New device packs power to analyze genes, proteins at patients' bedside

August 30, 2010

University of Florida researchers have helped to develop a device that quickly identifies genes and proteins in body fluids -- a technique that could make a vital difference to the trauma patients doctors treat.

In a study published online Sunday in the September issue of , scientists describe how they developed and tested a new way to isolate cells from patient samples and analyze them to help predict outcomes after severe trauma. The technology, called a microfluidic cassette, allows precise analysis of very small volumes of fluids and can be used to study patients’ genes and proteins.

“What’s so powerful about this technique is that you can isolate any cell population quickly and efficiently at the bedside,” said Lyle L. Moldawer, a professor and vice chairman of research in the UF College of Medicine’s department of surgery. “In this case we isolated blood neutrophils, but we’ve also isolated , mixed leukocytes, monocytes. Theoretically, you can isolate any , under any disease, and rapidly get to produce a genomic signature.”

Knowing the genomic signature of a can help doctors diagnose diseases and may allow them to predict how individual patients will respond to trauma and what treatments to order. The approach also could be used with patients who have cancer or other conditions.

Moldawer, a co-author of the paper who also directs the department’s Laboratory of Inflammation Biology and Surgical Science, said the team that developed and tested the cassette did so to isolate neutrophils, the first type of white blood cell on the scene of an infection, and to analyze the proteins they produce. These proteins indicate how genes that regulate the immune system respond to trauma, which may allow health-care providers to quickly identify patients more likely to develop serious complications.

The device was constructed by a team at Massachusetts General Hospital and sent to UF for initial testing, spearheaded by Dr. Elizabeth Warner, a surgical resident researcher and a co-author of the paper. Scientists from several other institutions, including Stanford University, the University of Rochester, the University of Washington, Pacific Northwest National Laboratory, Harvard University and Washington University in St. Louis also co-authored the paper.

The institutions are participants in the “Glue Grant” program set up by the National Institute of General Medical Sciences, and members of the “Inflammation and the Host Response to Injury” consortium.

Previous devices required 4 to 8 milliliters of fluids, the work of a highly skilled technician and several hours to complete analysis.

“We’re getting 100 nanograms of RNA with 0.15 (milliliters) of blood and we’re doing it all in 30 minutes,” said Kenneth Kotz, a research fellow in the department of surgery at Massachusetts General Hospital. “No one’s really ever been able to do this for neutrophils. No one’s been able to demonstrate the speed and the sample quality with these small blood volumes.”

Kotz built the device, which is laced with antibodies that capture the individual cells when a sample of fluid, such as blood or urine, is pumped through it. Nucleic acids or proteins from the cells are then extracted from the cassette, allowing researchers to analyze how specific genes are expressed.

Testing showed the device yielded pure samples of , and their gene expression pattern was consistent with results from tests performed in previous studies.

“We’ve identified 63 genes that are differentially expressed,” Moldawer said, “so that when you are admitted to the emergency room after severe trauma, we can hopefully tell with better certainty whether you’re going to have a good or bad outcome (by looking at these genes).”

The genes in question regulate functions of the immune system. Patients whose expression of these genes is abnormal, he said, are less likely to return to their normal immune function within days of trauma, as most patients do. This leaves them more vulnerable to infections and a myriad of related complications.

“There’s tremendous genetic variation among people, so you can’t expect patients to react the same way,” said Bernard Brownstein, a senior research scientist in the department of anesthesiology at Washington University in St. Louis and a co-author of the journal article. “They don’t all react the same way to the same kinds of trauma.

“You end up doing what you know works for the average person, whereas what you’d like to do is get a sample of that person’s blood” to determine which course of treatment would work best for the specific patient, he said.

The new microfluidic device will allow providers to do just that.

“As the cost for doing the gene expression and proteomics comes down and is more automated, this will be a very cost-effective means that opens the way for diagnosis of disease and pointing toward particular therapies,” said Dr. Richard Hotchkiss, a professor of anesthesiology at the Washington University School of Medicine in St. Louis. Hotchkiss is not a member of the Glue Grant team and was not involved in development or testing of the device.

Explore further: Gene chip technology shows potential for identifying life-threatening blood infection

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