Cell-detection system promising for medical research, diagnostics


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Researchers are developing a system that uses tiny magnetic beads to quickly detect rare types of cancer cells circulating in a patient’s blood, an advance that could help medical doctors diagnose cancer earlier than now possible and monitor how well a patient is responding to therapy.
While other researchers have used magnetic beads for similar applications, the new high-throughput system has the ability to quickly process and analyze large volumes of blood or other fluids, said Cagri Savran, an assoc. prof. of mechanical engineering at Purdue Univ.
He is working with oncologists at the Indiana Univ. School of Medicine to further develop the technology, which recently was highlighted in Lab on a Chip.
The approach combines two techniques: immunomagnetic separation and microfluidics. In immunomagnetic separation, magnetic beads about a micron in diameter are “functionalized,” or coated with antibodies that recognize and attach to antigens on the surface of target cells.
The researchers functionalized the beads to recognize breast cancer and lung cancer cells in laboratory cultures.
“We were able to detect cancer cells with up to a 90% yield,” said Savran, working with Purdue postdoctoral fellow Chun-Li Chang and medical researchers Shadia Jalal and Daniela E. Matei from the IU School of Medicine’s Dept. of Medicine. “We expect this system to be useful in a wide variety of settings, including detection of rare cells for clinical applications.”
Previous systems using immunomagnetic separation to isolate cells required that the cells then be transferred to another system to be identified, counted and studied.
“What’s new here is that we’ve built a system that can perform all of these steps on one chip,” said Savran, also an assoc. prof. of biomedical engineering. “It both separates cells and also places them on a chip surface so you can count them and study them with a microscope.”
Another innovation is the fast processing, he said. Other “microfluidic” chips are unable to quickly process large volumes of fluid because they rely on extremely narrow channels, which restrict fluid flow.
“The circulating cancer cells are difficult to detect because very few of them are contained in blood,” Savran said. “That means you have to use as many magnetic beads as practically possible to quickly screen and process a relatively large sample, or you won’t find these cells.”
The new design passes the fluid through a chamber that allows for faster flow; a standard 7.5-mL fluid sample can run through the system in a matter of minutes.
The Purdue portion of the research is based at the Birck Nanotechnology Center in Purdue’s Discovery Park.
The beads are directed by a magnetic field to a silicon mesh containing holes 8 um in diameter. Because the target cells are so sparse, many of the beads fail to attract any and pass through the silicon mesh. The beads that have attached to cells are too large to pass through the holes in the mesh.
If needed, the cells can quickly be flushed from the system for further analysis simply by turning off the magnetic field.
“Not only can the cells be readily retrieved for further usage, the chip can be re-used for subsequent experiments,” Savran said.
The technology also could be used to cull other types of cells.
“This is not only for cancer applications,” he said.

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