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SAN FRANCISCO, Feb. 20 (Xinhua) -- Tiny nanostraws developed by researchers with Stanford University offer a method of sampling cell contents without disrupting its natural processes.
Cells within human bodies divide and change over time, with thousands of chemical reactions occurring within each cell daily. While this makes it difficult for researchers to understand what's happening inside, a problem with the current method of cell sampling, called lysing, is that it ruptures the cell. Once the cell is destroyed, it can't be sampled from again.
Relying on tiny tubes 600 times smaller than a strand of hair that allow researchers to sample a single cell at a time, the nanostraws in the new Nanostraw Extraction (NEX) sampling system penetrate a cell's outer membrane, without damaging it, and draw out proteins and genetic material from the cell's salty interior.
"It's like a blood draw for the cell," said Nicholas Melosh, an associate professor of materials science and engineering and senior author on a paper describing the work published in Proceedings of the National Academy of Sciences.
In human bodies, cells are connected by a system of "gates" through which they send each other nutrients and molecules, like rooms in a house connected by doorways. These intercellular gates, called gap junctions, are what inspired Melosh six years ago, when he was trying to determine a non-destructive way of delivering substances, like DNA or medicines, inside cells.
The NEX sampling system is the reverse, observing what's happening within rather than delivering something new. "What we hope to do, using this technology, is to watch as these cells change over time and be able to infer how different environmental conditions and 'chemical cocktails' influence their development - to help optimize the therapy process," Melosh was quoted as saying in a news release from Stanford on Monday.
In building the NEX system, Melosh and his team needed to ensure cell sampling with this method was possible, and to see that the samples were actually a reliable measure of the cell content, and that samples, when taken over time, remained consistent.
When the team compared their cell samples from the NEX with cell samples taken by breaking the cells open, they found that 90 percent of the samples were congruous, and that when they sampled from a group of cells day after day, certain molecules that should be present at constant levels remained the same, indicating that their sampling accurately reflected the cell's interior.
They tested the NEX sampling method not only with generic cell lines, but also with human heart tissue and brain cells grown from stem cells. In each case, the nanostraw sampling reflected the same cellular contents as lysing the cells.
The goal of developing this technology, according to Melosh, was to make an impact in medical biology by providing a platform that any lab could build.
If researchers can fully understand how a cell works, then they can develop treatments that will address those processes directly. For example, in the case of stem cells, researchers are uncovering ways of growing entire, patient-specific organs. The trick is, they don't really know how stem cells develop.
"For stem cells, we know that they can turn into many other cell types, but we do not know the evolution - how do they go from stem cells to, say, cardiac cells? There is always a mystery. This sampling technique will give us a clearer idea of how it's done," said Yuhong Cao, a graduate student and first author on the paper.
The sampling technique could also inform cancer treatments and answer questions about why some cancer cells are resistant to chemotherapy while others are not.
"With chemotherapy, there are always cells that are resistant," said Cao. "If we can follow the intercellular mechanism of the surviving cells, we can know, genetically, its response to the drug."
