2022
DOI: 10.1016/j.bios.2021.113834
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Implementation of biohybrid olfactory bulb on a high-density CMOS-chip to reveal large-scale spatiotemporal circuit information

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Cited by 18 publications
(50 citation statements)
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“…To estimate the mesoscale functional connectivity and measure the information flow and its direction within the correlated links in the circuitry, we employed multivariate Granger causality and directed transfer function (DTF) 11 . The ENR network showed both higher unidirectional (i.e., DG→CA3, CA1, EC, PC) and bidirectional (i.e., CA3↔CA3, CA1↔CA1, DG↔DG, Hilus↔Hilus, EC↔EC, and PC↔PC) interaction links compared to the SD network (Figures 1g-i) .…”
Section: Resultsmentioning
confidence: 99%
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“…To estimate the mesoscale functional connectivity and measure the information flow and its direction within the correlated links in the circuitry, we employed multivariate Granger causality and directed transfer function (DTF) 11 . The ENR network showed both higher unidirectional (i.e., DG→CA3, CA1, EC, PC) and bidirectional (i.e., CA3↔CA3, CA1↔CA1, DG↔DG, Hilus↔Hilus, EC↔EC, and PC↔PC) interaction links compared to the SD network (Figures 1g-i) .…”
Section: Resultsmentioning
confidence: 99%
“…Next, we identified the topographic propagation delay of the spatiotemporal firing patterns by computing the time-delay between sequential occurring events in each hippo-cortical subregions, which yielded greater firing probability and higher synchrony in the ENR compared to the SD networks ( Figure 5d ). We then analyzed the spatiotemporal propagation patterns of the recorded events with an algorithm based on the center of activity trajectories (CATs) 11 and classified the CATs of network-wide activity with an unsupervised machine learning algorithm (see method). Thereby, we identified three categories of propagation pathways: 1) hippocampus to entorhinal/perirhinal-cortex, 2) intra-hippocampal circuits mediated by the recurrent network, and 3) entorhinal-cortex to hippocampus corresponding to the classical unidirectional tri-synaptic pathway ( Figures 5e-l ).…”
Section: Resultsmentioning
confidence: 99%
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“…Other noteworthy studies in neuromorphic olfaction include the rank-order-based latency coding [16,17], hardware-based olfactory models based on the antennal lobe of fruit fly [18][19][20], a VLSI implementation of an SNN based on the neurophysiological architecture of a rodent olfactory bulb [21], hardware implementation of the olfactory bulb model [22], a classifier using a convolutional spiking neural network [23], a 3D SNN reservoir-based classifier for odor recognition [24], and the columnar olfactory bulb model inspired by the glomerular layer of the mammalian olfactory pathway that was recently extended for its implementation on Loihi, Intel's neuromorphic research chip [14,25]. However, most of the research in neuromorphic olfaction, such as [15,21,[26][27][28][29][30], is more driven towards implementing a high level of bio-realism to emulate the biological olfactory pathway, which results in impractical models with limited scope for real-world applications [5].…”
Section: Introductionmentioning
confidence: 99%