By blending optical and atomic force microscope technologies, Iowa State
University and Ames Laboratory researchers have found a way to complete
3-D measurements of single biological molecules with unprecedented
accuracy and precision.
Existing technologies allow researchers to measure single molecules
on the x and y axes of a 2-D plane. The new technology allows
researchers to make height measurements (the z axis) down to the
nanometer -- just a billionth of a meter -- without custom optics or
special surfaces for the samples.
"This is a completely new type of measurement that can be used to
determine the z position of molecules," said Sanjeevi Sivasankar, an
Iowa State assistant professor of physics and astronomy and an associate
of the U.S. Department of Energy's Ames Laboratory.
Details of the technology were recently published by the journal Nano Letters.
Co-authors of the study are Sivasankar; Hui Li, an Iowa State
post-doctoral research associate in physics and astronomy and an
associate of the Ames Laboratory; and Chi-Fu Yen, an Iowa State doctoral
student in electrical and computer engineering and a student associate
of the Ames Laboratory.
The project was supported by lab startup funds from Iowa State
University and a $120,075 grant from the Grow Iowa Values Fund, a state
economic development program.
Sivasankar's research program has two objectives: to learn how
biological cells adhere to each other and to develop new tools to study
those cells.
That's why the new microscope technology -- called standing wave axial nanometry (SWAN) -- was developed in Sivasankar's lab.
Here's how the technology works: Researchers attach a commercial
atomic force microscope to a single molecule fluorescence microscope.
The tip of the atomic force microscope is positioned over a focused
laser beam, creating a standing wave pattern. A molecule that has been
treated to emit light is placed within the standing wave. As the tip of
the atomic force microscope moves up and down, the fluorescence emitted
by the molecule fluctuates in a way that corresponds to its distance
from the surface. That distance can be compared to a marker on the
surface and measured.
"We can detect the height of the molecule with nanometer accuracy and precision," Sivasankar said.
The paper reports that measurements of a molecule's height are
accurate to less than a nanometer. It also reports that measurements can
be taken again and again to a precision of 3.7 nanometers.
Sivasankar's research team used fluorescent nanospheres and single
strands of DNA to calibrate, test and prove their new instrument.
Users who could benefit from the technology include medical
researchers who need high-resolution data from microscopes. Sivasankar
thinks the technology has commercial potential and is confident it will
advance his own work in single molecule biophysics.
"We hope to use this technology to move that research forward," he
said. "And in doing that, we'll continue to invent new technologies."
Journal Reference:
- Hui Li, Chi-Fu Yen, Sanjeevi Sivasankar. Fluorescence Axial Localization with Nanometer Accuracy and Precision. Nano Letters, 2012; 12 (7): 3731 DOI: 10.1021/nl301542c
Courtesy: ScienceDaily
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