A Brief History of Simulation Neuroscience

Fan, Xue; Markram, Henry

doi:10.3389/fninf.2019.00032

Cited by 65 publications

(44 citation statements)

References 275 publications

(334 reference statements)

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“…Our "replicate and explain" approach differs from the typical computational route taken to study circuit dynamics, whereby simplified circuit models are constructed to study the dependence of an observed phenomenon, e.g., SSA, on unobserved biophysical parameters 38,39 , for example, synaptic depression. While this classical modeling approach is invaluable for testing specific mechanisms that might explain the observed phenomena, the model is a priori tailored to replicate the phenomenon and, by design, it ignores other putative underlying mechanisms (and the interactions among them) that might impact the studied phenomena 40 .…”

Section: Discussionmentioning

confidence: 99%

Dense Computer Replica of Cortical Microcircuits Unravels Cellular Underpinnings of Auditory Surprise Response

Amsalem

Reimann

et al. 2020

Preprint

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The nervous system is notorious for its strong response evoked by a surprising sensory input, but the biophysical and anatomical underpinnings of this phenomenon are only partially understood. Here we utilized in-silico experiments of a biologicallydetailed model of a neocortical microcircuit to study stimulus specific adaptation (SSA) in the auditory cortex, whereby the neuronal response adapts significantly for a repeated ("expected") tone but not for a rare ("surprise") tone. SSA experiments were mimicked by stimulating tonotopically-mapped thalamo-cortical afferents projecting to the microcircuit; the activity of these afferents was modeled based on our in-vivo recordings from individual thalamic neurons. The modeled microcircuit expressed naturally many experimentally-observed properties of SSA, suggesting that SSA is a general property of neocortical microcircuits. By systematically modulating circuit parameters, we found that key features of SSA depended on synergistic effects of synaptic depression, spike frequency adaptation and recurrent network connectivity. The relative contribution of each of these mechanisms in shaping SSA was explored, additional SSA-related experimental results were explained and new experiments for further studying SSA were suggested.

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Section: Discussionmentioning

confidence: 99%

Dense Computer Replica of Cortical Microcircuits Unravels Cellular Underpinnings of Auditory Surprise Response

Amsalem

Reimann

et al. 2020

Preprint

Self Cite

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“…The same model partitioned across 64 cores required only 17 min. For a detailed discussion of several other large-scale simulation efforts, see also (De Garis et al, 2010; Fan and Markram, 2019).…”

Section: Discussionmentioning

confidence: 99%

Enabling Large-Scale Simulations With the GENESIS Neuronal Simulator

Crone

Vindiola

et al. 2019

Front. Neuroinform.

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In this paper, we evaluate the computational performance of the GEneral NEural SImulation System (GENESIS) for large scale simulations of neural networks. While many benchmark studies have been performed for large scale simulations with leaky integrate-and-fire neurons or neuronal models with only a few compartments, this work focuses on higher fidelity neuronal models represented by 50–74 compartments per neuron. After making some modifications to the source code for GENESIS and its parallel implementation, PGENESIS, particularly to improve memory usage, we find that PGENESIS is able to efficiently scale on supercomputing resources to network sizes as large as 9 × 106 neurons with 18 × 109 synapses and 2.2 × 106 neurons with 45 × 109 synapses. The modifications to GENESIS that enabled these large scale simulations have been incorporated into the May 2019 Official Release of PGENESIS 2.4 available for download from the GENESIS web site (genesis-sim.org).

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“…Concepts developed through work with algorithms, neural networks, and reinforcement learning may provide new approaches that help better understand brain-based intelligence, while artificial neural networks may serve as simulations that provide insights which help to better understand brain processes. Simulation neuroscience, a new research field that aims to build a digital copy of the brain, relies heavily on these interdisciplinary connections and fosters collaborations between researchers from neuroscience and computer science (Markram 2006;Fan and Markram 2019).…”

Section: Brain-based and Artificial Intelligencementioning

confidence: 99%

Editorial: Shaping Ethical Futures in Brain-Based and Artificial Intelligence Research

2020

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In discussions of the ethical and social implications of artificial intelligence (AI), a good starting point is: How is AI and AI-related technology similar to and different from related contexts and technology? It seems helpful not to attempt to start the debate on ethical and social implications of AI from scratch, but to refer and relate to already existing and sometimes longstanding debates and research. Two fields seem to be particularly useful here: The discussion of philosophical, ethical and social aspects of technology on the one hand, and the context of brain-related sciences, philosophy of mind, bioethics and neuroethics on the other hand. With this topical collection, we focus on the second approach, i.e. we think about ethical implications of AI and neurotechnology by thinking about and drawing upon similarities and differences between brains and computer technology, neuroscience, behavioral, and cognitive science and computer science, starting from concepts and conceptions used to describe characteristics of humans and non-human animals and reflecting on how these can be used in or transferred to AI.

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A Brief History of Simulation Neuroscience

Cited by 65 publications

References 275 publications

Dense Computer Replica of Cortical Microcircuits Unravels Cellular Underpinnings of Auditory Surprise Response

Dense Computer Replica of Cortical Microcircuits Unravels Cellular Underpinnings of Auditory Surprise Response

Enabling Large-Scale Simulations With the GENESIS Neuronal Simulator

Editorial: Shaping Ethical Futures in Brain-Based and Artificial Intelligence Research

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