BRAIN Initiative: Cutting-Edge Tools and Resources for the Community

Litvina, Elizabeth Y.; Adams, Alois J.; Barth, Alison L.; Bruchez, Marcel P.; Carson, James A.; Chung, Jason; Dupre, Kristin B.; Frank, Loren M.; Gates, Kathleen M.; Harris, Kristen M.; Joo, Hannah R.; Lichtman, Jeff W.; Ramos, Khara M.; Sejnowski, Terrence J.; Trimmer, James S.; White, Samantha; Koroshetz, Walter J.

doi:10.1523/jneurosci.1169-19.2019

Cited by 36 publications

(38 citation statements)

References 65 publications

(62 reference statements)

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“…In our approach, unrecorded units and associated undetected correlation patterns may produce a reduction in the number of computed correlation triangles, which in turn may result in reduced filtering capabilities. As other technologies from the Brain Initiative (Litvina et al, 2019) and related efforts, such as the Human Brain Project in the EU, become available online and are validated, the methods we develop here will be in a position to take immediate advantage of them. For example, high-density MEAs (HDMEAs) that include tens of thousands of electrodes at cellular and subcellular resolution (Ullo et al, 2014;Muller et al, 2015;Yada et al, 2016;Bullmann et al, 2019) offer optimized acquisition settings and will greatly improve the resolution and accuracy of our approach.…”

Section: Discussionmentioning

confidence: 99%

Super-Selective Reconstruction of Causal and Direct Connectivity With Application to in vitro iPSC Neuronal Networks

et al. 2021

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Despite advancements in the development of cell-based in-vitro neuronal network models, the lack of appropriate computational tools limits their analyses. Methods aimed at deciphering the effective connections between neurons from extracellular spike recordings would increase utility of in vitro local neural circuits, especially for studies of human neural development and disease based on induced pluripotent stem cells (hiPSC). Current techniques allow statistical inference of functional couplings in the network but are fundamentally unable to correctly identify indirect and apparent connections between neurons, generating redundant maps with limited ability to model the causal dynamics of the network. In this paper, we describe a novel mathematically rigorous, model-free method to map effective—direct and causal—connectivity of neuronal networks from multi-electrode array data. The inference algorithm uses a combination of statistical and deterministic indicators which, first, enables identification of all existing functional links in the network and then reconstructs the directed and causal connection diagram via a super-selective rule enabling highly accurate classification of direct, indirect, and apparent links. Our method can be generally applied to the functional characterization of any in vitro neuronal networks. Here, we show that, given its accuracy, it can offer important insights into the functional development of in vitro hiPSC-derived neuronal cultures.

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Section: Discussionmentioning

confidence: 99%

Super-Selective Reconstruction of Causal and Direct Connectivity With Application to in vitro iPSC Neuronal Networks

et al. 2021

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“… The epilepsy community would benefit from learning from successful models for research and clinical care that have been implemented for other diseases. More specifically, there is a need to understand the mechanisms that underlie the epilepsies in order to develop targeted and more precise therapies; develop and validate an array of biomarkers for the epilepsies to identify those most at risk for developing epilepsy and SUDEP, measure progression of disease, and response to treatment; improve preclinical models of epilepsies so that they better recapitulate the human condition; expand epilepsy research and clinical care to underserved communities and diversify the workforce in both areas; and create and utilize innovative new tools and measures, such as those being developed in the BRAIN Initiative 14 that expand the capabilities of basic and clinical research on the epilepsies. …”

Section: Review Of Curing the Epilepsies Meetingmentioning

confidence: 99%

“…create and utilize innovative new tools and measures, such as those being developed in the BRAIN Initiative 14 that expand the capabilities of basic and clinical research on the epilepsies.…”

Section: Review Of Curing the Epilepsies Meetingmentioning

confidence: 99%

The 2021 Epilepsy Research Benchmarks—Respecting Core Principles, Reflecting Evolving Community Priorities

et al. 2021

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“…The promise of network models for characterizing individual-level processes in intensive longitudinal and functional neuroimaging time series data has precipitated a surge of interest across the behavioral and neural sciences. Many of these models were initially developed to characterize temporal and network dynamics of interactions between brain regions in functional magnetic resonance imaging (fMRI) data, leading to recent advances in the field's understanding of the neural correlates of cognition and psychiatric syndromes (Beltz et al, 2018;Elbich et al, 2019;Gates et al, 2014;Litvina et al, 2019;Mumford & Ramsey, 2014;Nichols et al, 2014;Price, Lane, et al, 2017;Weigard et al, 2019;Wu et al, 2019). Applications of similar network models to data from daily diary and ambulatory assessment studies have also begun to provide key insights into the within-person dynamics of basic psychological phenomena (Bar-Kalifa & Sened, 2019;Hofmans et al, 2019;Lydon-Staley & Bassett, 2018;Yang et al, 2019) and to elucidate person-specific structures, and determinants, of psychopathology Dotterer et al, 2019;Ellison et al, 2019;Jongeneel et al, 2019;Stroe-Kunold et al, 2016;Wright et al, 2015;Yang et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

The Influence of Autoregressive Relation Strength and Search Strategy on Directionality Recovery in GIMME

As¹,

Lane²,

Gates³

et al. 2020

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Unified structural equation modeling (uSEM) implemented in the Group Iterative Multiple Model Estimation (GIMME) framework has recently been widely used for characterizing within-person network dynamics of behavioral and functional neuroimaging variables. Previous studies have established that GIMME accurately recovers the presence of relations between variables. However, recovery of relation directionality is less consistent, which is concerning given the importance of directionality estimates for many research questions. There is evidence that strong autoregressive relations may aid directionality recovery and indirect evidence that a novel version of GIMME allowing for multiple solutions could improve recovery when such relations are weak, but it remains unclear how these strategies perform under a range of study conditions. Using comprehensive simulations that varied the strength of autoregressive relations among other factors, this study evaluated the directionality recovery of two GIMME search strategies: 1) estimating autoregressive relations by default in the null model (GIMME-AR), and 2) generating multiple solution paths (GIMME-MS). Both strategies recovered directionality best – and were roughly equivalent in performance – when autoregressive relations were strong (e.g., β = .60). When they were weak (β <= .10), GIMME-MS displayed an advantage, although overall directionality recovery was modest. Analyses of empirical data in which autoregressive relations were characteristically strong (resting state fMRI) versus weak (daily diary) mirrored simulation results and confirmed that these strategies typically disagree on directionality when autoregressive relations are weak. Findings have important implications for psychological and neuroimaging applications of uSEM/GIMME and suggest specific contexts which allow researchers to place confidence in directionality results.

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BRAIN Initiative: Cutting-Edge Tools and Resources for the Community

Cited by 36 publications

References 65 publications

Super-Selective Reconstruction of Causal and Direct Connectivity With Application to in vitro iPSC Neuronal Networks

Super-Selective Reconstruction of Causal and Direct Connectivity With Application to in vitro iPSC Neuronal Networks

The 2021 Epilepsy Research Benchmarks—Respecting Core Principles, Reflecting Evolving Community Priorities

The Influence of Autoregressive Relation Strength and Search Strategy on Directionality Recovery in GIMME

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