It’s in the early stages, but genistein, derived from soybeans and other plants, shows promise in inhibiting the HIV infection, says Yuntao Wu, a professor with the George Mason-based National Center for Biodefense and Infectious Diseases and the Department of Molecular and Microbiology. …
This achievement shatters the previous record, setting a new benchmark for the most sensitive limit of detection, and may significantly advance early disease diagnostics. …
In a study published in the July issue of the Proceedings of the National Academy of Sciences, researchers found a missing piece of the pediatric cancer puzzle. Changxian Shen, PhD, senior research associate at the Center for Childhood Cancer and Blood Diseases at The Research Institute at Nationwide Children’s Hospital, and Peter Houghton, PhD, director of the center, may have identified one mechanism behind the early development of some pediatric solid tumors — as well as a target for future pediatric cancer therapies…
"Scientists have known that Bmi1 is a central control switch within the adult stem cells of many tissues, including the brain, blood, lung and mammary gland," said Ophir Klein, MD, PhD, who directs the Craniofacial and Mesenchymal Biology (CMB) Program and serves as chair of the Division of Craniofacial Anomalies at UCSF. "Bmi1 also is a cancer-causing gene that becomes reactivated in cancer cells." Klein’s research group now has shown that BMI1 plays another role in ensuring that the process of development unfolds normally. The hallmarks of all stem cells are that they are immature, they keep dividing to replenish their numbers almost indefinitely, and they generate new specialized cells to function in the tissues in which they reside, a process called cell differentiation. …
In the first study to test the invention in the operating theatre, the "iKnife" diagnosed tissue samples from 91 patients with 100 per cent accuracy, instantly providing information that normally takes up to half an hour to reveal using laboratory tests. The findings, by researchers at Imperial College London, are published today in the journal Science Translational Medicine. The study was funded by the National Institute for Health Research (NIHR) Imperial Biomedical Research Centre, the European Research Council and the Hungarian National Office for Research and Technology. …
The results appear online this week in the Proceedings of the National Academy of Sciences. "In demonstrating the ability to rebuild a microvascular bed in a clinically relevant manner, we have made an important step toward the construction of blood vessels for therapeutic use," says Sharon Gerecht, Ph.D., an associate professor in the Johns Hopkins University Department of Chemical and Biomolecular Engineering, Physical Sciences-Oncology Center and Institute for NanoBioTechnology. "Our findings could yield more effective treatments for patients afflicted with burns, diabetic complications and other conditions in which vasculature function is compromised." Gerecht’s research group and others had previously grown blood vessels in the laboratory using stem cells, but barriers remain to efficiently producing the vessels and using them to treat patients. For the current study, the group focused on streamlining the new growth process. …
"Most women think that if they had cancer as a child, then they’ll never have children. It turns out that many of them can get pregnant. It just might be a little harder," said senior author Lisa Diller, MD, chief medical officer of Dana-Farber/Boston Children’s and medical director of the David B…
The discovery of the cell death processes that determine the number of ‘regulatory T cells’ an individual has could one day lead to better treatments for immune disorders. Regulatory T cells are members of a group of immune cells called T cells. Most T cells actively respond to clear the body of infections. …
The technique, named cell type specific labeling using amino acid precursors (CTAP), exploits the inability of vertebrate cells to synthesize essential amino acids normally required for growth and homeostasis. The research was published online in the journal Nature Methods on June 30, 2013. This technological advance will provide investigators with a new tool for comprehensive mapping of cell-cell communication, which is important in all aspects of cancer development, maintenance, and response to therapy. For example, this method could be used to study cell signaling events between normal and malignant cells in order to better understand the molecular mechanisms by which surrounding normal cells alter tumor growth and response to treatment…
In a joint effort with the National Institutes of Health, a group of researchers from the University of Copenhagen have taken a step closer to being able to design a more effective anticancer treatment by mapping a previously unknown molecular mechanism. The group has been working with proteases, important enzymes which are responsible for maintaining different types of tissues in the body while also being involved in many -diseases, including cancer. Cancer cells can exploit an over-production of proteases to force their way into the body so they can quickly grow and create a space for themselves in which to spread. "So far, we have been unable to treat cancer patients with drugs which can effectively stop cancer cells from spreading, but having now discovered that an important function of proteases has been overlooked, we have the possibility of designing new drugs…