New advanced petri dish, also called 3D scaffold, could enable doctors to get answers about the effectiveness of drugs in days or weeks.
‘Cell cultures can be used for drug testing or single cell analysis, which in turn helps to identify best treatments for a patient suffering from cancer.’
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At present, some patients have samples of their cancer cells grown in mice for drug testing and analysis, but the cancer cells don't always grow and the process takes months, Luker said. Read More..
An advanced petri dish, known as a 3D scaffold, could enable doctors to get answers about the effectiveness of drugs in days or weeks. But earlier scaffolds, trying to mimic the structure and composition of the gel-like network that binds a collection of cells into a tissue, also have mixed records.
"Rather than trying to guess at what the tumor cells' microenvironment ought to be, we've made a space where they can create their own cell niche, as they do in the body," said Stacy Jordahl, a recent chemical engineering Ph.D. graduate from U-M and first author on the paper in Advanced Materials.
Preserving a Young Cancer Patient�s Fertility With Cell Culture System
New method to preserve boy cancer patient’s fertility has been developed at American Associates, Ben-Gurion University of The Negev. This study may open the way for new therapeutic strategies for fertility preservation of prepubertal cancer patient boys (PCPBs).
New method to preserve boy cancer patient’s fertility has been developed at American Associates, Ben-Gurion University of The Negev. This study may open the way for new therapeutic strategies for fertility preservation of prepubertal cancer patient boys (PCPBs).
While researchers have used layers of balled-up fibronectin to help cells to attach to previous scaffolds, the protein hasn't been used to full advantage.
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Led by Joerg Lahann, the Wolfgang Pauli Collegiate Professor of Chemical Engineering and director of the Biointerfaces Institute at U-M, the engineers built a grid of microscale cubicles, each half a millimeter to a side.
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"With this engineered way to draw proteins into a network of fibers, we can produce a more natural environment for growing cancer cell cultures that enable us to test drugs or understand cancer biology," Lahann said.
Lahann's team turned the structures over to two cancer researchers, Luker and Max Wicha, the Madeline and Sidney Forbes Professor of Oncology. They used the structures to culture cells that had been removed from breast cancer patients by draining fluid pockets that can accumulate in the abdomen and chest as the disease progresses.
Although cancer cells represent only about 5% of the cells in these fluids, they dominated the cell population after a few days to a week on the fibronectin network. And the cancer researchers were impressed.
"There have been a lot of technologies and approaches devised to try to grow cancer cells in culture that haven't worked so well. Most cancer cells die out when cultured in artificial conditions," Luker said. "In this system, we could pretty consistently grow out the cultures at least for short periods of time."
In addition, the cells seemed to change as they grew on the fibronectin network, becoming more like the kind of cells that are believed to spread cancer to other parts of the body. This could be an advantage for testing cancer drugs, as those cells are most imperative to kill.
However, this bias would hinder experiments exploring cancer biology--for instance, identifying the influences that lead cells to become more aggressive or benign. In the future, the team may investigate whether changes to the way the fibronectin network is structured can remove this bias.
Source-Eurekalert
