Tübingen and Virginia Researchers Utilize AI to Decode Fruit Fly Brain Calculations
Information in the brain is transmitted via electrical signals between specialised cells, the neurons. Large networks of such neurons control perception, behaviour and cognition. Science has long searched for ways to simulate neural networks in the brain with computers in order to understand how they work. With new findings about the neural circuitry in the brain of the fruit fly and methods of artificial intelligence, researchers have now succeeded in creating a neural network that does something previously unimaginable: It predicts the activity of individual neurons without having to take measurements on a living brain. The study by Professor Jakob Macke and Janne Lappalainen from the University of Tübingen and Dr. Srinivas Turaga and colleagues from the Janelia Research Campus of the Howard Hughes Medical Institute in Ashburn, Virginia (USA), was published on Wednesday in the journal Nature .
For decades, neuroscientists have been measuring neural activity in living animals to better understand the connections between brain activity and behavior. These experiments have yielded groundbreaking insights into how the brain works – but much of the brain remains unexplored.
The teams from Tübingen and Virginia have now used artificial intelligence and the connectome, a map of neurons and their connections in brain tissue, to predict the activity of neurons in the living brain. By using only information from the connectome of the fruit fly’s visual system and making assumptions about the functions of the circuit, the researchers have created an AI simulation that can predict the activity of each neuron in the circuit. “We now have a computational method that allows us to translate measurements of the connectome into predictions of neuronal activity and brain function without first having to carry out complex measurements on the living neuron,” says Srinivas Turaga, head of the Janelia research group and one of the lead authors of the new study.
The research team used the connectome to create a detailed mechanistic network simulation of the fly’s visual system, where each modeled neuron corresponds to a real neuron and each modeled synapse corresponds to a real synapse in the brain. Although they did not know the dynamics of the neurons in the real tissue, the team was able to predict these unknown parameters using deep learning methods. To do this, they combined the information from the connectome with their knowledge of the circuit’s function: detecting movement. “With this combination, we were able to test whether our connectome-based approach can provide a good model of the brain,” says Janne Lappalainen, a doctoral student at the University of Tübingen and lead author of the study.