue Universityspectrogramspectroscopytumor spheroidsvoice-recognition security softwarelasers

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