The astoundingly intricate diagram is a significant advancement in neuroscience.
The astoundingly intricate diagram is a significant advancement in neuroscience.
The humble fruit fly’s brain has been mapped for the first time – offering hope of unlocking the secrets of thought.
It’s the most complete 3D model of its kind – featuring 3,016 neurons and all 548,000 connections between them.
The breathtakingly detailed diagram is a landmark achievement in neuroscience. It is expected to underpin future research – and open the door to improved artificial intelligence.
Senior author Dr. Joshua Vogelstein of Johns Hopkins University in Baltimore, Md., said: “If we want to understand who we are and how we think, part of that is understanding the mechanism of thought.
“And the key to that is knowing how neurons connect with each other.”
Fruit flies have brains about the size of a poppy seed. But they behave in ways that indicate substantial cognitive skills.
Behaviors include complex courtship dances and investigating hazards before choosing new locations.
Past reconstructions of the brains of insects, mice and even humans – known as connectomes – have been attempted since the 1970s.
They typically represent only a tiny fraction of the organ. This is by far the most expansive.
Dr. Vogelstein said: “It has been 50 years and this is the first brain connectome. It is a flag in the sand that we can do this. Everything has been working up to this.”
Getting a complete cellular-level picture of a brain requires hundreds or thousands of individual tissue slices.
They have to be scanned and then painstakingly put together like a jigsaw puzzle – neuron by neuron.
It took more than a decade to do that with the baby fruit fly. A mouse’s brain is a million times larger.
The chance of mapping anything close to a human’s is likely impossible in the near future – or even our lifetimes.
Fruit fly larva shares much of their fundamental biology with humans – including a comparable genetic foundation.
It also has rich learning and decision-making abilities – making it a useful model organism.
For practical purposes, its relatively compact brain can be imaged and circuits reconstructed within a reasonable time frame.
The project described in the journal Science still took 12 years. High-resolution imaging alone worked out at about a day per neuron.
This was carried out at Cambridge where researchers manually studied them to identify individual neurons, rigorously tracing each one and linking their synaptic links. Their U.S. colleagues then spent more than three years using original codes to analyze connectivity.
Eventually, the team charted every neuron and connection – categorizing each one to the role it plays in the brain. The busiest circuits were those that led to and away from neurons of the learning center.
Despite the challenges, it is expected scientists will take on the mouse brain within the next decade using the same techniques.
Other teams are already working on a map of the adult fruit fly brain.
The fruit fly larva work showed circuit features that were strikingly reminiscent of prominent and powerful machine learning architectures.
The team expects the continued study will reveal even more computational principles and potentially inspire new artificial intelligence systems.
Added Dr. Vogelstein: “What we learned about code for fruit flies will have implications for the code for humans.
“That is what we want to understand – how to write a program that leads to a human brain network.”
In total, the fruit fly brain has around 100,000 neurons – about the same amount as a lobster. The human brain has around 86 billion.
Produced in association with SWNS Talker
