Highlights d Two distinct subtypes of excitatory neurons in superficial retrosplenial cortex (RSC) d Most common neuron in layer 2/3 of RSC is excitatory lowrheobase (LR) neuron d LR intrinsic properties enable precise, sustained encoding of information d Layer 2/3 of RSC is dominated by feedforward, not feedback, inhibition
The granular layer, which mainly consists of granule and Golgi cells, is the first stage of the cerebellar cortex and processes spatiotemporal information transmitted by mossy fiber inputs with a wide variety of firing patterns. To study its dynamics at multiple time scales in response to inputs approximating real spatiotemporal patterns, we constructed a large-scale 3D network model of the granular layer. Patterned mossy fiber activity induces rhythmic Golgi cell activity that is synchronized by shared parallel fiber input and by gap junctions. This leads to long distance synchrony of Golgi cells along the transverse axis, powerfully regulating granule cell firing by imposing inhibition during a specific time window. The essential network mechanisms, including tunable Golgi cell oscillations, on-beam inhibition and NMDA receptors causing first winner keeps winning of granule cells, illustrate how fundamental properties of the granule layer operate in tandem to produce (1) well timed and spatially bound output, (2) a wide dynamic range of granule cell firing and (3) transient and coherent gating oscillations. These results substantially enrich our understanding of granule cell layer processing, which seems to promote spatial group selection of granule cell activity as a function of timing of mossy fiber input.
Abstract-Extreme scaling practices in silicon technology are quickly leading to integrated circuit components with limited reliability, where phenomena such as early-transistor failures, gate-oxide wearout, and transient faults are becoming increasingly common. In order to overcome these issues and develop robust design techniques for large-market silicon ICs, it is necessary to rely on accurate failure analysis frameworks which enable design houses to faithfully evaluate both the impact of a wide range of potential failures and the ability of candidate reliable mechanisms to overcome them. Unfortunately, while failure rates are already growing beyond economically viable limits, no fault analysis framework is yet available that is both accurate and can operate on a complex integrated system.To address this void, we present CrashTest, a fast, highfidelity and flexible resiliency analysis system. Given a hardware description model of the design under analysis, CrashTest is capable of orchestrating and performing a comprehensive design resiliency analysis by examining how the design reacts to faults while running software applications. Upon completion, CrashTest provides a high-fidelity analysis report obtained by performing a fault injection campaign at the gate-level netlist of the design. The fault injection and analysis process is significantly accelerated by the use of an FPGA hardware emulation platform. We conducted experimental evaluations on a range of systems, including a complex LEON-based systemon-chip, and evaluated the impact of gate-level injected faults at the system level. We found that CrashTest is 16-90x faster than an equivalent software-based framework, when analyzing designs through direct primary I/Os. As shown by our LEONbased SoC experiments, CrashTest exhibits emulation speeds that are six orders of magnitude faster than simulation.
The granular retrosplenial cortex (RSG) is critical for both spatial and non-spatial behaviors, but the underlying neural codes remain poorly understood. Here, we use optogenetic circuit mapping in mice to reveal a double dissociation that allows parallel circuits in superficial RSG to process disparate inputs. The anterior thalamus and dorsal subiculum, sources of spatial information, strongly and selectively recruit small low-rheobase (LR) pyramidal cells in RSG. In contrast, neighboring regular-spiking (RS) cells are preferentially controlled by claustral and anterior cingulate inputs, sources of mostly non-spatial information. Precise sublaminar axonal and dendritic arborization within RSG layer 1, in particular, permits this parallel processing. Observed thalamocortical synaptic dynamics enable computational models of LR neurons to compute the speed of head rotation, despite receiving head direction inputs that do not explicitly encode speed. Thus, parallel input streams identify a distinct principal neuronal subtype ideally positioned to support spatial orientation computations in the RSG.
Neurons of the cerebellar nuclei convey the final output of the cerebellum to their targets in various parts of the brain. Within the cerebellum their direct upstream connections originate from inhibitory Purkinje neurons. Purkinje neurons have a complex firing pattern of regular spikes interrupted by intermittent pauses of variable length. How can the cerebellar nucleus process this complex input pattern? In this modeling study, we investigate different forms of Purkinje neuron simple spike pause synchrony and its influence on candidate coding strategies in the cerebellar nuclei. That is, we investigate how different alignments of synchronous pauses in synthetic Purkinje neuron spike trains affect either time-locking or rate-changes in the downstream nuclei. We find that Purkinje neuron synchrony is mainly represented by changes in the firing rate of cerebellar nuclei neurons. Pause beginning synchronization produced a unique effect on nuclei neuron firing, while the effect of pause ending and pause overlapping synchronization could not be distinguished from each other. Pause beginning synchronization produced better time-locking of nuclear neurons for short length pauses. We also characterize the effect of pause length and spike jitter on the nuclear neuron firing. Additionally, we find that the rate of rebound responses in nuclear neurons after a synchronous pause is controlled by the firing rate of Purkinje neurons preceding it.
Overall, the model suggests single-unit surface recording is limited to neurons in layer 1 and further improvement in electrode design is needed.
The granular retrosplenial cortex (RSG) is critical for both spatial navigation and fear conditioning, but the neural codes enabling these seemingly disparate functions remain unknown. Here, using optogenetic circuit mapping, we reveal a double dissociation that allows parallel circuits in superficial RSG to process navigation- versus fear-related inputs. The anterior thalamus, a source of head direction information, strongly recruits small, low rheobase (LR) pyramidal cells in RSG layer 3. Neighboring regular-spiking (RS) cells are instead preferentially controlled by claustral and anterior cingulate inputs, sources of higher-order and fear-related information. Precise sublaminar axonal and dendritic arborization within RSG layer 1 enable this parallel processing. Synaptic dynamics and computational modeling suggest LR neurons are optimally-tuned conjunctive encoders of direction and distance inputs from the thalamus and dorsal subiculum, respectively. RS cells are better positioned to support contextual fear memories. Thus, parallel input streams to computationally-distinct principal neurons help facilitate diverse RSG functions.
Traumatic brain injuries (TBI) lead to dramatic changes in the surviving brain tissue. Altered ion concentrations, coupled with changes in the expression of membrane-spanning proteins, create a post-TBI brain state that can lead to further neuronal loss caused by secondary excitotoxicity. Several GABA receptor agonists have been tested in the search for neuroprotection immediately after an injury, with paradoxical results. These drugs not only fail to offer neuroprotection, but can also slow down functional recovery after TBI. Here, using computational modeling, we provide a biophysical hypothesis to explain these observations. We show that the accumulation of intracellular chloride ions caused by a transient upregulation of Na +-K +-2Cl-(NKCC1) co-transporters as observed following TBI, causes GABA receptor agonists to lead to excitation and depolarization block, rather than the expected hyperpolarization. The likelihood of prolonged, excitotoxic depolarization block is further exacerbated by the extremely high levels of extracellular potassium seen after TBI. Our modeling results predict that the neuroprotective efficacy of GABA receptor agonists can be substantially enhanced when they are combined with NKCC1 co-transporter inhibitors. This suggests a rational, biophysically principled method for identifying drug combinations for neuroprotection after TBI.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.