Litcius/Paper detail

Ultrafast simulation of large-scale neocortical microcircuitry with biophysically realistic neurons

Viktor Janos Oláh, Nigel P. Pedersen, Matthew JM Rowan

2022eLife15 citationsDOIOpen Access PDF

Abstract

Understanding the activity of the mammalian brain requires an integrative knowledge of circuits at distinct scales, ranging from ion channel gating to circuit connectomics. Computational models are regularly employed to understand how multiple parameters contribute synergistically to circuit behavior. However, traditional models of anatomically and biophysically realistic neurons are computationally demanding, especially when scaled to model local circuits. To overcome this limitation, we trained several artificial neural network (ANN) architectures to model the activity of realistic multicompartmental cortical neurons. We identified an ANN architecture that accurately predicted subthreshold activity and action potential firing. The ANN could correctly generalize to previously unobserved synaptic input, including in models containing nonlinear dendritic properties. When scaled, processing times were orders of magnitude faster compared with traditional approaches, allowing for rapid parameter-space mapping in a circuit model of Rett syndrome. Thus, we present a novel ANN approach allowing for rapid, detailed network experiments using inexpensive and commonly available computational resources.

Topics & Concepts

ConnectomicsComputer scienceBiological neural networkNeuromorphic engineeringArtificial neural networkNeuroscienceComputational neuroscienceSubthreshold conductionParameter spaceNonlinear systemComputational modelConnectomeArtificial intelligenceMachine learningPhysicsBiologyFunctional connectivityMathematicsStatisticsQuantum mechanicsTransistorVoltageAdvanced Memory and Neural ComputingNeural dynamics and brain functionGenetics and Neurodevelopmental Disorders