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  • When you think about all the things humans have put their mind to, it’s impressive:

  • we built and landed robots on Mars to learn more about space.

  • We conjured up theories about how the universe worksand then proved them right.

  • We sequenced the human genome to paint a complete picture of our dna. but as for the minds that

  • made this all possible, we still don’t know much about how those actually work.

  • Scientists have been trying to navigate the mechanics of our large, complicated brains

  • for hundreds of years.

  • What would be really helpful is if we had a map.

  • And in order to get one of those, were going to need some brave scientists and very

  • advanced technology.

  • So how close are we to mapping the human brain?

  • If we could build a complete map of our brain and translate it, imagine what we could do:

  • We think maybe that will give us clues as to the causes of various forms of mental illness,

  • learning difficulties, diseases of aging.

  • And that might better allow us to figure out, are there treatments?

  • Or prevent the onset of some of those illnesses.

  • A map of the brain could even help us understand other scientific mysteries, like the origins

  • of consciousness.

  • Our brain is so powerful that if we better understood how it worked, we might be able

  • to create smarter robots and computers.

  • There is this technology in our brain for ... actually, in the brain of every mammal,

  • that allow us to behave autonomously.

  • It is very power-efficient.

  • A map of the human brain is seen as so valuable that multiple efforts across the world are

  • underway to get us there.

  • Aside from some big projects in the U.S. — well get to those laterthe European commission

  • is funding 100 universities to create a detailed computer model of the human brain.

  • China also announced a project to map the brain, and so has Japan.

  • There’s even several private projects focused on this goal.

  • So what do we mean when we say a map of the human brain?

  • Specifically, were talking about creating something called a “connectome” — a

  • complete catalog of all the structures in the brain and how they connect.

  • We typically think of there being both a structural and a functional connectome.

  • So the structural connectome is the white matter fibers that connect different parts

  • of the brain or the synapses that connect neurons.

  • And we call that structural because there's a physical synapse there that we can measure

  • and look at.

  • We're kind of making more of a roadmap of connections among brain regions.But there's

  • also what we call functional connections in the human brain, which have to do with kind

  • of coordination and function across brain regions.

  • That means identifying parts of the brain that work together but don’t necessarily

  • touch.

  • We don’t have any fully mapped functional connectomes yet and the only structural connectome

  • weve fully mapped is of “C elegans,” a transparent nematode about 1 millimeter

  • in length.

  • Even though they've been able to do that, it's still a complex organism.

  • And there's still a lot of work to be done to understand how the interactions give rise

  • to even the relatively simple behaviors that the C elegans can accomplish.

  • The connectome of the c. elegans brain identifies 302 neurons.

  • And if researching and building that connectome was complicated, now imagine how exponentially

  • more difficult it is to do the same with humans, who have somewhere in the region of 100 billion

  • neurons.

  • This is probably the first obstacle scientists have to overcome in mapping our brainsthe

  • sheer size and daunting complexity.

  • So, they have to start small, and I mean really smallthe samples they are studying are

  • the size of a grain of sand.

  • Inside that small grain of sand, there's about 100,000 neurons and form about one billion

  • connections.

  • So now, you see our brain is more than a million times bigger than this grain of sand, so you

  • can see how much units are compressed in such a small space.

  • And the brain is always changing, which makes it even more difficult to study.

  • When we're born, the brain grows over the course of development.

  • It builds new neurons, we're learning and interacting with the environment and that's

  • also shaping brain connections and how different parts of the brain work together.

  • but then it also starts to change as we get older and we move into later in life.

  • To tackle these challenges, the Obama administration started the Brain Initiative in 2014, bringing

  • several scientific institutions together to understand and treat the human mind.

  • As part of that coalition, the Allen Institute is analyzing mouse brain samples to count,

  • catalog, and connect the many different cell typesas a foundation for eventually doing

  • the same for the human brain.

  • Using electron microscopy, the team imaged billions of tiny synaptic connections in a

  • cubic millimeter of mouse neocortex.

  • Mapping the, the brain, at least at the resolution that we do it is difficult because many things

  • have to go right in the series.

  • Preparing the sample has to be perfect.

  • Scientists had to section the grain-sized brain sample into 25,000 pristine slices 40

  • nanometers wide.

  • For reference, a strand of hair is five times as thick as that.

  • Then those slices were distributed over six electron microscopes to be photographed.

  • It took us about five months to take all the pictures of that millimeter cube.I don't have

  • the final tally, but there's certainly hundreds of millions of those.

  • This type of data gathering took exhaustive, dedicated work around the clock.

  • When all the images were collected, researchers could then segment each single neuron and

  • create a 3D wiring diagram...step one towards that complete structural connectome, which

  • the team estimates will take five years to finish.

  • In terms of data storage was about two petabytes of data.

  • That’s about 2 million gigabytes from just a millimeter.

  • To eventually work with bigger human brain samples, something about this process will

  • have to change, as it will eventually be the largest data set ever collected about anything

  • in the world.

  • I think substantial, substantial advances on sample preparations, sample sectioning.

  • And above all, the storage of such will be immense.

  • Either technology will have to evolve in a way that such storage is available or our

  • sampling will have to evolve in ways that we can compress that, that information that

  • we want to extract from it.

  • Well also need forms of technology that aren’t as invasive as this, so we can study

  • live human brains, too.

  • And to develop a really robust map, were going to need to work with more than just

  • 1 single brain.

  • Well need to study young brains, old brains, male brains, female brains.

  • We collected a pretty interesting and unique sample of 1200 individuals.

  • The human connectome project, led by the NIH, is using non-invasive tools to study human

  • brains now.

  • So the main tool we use to start out is an MRI machine.

  • If we're looking at the structural connectome, we typically use something called diffusion

  • imaging.

  • It's looking at the diffusion of water along these white matter connections in the brain.

  • And if you have a nice strong connection going in a certain direction between two parts of

  • the brain, we can measure that.

  • We do something pretty different though when we look at the functional connectome in the

  • human brains.

  • So we still use an MRI scanner, but we use a different kind of sequence.

  • It's looking actually at blood flow in the brain that we think happens after there has

  • been neural activity.

  • So if you're looking at brain activity in a brain region going up and down over time,

  • you can say, "Are there other brain regions that show that same pattern?"

  • And if the patterns are very similar over time, we call those functionally connected

  • brain regions.

  • So far, the human connectome project has made a lot of advances in this area of mapping

  • the brain.

  • In 2016, they released the most detailed map of the cerebral cortex to date, discovering

  • 97 new brain regions in addition to confirming the existence of 83 others.

  • We understand much more now about how different brain regions kind of wire up together to

  • form networks.

  • We're starting to get a good sense of how those networks relate to which types of behaviors.

  • Where I think we still have work to do is understanding exactly how those contribute

  • or are changed by the experience of illnesses, how different kinds of environmental factors

  • might have an impact.

  • So this challenge is immense.

  • It will push our technology and creativity to their furthest limits; but so did sending

  • robots to mars, and sequencing the human genome... and we did all that.

  • So how close are we to mapping the human brain?

  • The biggest barriers keeping us from building a highly detailed human connectome is really

  • technology.

  • In my scientific lifetime, the progress has been exponential.

  • So I wouldn't be surprised in 10 or 20 years if we had a sort of dramatic leap in our understanding.

  • I think we may never have a map of every connection in the human brain in the sense of understanding

  • exactly how they interact together to give rise to exactly all the human behavioral and

  • cognitive and emotional abilities.

  • That's a tall order and I'm not entirely convinced that we will ever be there.

  • Looking at the shapes of those neurons they are beautiful.

  • They make me happy.

  • We and our collaborators are the first ones to see such, such, such detail at such scale

  • on the brain and that's like the, the old explorers when they arrived at the new continent.

  • We are, you know, we are mapping this, we are going into, into a territory where, where

  • things are new.

  • For more episodes of How Close Are We, check out this playlist right here.

  • Don’t forget to subscribe and come back to Seeker for more episodes.

  • Thanks for watching.

When you think about all the things humans have put their mind to, it’s impressive:

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我們離一張完整的人腦地圖有多近? (How Close Are We to a Complete Map of the Human Brain?)

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    林宜悉 發佈於 2021 年 01 月 14 日
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