Spiking neural network models of interaural time difference extraction via a massively collaborative process

Abstract

Neuroscientists are increasingly initiating large-scale collaborations which bring together tens to hundreds of researchers. At this scale, such projects can tackle large-scale challenges and engage a wide range of participants. Inspired by projects in pure mathematics, we set out to test the feasibility of widening access to such projects even further, by running a massively collaborative project in computational neuroscience. The key difference, with prior neuroscientific efforts, being that our entire project (code, results, writing) was public from the outset, and that anyone could participate. To achieve this, we launched a public Git repository, with code for training spiking neural networks to solve a sound localisation task via surrogate gradient descent. We then invited anyone, anywhere to use this code as a springboard for exploring questions of interest to them, and encouraged participants to share their work both asynchronously through Git and synchronously at monthly online workshops. Our hope was that the resulting range of participants would allow us to make discoveries that a single team would have been unlikely to find. At a scientific level, our work investigated how a range of biologically-relevant parameters, from time delays to membrane time constants and levels of inhibition, could impact sound localisation in networks of spiking units. At a more macro-level, our project brought together 31 researchers from multiple countries, provided hands-on research experience to early career participants, and opportunities for supervision and teaching to later career participants. While our scientific results were not groundbreaking, our project demonstrates the potential for massively collaborative projects to transform neuroscience

Significance statement How should we structure large-scale scientific efforts? Massively collaborative projects, which anyone, anywhere, can contribute to, are one option. We ran a computational neuroscience project like this for two years and, here, share our results and experiences. At a scientific level, our work investigated how networks of simulated neurons can localise sound. At a more macro-level, our project brought together 31 researchers from multiple countries and provided research and training opportunities. Overall, our work demonstrates the potential for massively collaborative projects to transform how science is structured.