News & Events
Clarkson University Professors' Cancer Cell Research Published in Top Nanotechology Journal
[A photograph for media use is available at http://www.clarkson.edu/news/photos/cancer-cells.jpg]
A group of Clarkson University researchers led by Nanoengineering and Biotechnology Laboratories Center (NABLAB) Director Igor Sokolov has discovered a previously unknown feature that distinguishes cancer from normal cells: the difference in cell surface properties.
The research was published this week in the advance online publication of the elite scientific journal Nature Nanotechnology -- rated the number one journal in nanotechnology by its impact index. The research will also be published in an upcoming print edition.
In the paper "Atomic Force Microscopy Detects Differences in the Surface Brush of Normal and Cancerous Cells," the authors have identified a critical difference between the surface properties of normal and cancer cells: variation in brushes or tiny "hairs" that cover the cell surface.
The results imply that the brush layer cannot be ignored as was previously done when characterizing cells by mechanical methods. The authors suggest that the difference in the brush layers may have a biological significance, and can be used for detection of cancer.
Brushes on the cell surface, mostly consisting of microridges and tiny hairs called microvilli, are important for interacting with the external environment. Sokolov and his colleagues processed force measurements - taken from the cell surface using an atomic force microscope - according to a model that accounts for these brushes, to quantitatively show that cancerous cells are different. Normal cells have brushes of one length, whereas cancerous cells have mostly two brush lengths of significantly different densities.
The study is done with the help of a physical instrument, the atomic force microscope, which is not a conventional tool for biological research. As a result, the differences found were outside of what is conventionally measured in biology.
"Cancer cells are traditionally detected by biochemical means," says Sokolov. "However, despite many years of success, those methods have not resulted in defeating cancer. Therefore it is very important to search for alternative, nontraditional ways of looking at cancer. Investigation of the physical properties of cell surfaces might be one such nontraditional way."
The authors also demonstrated that the difference found in cell surface "brush" is practically impossible to find with other microscopic methods.
The research group consists of Sokolov, professor of physics and chemical & biomolecular science; Craig D. Woodworth, professor of biology; Swaminathan Iyer, a physics postdoctoral fellow; and Ravi M. Gaikwad and Venkatesh Subba-Rao, both physics graduate students.
This is the second paper published in a top scientific journal on the work done within NABLAB.
The paper can be found on the Nature Web site at http://www.nature.com/nnano/journal/vaop/ncurrent/abs/nnano.2009.77.html .
Clarkson University launches leaders into the global economy. One in six alumni already leads as a CEO, VP or equivalent senior executive of a company. Located just outside the Adirondack Park in Potsdam, N.Y., Clarkson is a nationally recognized research university for undergraduates with select graduate programs in signature areas of academic excellence directed toward the world's pressing issues. Through 50 rigorous programs of study in engineering, business, arts, sciences and health sciences, the entire learning-living community spans boundaries across disciplines, nations and cultures to build powers of observation, challenge the status quo, and connect discovery and engineering innovation with enterprise.
Photo caption: A group of Clarkson University researchers have discovered a previously unknown feature that distinguishes cancer from normal cells. Above, a rendering shows the spherical probe of an atomic-force microscope touching human epithelial cervical cancers cells. One can clearly see the "brushy" surface of the cells.