AI Article Synopsis
- Neuroscience aims to create a causal model of the nervous system, and recent research on the fly connectome maps the synaptic connections between neurons but lacks details on their signaling strength in real conditions.
- A new integrated approach combines experimental data from optogenetic perturbations with statistical methods to estimate the causal relationships in the fly brain, referred to as the 'effectome'.
- The findings suggest that the fly’s brain dynamics are primarily governed by small, independent circuits of neurons, making it feasible to develop a causal model for its brain activity.
Article Abstract
A goal of neuroscience is to obtain a causal model of the nervous system. The recently reported whole-brain fly connectome specifies the synaptic paths by which neurons can affect each other, but not how strongly they do affect each other in vivo. To overcome this limitation, we introduce a combined experimental and statistical strategy for efficiently learning a causal model of the fly brain, which we refer to as the 'effectome'. Specifically, we propose an estimator for a linear dynamical model of the fly brain that uses stochastic optogenetic perturbation data to estimate causal effects and the connectome as a prior to greatly improve estimation efficiency. We validate our estimator in connectome-based linear simulations and show that it recovers a linear approximation to the nonlinear dynamics of more biophysically realistic simulations. We then analyse the connectome to propose circuits that dominate the dynamics of the fly nervous system. We discover that the dominant circuits involve only relatively small populations of neurons-thus, neuron-level imaging, stimulation and identification are feasible. This approach also re-discovers known circuits and generates testable hypotheses about their dynamics. Overall, we provide evidence that fly whole-brain dynamics are generated by a large collection of small circuits that operate largely independently of each other. This implies that a causal model of a brain can be feasibly obtained in the fly.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11446844 | PMC |
| http://dx.doi.org/10.1038/s41586-024-07982-0 | DOI Listing |
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