'Brain Retraining'
Gives Hope to Stroke Patients
An experimental rehabilitation technique has scientists in a cautiously optimistic mood.
Scientists debate endlessly whether we will ever really understand the workings of the mind — and every once in a while they're given reason to hope. The latest source of optimism is a study published in Friday's issue of Stroke: Journal of the American Heart Association, which shows for the first time that a new type of rehabilitation may help stroke victims regain nearly full use of their paralyzed limbs. The experimental therapy, employed by researchers at the University of Alabama and the Friedrich Schiller University in Germany, involves immobilizing the good arm of a stroke victim and forcing the patient to use their "bad" arm to perform daily tasks. Patients performed the exercises six hours a day for two weeks.
When the course of therapy was complete, a brain scan indicated renewed muscle activity in the paralyzed limb — a finding that seems to vindicate scientists' previous theory that the brain can, in fact, be actively rewired. "For years there's been hope that you can retrain the brain," says TIME medical correspondent Christine Gorman. As our understanding of the brain becomes more sophisticated, Gorman explains, we get further from the erroneous idea that the brain is static, or fixed. "Now we know that tasks like learning a language or playing a new instrument change the brain," Gorman says. And although the stroke therapy remains experimental, it offers renewed hope for even more dramatic and practical discoveries down the road.
The new medicine has fundamentally changed how we think about disease. Instead of devising ways to treat illnesses, scientists conduct genetic manipulations that could eliminate problems entirely. What's a reality, is where the science is going, offers wonderful possibilities.
http://www.nytimes.com/library/national/science/health/060200hth-brain-stroke.html
Date: Posted 6/2/2000
Science Authors Report
Adult Stem Cells Can Produce A Wealth Of Cell Types
Washington D.C. -- Reprogrammed adult neural stem cells can potentially generate a cornucopia of cell types-giving rise to cells in heart, liver, muscle, intestine and other tissues, a 2 June Science study suggests.
When adult neural stem cells from mice are grown with embryonic cells or within an embryo, the adult stem cells can revert to an unspecialized state and give rise to different cell lineages, according to the Science study. The research, completed by a team of Swedish scientists, adds to a growing body of data indicating that adult stem cells, like embryonic stem cells, may be more versatile than previously assumed.
Embryonic stem cells are the "blank slates" of an organism, capable of developing into all types of tissue in the body. Scientists have long been interested in the therapeutic potential of embryonic stem cells, which may be used someday to create new tissues for organ transplants and replacements for cells destroyed by diseases like diabetes or trauma like spinal cord injuries.
As ethical and legal controversy threatens to cloud the future of embryonic stem cell research, however, some scientists have turned to adult stem cells to discover whether they also have the same open-ended potential. Until recently, researchers thought that the more specialized adult stem cells, found in areas of the body like the skin, nervous system, and blood and lymph systems, could only give rise to their own kind. Now, scientists are accumulating evidence--including last year's mouse study showing how brain stem cells transplanted into bone marrow could produce blood cells (see Science, 22 January 1999)--that adult stem cells may be capable of reprogramming themselves.
The Science study confirms that adult stem cells are in fact more chameleon-like than previously suspected, taking cues from their cellular environment to produce offspring of the same type as the cells that surround them. To test the influence of environment on adult stem cell destiny, the Swedish team exposed genetically tagged mouse neural stem cells to a variety of tissue types by growing them together with embryo cell cultures in the lab and injecting them into early-stage chick and mouse embryos.
In the lab cultures, the offspring of the stem cells switched their identities to become muscle cells. Depending on which early cell layer they managed to infiltrate in the developing chick and mouse, the stem cell progeny incorporated into these embryos contributed to heart, lung, intestine, kidney, liver, nervous system, and other tissues.
As the researchers discovered, even lone neural adult stem cells displayed this ability to differentiate themselves into various cell types. In all these cases, the cells looked and acted just like the host cells around them. The "most striking indications" of this complete cellular makeover, say the authors, were the apparently normal and beating embryonic mouse hearts containing very large amounts of these derived stem cells.
Although the scientists are certain that environment plays a major role in determining an adult stem cell's fate, they aren't entirely sure what critical factor environment supplies.
"The short answer is that we have no clue," says co-author Jonas Frisén of the Karolinska Institute in Stockholm. "We can speculate that the crucial elements are extracellular signals, or secretions from the embryonic cells. There is probably a cocktail of various factors involved, but we have no solid data yet about what these molecules are."
If scientists can determine the molecular composition of these extracellular signals, Frisén says, researchers could take the next step and coax these adult stem cells toward several different cellular lineages, without exposing them to embryonic cells at all.
Frisén and colleagues want to test other types of adult stem cells, not just neural cells, to see if they have similarly plastic potential.
"This could be very valuable in a clinical setting, since neural stem cells are really the least accessible," says Frisén.
The research team is also planning future experiments to see how long the transformed stem cells survive within these tissues, and whether they retain their new commitments indefinitely.
Note: This story has been adapted from a news release issued by American Association For The Advancement Of Science for journalists and other members of the public. If you wish to quote from any part of this story, please credit American Association For The Advancement Of Science as the original source. You may also wish to include the following link in any citation: http://www.sciencedaily.com/releases/2000/06/000602072837.htm
Science News / HowComYouCom.com
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