Will future computers run on human brain cells?
Johns Hopkins University
The team outlines their plan for "organoid
intelligence" today in the journal Frontiers in Science.
"Computing and artificial intelligence have been driving the technology revolution but they are reaching a ceiling," said Thomas Hartung, a professor of environmental health sciences at the Johns Hopkins Bloomberg School of Public Health and Whiting School of Engineering who is spearheading the work.
"Biocomputing is an enormous effort of compacting
computational power and increasing its efficiency to push past our current
technological limits."
For nearly two decades scientists have used tiny organoids, lab-grown tissue resembling fully grown organs, to experiment on kidneys, lungs, and other organs without resorting to human or animal testing.
More
recently Hartung and colleagues at Johns Hopkins have been working with brain
organoids, orbs the size of a pen dot with neurons and other features that
promise to sustain basic functions like learning and remembering.
"This opens up research on how the human brain works,"
Hartung said. "Because you can start manipulating the system, doing things
you cannot ethically do with human brains."
Hartung began to grow and assemble brain cells into functional
organoids in 2012 using cells from human skin samples reprogrammed into an
embryonic stem cell-like state. Each organoid contains about 50,000 cells,
about the size of a fruit fly's nervous system. He now envisions building a
futuristic computer with such brain organoids.
Computers that run on this "biological hardware" could
in the next decade begin to alleviate energy-consumption demands of
supercomputing that are becoming increasingly unsustainable, Hartung said. Even
though computers process calculations involving numbers and data faster than
humans, brains are much smarter in making complex logical decisions, like
telling a dog from a cat.
"The brain is still unmatched by modern computers,"
Hartung said. "Frontier, the latest supercomputer in Kentucky, is a $600
million, 6,800-square-feet installation. Only in June of last year, it exceeded
for the first time the computational capacity of a single human brain -- but
using a million times more energy."
It might take decades before organoid intelligence can power a
system as smart as a mouse, Hartung said. But by scaling up production of brain
organoids and training them with artificial intelligence, he foresees a future
where biocomputers support superior computing speed, processing power, data
efficiency, and storage capabilities.
"It will take decades before we achieve the goal of
something comparable to any type of computer," Hartung said. "But if
we don't start creating funding programs for this, it will be much more
difficult."
Organoid intelligence could also revolutionize drug testing
research for neurodevelopmental disorders and neurodegeneration, said Lena
Smirnova, a Johns Hopkins assistant professor of environmental health and
engineering who co-leads the investigations.
"We want to compare brain organoids from typically
developed donors versus brain organoids from donors with autism," Smirnova
said. "The tools we are developing towards biological computing are the
same tools that will allow us to understand changes in neuronal networks
specific for autism, without having to use animals or to access patients, so we
can understand the underlying mechanisms of why patients have these cognition
issues and impairments."
To assess the ethical implications of working with organoid
intelligence, a diverse consortium of scientists, bioethicists, and members of
the public have been embedded within the team.
Johns Hopkins authors included: Brian S. Caffo, David H.
Gracias, Qi Huang, Itzy E. Morales Pantoja, Bohao Tang, Donald J. Zack, Cynthia
A. Berlinicke, J. Lomax Boyd, Timothy DHarris, Erik C. Johnson, Jeffrey Kahn,
Barton L. Paulhamus, Jesse Plotkin, Alexander S. Szalay, Joshua T. Vogelstein,
and Paul F. Worley.
Other authors included: Brett J. Kagan, of Cortical Labs; Alysson R. Muotri, of the University of California San Diego; and Jens C. Schwamborn of University of Luxembourg.
