A GPU-based Computational Framework That Bridges Neuron Simulation and Artificial Intelligence

Overview

Journal Nat Commun

Specialty Biology

Date 2023 Sep 18

PMID 37723170

Authors

Yichen Zhang

Gan He

Lei Ma

Xiaofei Liu

J J Johannes Hjorth

Alexander Kozlov

Yutao He

Shenjian Zhang

Jeanette Hellgren Kotaleski

Yonghong Tian

Sten Grillner

Kai Du

Tiejun Huang

Affiliations

Soon will be listed here.

Abstract

Biophysically detailed multi-compartment models are powerful tools to explore computational principles of the brain and also serve as a theoretical framework to generate algorithms for artificial intelligence (AI) systems. However, the expensive computational cost severely limits the applications in both the neuroscience and AI fields. The major bottleneck during simulating detailed compartment models is the ability of a simulator to solve large systems of linear equations. Here, we present a novel Dendritic Hierarchical Scheduling (DHS) method to markedly accelerate such a process. We theoretically prove that the DHS implementation is computationally optimal and accurate. This GPU-based method performs with 2-3 orders of magnitude higher speed than that of the classic serial Hines method in the conventional CPU platform. We build a DeepDendrite framework, which integrates the DHS method and the GPU computing engine of the NEURON simulator and demonstrate applications of DeepDendrite in neuroscience tasks. We investigate how spatial patterns of spine inputs affect neuronal excitability in a detailed human pyramidal neuron model with 25,000 spines. Furthermore, we provide a brief discussion on the potential of DeepDendrite for AI, specifically highlighting its ability to enable the efficient training of biophysically detailed models in typical image classification tasks.

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