Computational Models of Astrocyte-Neuron Interactions
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Source: https://github.com/AllenNeuralDynamics/ComputationalReviewAstrocytes/blob/1a55da0634a3bc04e5688792ed12141ce271d28e/content/13_computational_models.md
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Citation contexts
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1CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}
sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference With the review’s empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections{ref}sec:calcium-signaling,{ref}sec:gliotransmission,{ref}sec:metabolic-coupling,{ref}sec:plasticity,{ref}sec:in-vivo-dynamics, and{ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact... -
2CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}
sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference With the review’s empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections{ref}sec:calcium-signaling,{ref}sec:gliotransmission,{ref}sec:metabolic-coupling,{ref}sec:plasticity,{ref}sec:in-vivo-dynamics, and{ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact... -
3CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}
sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference With the review’s empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections{ref}sec:calcium-signaling,{ref}sec:gliotransmission,{ref}sec:metabolic-coupling,{ref}sec:plasticity,{ref}sec:in-vivo-dynamics, and{ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact... -
4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference 4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference; (iii) network-
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5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference 4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference; (iii) network-
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6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference 6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference reported that none of nine canonical
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1CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}
sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference originally developed to describe astrocytes 2CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference0. -
2CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}
sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference1 2CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference2. -
2CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}
sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference3 2CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference4. -
2CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}
sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference5 the experimental trace 2CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference6. Second, a systematic -
2CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}
sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference7 2CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference8. The resulting “canonical” parameter -
2CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}
sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference9 3CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference0, C_{θ}≈ 0.15–0.80\,μ{M}, -
3CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}
sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference1 gap-junction network of 3CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference2, approximately -
3CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}
sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference3 tripartite-synapse model of 3CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference4. -
3CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}
sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference5 3-D gap-junction network of 3CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference6. Each -
3CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}
sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference7 3CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference8, postsynaptic slow inward currents through -
3CitationWith the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}
sec:calcium-signaling, {ref}sec:gliotransmission, {ref}sec:metabolic-coupling, {ref}sec:plasticity, {ref}sec:in-vivo-dynamics, and {ref}sec:regional-diversityhave been translated into formal computational predictions, and how well those predictions survive contact...content/13_computational_models.md:line 4Open reference9 extrasynaptic NMDARs 4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference0, and a third-factor -
4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference1 4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference2. In
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4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference3 4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference4. In
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4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference5 4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference6.
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4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference7 4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference8.
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4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference9 4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference0. The discrepancy is not yet resolved. Two
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4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference1 Ca2+ is abolished 4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference2. Second, models
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4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference3 release 4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference4. Whether
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4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference5 4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference6 behavioural null, and with the
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4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference7 deletion 4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference8, which would
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4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference9 deletion 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference0, which would
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5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference1 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference2. A bidirectionally
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5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference3 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference4. A spiking Izhikevich network with astrocytic
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5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference5 match in vivo recordings 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference6. A spiking network
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5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference7 damage-matched control 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference8. An unsupervised spiking
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5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference9 respectively in a 90%-faulty network 4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference0, and
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4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference1 population raster 4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference2.
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4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference3 working-memory retention 4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference4, for slow-timescale
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4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference5 4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference6, for the formation and protection of synaptic
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4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference7 memory traces 4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference8, and for
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4Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference, 5Citation[nadkarni2008ploscomput, depitta2016neuralplasticity]; (iii) network-content/13_computational_models.md:line 14Open reference9 memory traces 6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference0, and for
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6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference1 pattern-completion-like operations on 2-D stimuli 6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference2.
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6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference3 6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference4, and that astrocyte-augmented spiking
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6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference5 neuron-only controls 6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference6. As in
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6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference7 6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference8 found that no canonical astrocyte
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6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference9 similar conclusions 6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference0, and domain-specific
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6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference1 6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference2.
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6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference3 6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference4 and to the compartmentalised physiology of
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6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference5 6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference6.
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6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference7 6Citation[manninen2018frontneuroinform] reported that none of nine canonicalcontent/13_computational_models.md:line 20Open reference8.
References
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- [bezerra_2024_ploscomput] “With the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}`sec:calcium-signaling`, {ref}`sec:gliotransmission`, {ref}`sec:metabolic-coupling`, {ref}`sec:plasticity`, {ref}`sec:in-vivo-dynamics`, and {ref}`sec:regional-diversity` have been translated into formal computational predictions, and how well those predictions survive contact...”
- [jiang_2025_ploscomput] “With the review's empirical content now in place, this section asks a different question: which of the mechanisms catalogued in Sections {ref}`sec:calcium-signaling`, {ref}`sec:gliotransmission`, {ref}`sec:metabolic-coupling`, {ref}`sec:plasticity`, {ref}`sec:in-vivo-dynamics`, and {ref}`sec:regional-diversity` have been translated into formal computational predictions, and how well those predictions survive contact...”
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- [petravicz_2014_frontbehav] “[petravicz_2014_frontbehav]. The discrepancy is not yet resolved. Two”
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- [blummoyse_2022_ploscomput] “release [blummoyse_2022_ploscomput]. Whether”
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- [naghieh_2023_iscience] “damage-matched control [naghieh_2023_iscience]. An unsupervised spiking”
- [rastogi_2021_frontneurosci] “respectively in a 90\%-faulty network [rastogi_2021_frontneurosci], and”
- [stasenko_2023_entropy] “population raster [stasenko_2023_entropy].”
- [lenk_2020_frontcomput] “[lenk_2020_frontcomput], for the formation and protection of synaptic”
- [manninen_2023_neuroinform] “similar conclusions [manninen_2023_neuroinform], and domain-specific”
- [gonzalez_2020_frontneuroinform] “[gonzalez_2020_frontneuroinform].”
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- Design Brief: Beta-test Evaluation Protocol for SciDEX v2 Design Trajectories
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