Scientists at Ohio State University say they've figured out a way to grow the genetic equivalent of a nearly complete embryonic human brain.
An "incredible achievement" and a "quantum leap forward" in the battle against cancer, autism, Parkinson's and Alzheimer's.
Technically,
they're not quite "brains." They're called brain organoids, pieces of
human tissue grown in petri dishes from skin cells.
These
little blobs of tissue, 2-3 millimeters long, could help researchers
test drugs and other treatments that may help prevent, fight and maybe
even cure some of the most devastating disorders and diseases of our
time.
In addition to Parkinson's
disease, autism and Alzheimer's disease, they could also lead to
unlocking the mysteries of schizophrenia, epilepsy, traumatic brain
injuries and post-traumatic stress disorder. Millions of people suffer
from all these disorders and diseases worldwide.
"The
idea of taking skin cells, reverting them back to a basic stage of
development and then teaching them how to turn into the cells that make
up the brain is something we have been dreaming about for some time,"
said CNN Chief Medical Correspondent Dr. Sanjay Gupta.
"It is
exponentially closer to reality now. Furthermore, the idea of using
these 'mini brains' as a testing ground for therapies could help doctors
figure out the best treatments for individual patients as opposed to
the 'one size fits all' approach that is often used nowadays."
Scientists have been making brain tissue organoids in the lab for less than a decade.
Japanese
scientists were among the first to prompt cells from mice and humans to
form "layered balls reminiscent" of a part of the brain called the
cerebral cortex, according to the science journal, Nature.
In 2011, Madeline Lancaster, a scientist a the Institute of Molecular
Biotechnology in Vienna, was able to grow an embryonic brain.
Ohio
State biomedical researcher Rene Anand said his team's work is
different because "our organoids have most of the brain parts."
"I'll
give you one example: If you want to study Parkinson's, you need the
mid-brain. The best I can tell from all published research on organoids
is they don't have the mid-brain. We have the mid-brain we are already
moving toward trying to study them."
Anand said he has grown organoids that include 98% of cells that exist in a brain of a human fetus at five weeks.
"I think it took all of us by surprise," Dr. Rudolph Tanzi — an Alzheimer's research pioneer at Harvard told CNN. "The results were absolutely astounding it's an incredible achievement."
Creating
a fetal brain that includes so many different types of brain cells
amounts to a "quantum leap forward," he said. Tanzi co-discovered all
three genes that cause early-onset familial Alzheimer's, according to his Harvard biography.
Anand said using the breakthrough to learn more about Alzheimer's is a "high priority" for his team.
Despite
all the excitement, Anand is quick to point out that the project is
still at a very early stage.
"The sooner we commercialize it and make a
model available, the sooner everybody else can jump in and use it to
solve these problems." Brain organoids may help researchers find key
solutions to some sub-types of autism within 10 years, Anand said.
"Right
now, it's like we're climbing Mount Everest and we're at Base Camp
One," Anand said. "You know, you have to stop, get your oxygen together,
then move up to the next step. So, we've still got a ways to go."
As you might expect, growing human brain organoids poses a lot of head-scratching questions.
Here are five big ones:
1. Does this mean scientists could grow a miniature version of your "brain?"
Sort
of. If a lab technician used some of your skin cells, they could grow
an embryonic brain organic that would have your genetic material. Could
that brain organoid be developed into a fully grown brain? No, that's
not possible yet.
A fully grown brain would need a vascular system and
other parts before it could meet the official definition of a brain.
"They are not capable of growing beyond where they are," said Anand. "We
have no intention of going beyond that."
2. Exactly how would brain organoids contribute to new treatments?
Scientists
would use them to mimic human brains deteriorating from Alzheimer's or
Parkinson's and then study how they react to innovative treatments or
newly developed drugs. "You still have to find a way to accelerate the
aging of that brain, the pathology, to mimic a disease like Alzheimer's
or Parkinson's," said Tanzi.
3. Is it possible that brain organoids are conscious?
No,
said Tanzi. Because these tissues don't have any input. "The brain
doesn't work alone. The brain needs sensory input.
The brain in a dish
is not getting sensory input. We depend on our limited sensory system
our five senses to provide input to the brain. The brain interprets
that information and integrates it.
And then we're putting everything we
experience in context based on the information that's already stored in
our brains through synapse."
4. Theoretically, could this research lead to a future with artificially intelligent machines that have humanlike brains?
It's
not out of the realm of possibility, Tanzi said. "If somebody someday
figures out how to put a brain into an AI that has sensory input now
you're creating AI hybrids with organic brains. Then, that's a whole
different story.
Then, you're talking about what's been covered in
science fiction movies. But I would say it's very far away, if at all." CONTINUE READING
CNN
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