The good news is that we are now
learning how to inject useful cells into the brain itself allowing the original
promise of stem cell therapy to be met.
The early going suggests that it works enough to plausibly stabilize the
disease.
This has been advanced rather
quickly and I suspect application to patients will be sooner rather than later. Those patients are suffering from a death
sentence and just halting the progress of the disease is a huge boon. Reversing it will recover functionality and
again allow a useful life. Yet this is
not a cure so much as a damage management program. We will still take it.
It is one disease that has taken
two of my friends with whom I worked closely and I would like to see any
progress sped into the clinics. It may
not take your mind like Alzheimer’s but it certainly is your ever present friend
preventing a proper life.
New Method for Making Neurons Reverses Parkinsons in Rats and tests are
proceeding on Monkeys
NOVEMBER 07, 2011
Technology Review - A new method of synthesizing
dopamine-producing neurons, the predominant type of brain cell destroyed in
Parkinson's, offers hope for creating cell-replacement therapies that
reverse the damage.
The method provides an efficient way of making functional cells. When
transplanted into mice and rats with brain damage and movement problems similar
to Parkinson's, the cells integrated into the brain and worked normally,
reversing the animals' motor issues.
In the new study, researchers started with human embryonic stem cells, which by definition can differentiate into any cell type. To make a specific type of cell in high numbers, scientists expose the stem cells to a cocktail of chemicals that mimic what they would experience during normal development.
Studer's team found a way to make these cells even more efficiently. This is significant in terms of ultimately testing the therapy in humans; many methods for making specific types of cells are complex and yield small amounts of the desired product.
They could scale up the process to make enough material to transplant into monkeys, whose larger brains are more akin to humans' than other animals used in testing.
In addition, the researchers demonstrated that transplants of the cells could correct Parkinson's-like problems in mice and rats. Three different tests of motor function "all very dramatically improved when you put the cells in," says Studer.
While the two monkeys in the study also had brain damage reminiscent of Parkinson's, not enough time has passed to determine whether the transplants will help, Studer says. It took five months post-transplant for the cells to have a visible effect in rodents.
The findings demonstrate the challenges of developing treatments based on living cells. "Previously, I think many people thought of cell therapy [for Parkinson's] as a dopamine-producing biological pump," says Ole Isacson, a neuroscientist at
Researchers mostly used embryonic stem cells in these experiments, because tissue derived from these cells is already being used in human trials for treating spinal cord injury and certain types of blindness. They also showed that the protocol works on induced pluripotent stem (iPS) cells, which are derived from adult cells that are turned back to an embryonic-like state using a combination of genetic or chemical factors. iPS are genetically matched to the cell donor, and might ultimately provide a preferable source of tissue for therapy. However, these cells are further from human testing because they are much less studied than embryonic cells.
Studer's team now plans to make the cells on an even larger scale in a facility that meets conditions set by the
Revamping the brain: Human dopamine-producing cells (marked in red and green) survive and function when transplanted into the brain of rats with brain damage that resembles Parkinson’s disease.
New Method for Making Neurons Could Lead to Parkinson's Treatment
When transplanted into rodents with brain damage similar to
Parkinson's, the cells reversed the animals' motor issues.
MONDAY, NOVEMBER 7, 2011
BY EMILY SINGER
A new method of synthesizing dopamine-producing neurons, the predominant
type of brain cell destroyed in Parkinson's, offers hope for creating
cell-replacement therapies that reverse the damage.
The method provides an efficient way of making functional cells. When
transplanted into mice and rats with brain damage and movement problems similar
to Parkinson's, the cells integrated into the brain and worked normally,
reversing the animals' motor issues.
The finding brings researchers a step closer to testing a
stem-cell-derived therapy in patients with this disorder. "We finally have
a cell that seems to survive and function and a cell source that we can easily
scale up," says Lorenz Studer, a researcher at the Sloan Kettering
Institute and senior author on the new study. "That makes us optimistic
that this could potentially be used in patients in the future."
The research also highlights the challenges of generating cells for
tissue-replacement therapy, showing that subtle differences in the way the
cells are made can have a huge impact on how well they work once implanted.
Many of the symptoms of Parkinson's
disease—which include tremor, muscle rigidity, and loss of balance—are linked
to loss of dopamine in the brain. While medications exist to replace some of
the lost chemical, they do not alleviate all of the symptoms and can lose their
effectiveness over time. Scientists hope that replacing lost cells with new
ones will provide a more complete and long-term solution.
In the new study, researchers started with human embryonic stem cells,
which by definition can differentiate into any cell type. To make a specific
type of cell in high numbers, scientists expose the stem cells to a cocktail of
chemicals that mimic what they would experience during normal development.
While stem-cell researchers had previously been able to create
dopamine-producing neurons from human stem cells, these cells did little to
alleviate movement problems in animals engineered to mimic the symptoms of
Parkinson's. In 2009, Studer and others developed a method of making the cells
that more closely mimics the way they form during development. The resulting
cells also carry more of the molecular markers that characterize
dopamine-producing cells in the brain.
In the new research, published Sunday in the journal Nature,
Studer's team found a way to make these cells even more efficiently. This is
significant in terms of ultimately testing the therapy in humans; many methods
for making specific types of cells are complex and yield small amounts of the
desired product.
They could scale up the process to make enough material to transplant
into monkeys, whose larger brains are more akin to humans' than other animals
used in testing.
In addition, the researchers demonstrated that transplants of the cells
could correct Parkinson's-like problems in mice and rats. Three different tests
of motor function "all very dramatically improved when you put the cells
in," says Studer.
While the two monkeys in the study also had brain damage reminiscent of
Parkinson's, not enough time has passed to determine whether the transplants
will help, Studer says. It took five months post-transplant for the cells to
have a visible effect in rodents.
The findings demonstrate the challenges of developing treatments based
on living cells. "Previously, I think, many people thought of cell therapy
[for Parkinson's] as a dopamine-producing biological pump," says Ole Isacson,
a neuroscientist at Harvard
Medical School .
But in reality, it requires a very specific replacement of nerve cells. Unless
you have a specific differentiation protocol, you won't get functional recovery
in rodent models." Isacson was not involved in the research but has
collaborated with Studer on other projects.
Researchers mostly used embryonic stem cells in these experiments,
because tissue derived from these cells is already being used in human trials for
treating spinal cord injury and certain types of blindness. They also
showed that the protocol works on induced pluripotent stem (iPS) cells, which
are derived from adult cells that are turned back to an embryonic-like state
using a combination of genetic or chemical factors. iPS cells are genetically
matched to the cell donor, and might ultimately provide a preferable source of
tissue for therapy. However, these cells are further from human testing because
they are much less studied than embryonic cells.
Studer's team now plans to make the cells on an even larger scale in a
facility that meets conditions set by the U.S. Food and Drug Administration
for human therapies. "We need to be able make enough cells to graft 100
patients," says Studer. He predicts that will take a year or two, followed
by extensive safety testing to make sure the differentiated cells do not behave
in unexpected ways once implanted.
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Thank you for sharing this post.. Many people would be unaware about this treatment.. parkinson's stem cell therapy
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