Silencing of Activity During Hypoxia Improves Functional Outcomes in Motor Neuron Networks in vitro

Fiskum, Vegard; Sandvig, Axel; Sandvig, Ioanna

doi:10.3389/fnint.2021.792863

Cited by 10 publications

(9 citation statements)

References 51 publications

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“…As shown in Figure 2 , our engineered neural networks expressed both the excitatory neuronal marker CaMKIIa, and the inhibitory neuronal marker GAD65/67 in conjunction with the neuronal marker MAP2 by 21 DIV, strongly indicating the capacity for excitatory – inhibitory synaptic transmission within the maturing networks. This was further verified through recordings of electrophysiological activity, which showed that in healthy conditions, networks developed highly dynamic and complex age-dependent firing activity and network bursts over time, in line with previous studies by us and others (Chiappalone et al, 2006; Chiappalone et al, 2007; Fiskum et al, 2021; van de Wijdeven et al, 2018; Weir et al, 2023).…”

Section: Discussionsupporting

confidence: 89%

Evolving alterations of structural organization and functional connectivity in feedforward neural networks after induced P301L tau mutation

Weir,

Hanssen,

Winter-Hjelm

et al. 2023

Preprint

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Reciprocal structure-function relationships underly both healthy and pathological behaviors in complex neural networks. Neuropathology can have widespread implications on the structural properties of neural networks, and drive changes in the functional interactions among network components at the micro-, and mesoscale level. Thus, understanding network dysfunction requires a thorough investigation of the complex interactions between structural and functional network reconfigurations in response to perturbation. However, such network reconfigurations at the micro- and mesoscale level are often difficult to study in vivo. For example, subtle, evolving changes in synaptic connectivity, transmission, and electrophysiological shift from healthy to pathological states are difficult to study in the brain. Engineered in vitro neural networks are powerful models that enable selective targeting, manipulation, and monitoring of dynamic neural network behavior at the micro- and mesoscale in physiological and pathological conditions. In this study, we first established feedforward cortical neural networks using in-house developed two-nodal microfluidic chips with controllable connectivity interfaced with microelectrode arrays (mMEAs). We subsequently induced perturbations to these networks by adeno-associated virus (AAV) mediated expression of human mutated tau in the presysnaptic node and monitored network structure and activity over three weeks. We found that induced perturbation in the presynaptic node resulted in altered structural organization and extensive axonal retraction starting in the perturbed node. Perturbed networks also exhibited functional changes in intranodal activity, which manifested as an overall decline in both firing rate and bursting activity, with a progressive increase in synchrony over time. We also observed impaired spontaneous and evoked internodal signal propagation between pre-and postsynaptic nodes in the perturbed networks. These results provide novel insights into dynamic structural and functional reconfigurations in engineered feedforward neural networks as a result of evolving pathology.

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Section: Discussionsupporting

confidence: 89%

Evolving alterations of structural organization and functional connectivity in feedforward neural networks after induced P301L tau mutation

Weir,

Hanssen,

Winter-Hjelm

et al. 2023

Preprint

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“…The timing of media change relative to the time of recording is also likely to affect network activity. For example, human motor neurons were found to have a higher firing frequency 24 hours after media change compared to 48 hours after media change (Fiskum et al, 2021). The fact that we recorded activity 72 hours after media change may thus contribute to the very low burst propensity exhibited in our networks.…”

Section: Discussionmentioning

confidence: 99%

“…A signal was defined and recorded as a spike when reaching beyond a differential threshold of 7.5 times the standard deviation of the background activity. Firing rate and burst propensity (a measure of fraction of spikes in networks bursts) were analysed using an in-house made MATLAB script, reported previously (Fiskum et al, 2021). A network burst was identified when a binned spike distribution of 50ms bins exceeded a threshold of firing rate of 7.5 standard deviations and more than 20% of all active electrodes in the recording fired.…”

Section: Methodsmentioning

confidence: 99%

Microdissection and culturing of adult lateral entorhinal cortex layer II neurons from APP/PS1 Alzheimer model mice

Hanssen

Sandvig

et al. 2022

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Background: Primary neuronal cultures enable cell-biological studies of Alzheimer's disease (AD), albeit typically non-neuron-specific. The first cortical neurons affected in AD reside in layer II of the lateralmost part of the entorhinal cortex, and they undergo early accumulation of intracellular amyloid-β, form subsequent tau pathology, and start degenerating pre-symptomatically. These vulnerable entorhinal neurons uniquely express the glycoprotein reelin and provide selective inputs to the hippocampal memory system. Gaining a more direct access to study these neurons is therefore highly relevant. New method: We demonstrate a methodological approach for microdissection and long-term culturing of adult lateral entorhinal layer II-neurons from AD-model mice. Results: We maintain adult microdissected lateralmost entorhinal layer II-neurons beyond two months in culture. We show that they express neuronal markers, and that they are electrophysiologically active by 15 days in vitro and continuing beyond 2 months. Comparison with existing methods: Primary neurons are typically harvested from embryonic or early postnatal brains because such neurons are easier to culture compared to adult neurons. Methods to culture adult primary neurons have been reported, however, to our knowledge, culturing of adult entorhinal subregion-specific primary neurons from AD-model animals has not been reported. Conclusions: Our methodological approach offers a window to study initial pathological changes in the AD disease-cascade. This includes the study of proteinopathy, single-neuron changes, and network-level dysfunction.

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“…For further information see S3 Table It should also be noted that the rate of membrane depolarization increases as the available oxygen concentration at the neuron decreases. This behaviour was reported in both brain slices and in vitro cultures exposed to hypoxia [64,[67][68][69][70], and can be explained by the fact that a reduced availability of oxygen causes a break in the homeostatic maintenance of ion concentrations between inner and outer neuron environments, which is responsible for sustaining the electrical activity of the neuron. Essentially, when oxygen levels are reduced, the Na + -K + -ATP pump lacks resources for fuelling ion transport.…”

Section: Discussionmentioning

confidence: 77%

Digitoids: a novel computational platform for mimicking oxygen-dependent firing dynamics inin vitroneuronal networks

Fabbri,

Ahluwalia,

Magliaro

2023

Preprint

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In vitromodels of neural tissues are crucial to gain new insights on the pathophysiology of the brain. However, cell cultures are associated with many drawbacks and difficulties, e.g., technical complexities, ethical problems and high cost. Computational model-based solutions could represent an important tool to support the study of neuron function. In this work we present a novel computational platform where digital neuronal networks, i.e., Digitoids, can be developed with different size and layouts. The Digitoids rely on a novel firing model where the dependence on oxygen concentration is introduced, since it is a crucial limiting factor in cell cultures. To validate the performance of the platform, Digitoids were developed with the same morphological arrangement as observed in neuron monolayersin vitro. The comparison between the functional output of the Digitoids and the experimental data are not statistically different. The platform delivers a flexible digital tool that can easily be adapted for mimickingin vitromodels with increasing complexity and can be exploited to optimize the laboratory experiments involving neuron cultures.Author SummaryThe use of cell models within laboratories is crucial to gain new understandings of the functioning of neuronal assemblies. However, culturing cells requires highly skilled personnel, a huge quantity of disposable materials and is thus associated with elevated costs. To overcome these limitations, the use of computer-based systems that reproduce the electrical behaviour of neurons can be employed. Sincein vitromodels are vessel-free, we present a novel computational model of neuron electrophysiology, where we introduce the dependence on local oxygen concentration Indeed, oxygen affects the metabolism and the function of cultured neurons. Thanks to our model and platform, we are able to reproduce the morphology of the cultured networks of neurons and build the so-calledDigitoids. We then simulate theDigitoidsand obtain their electrophysiological output. We compared theDigitoids’output with experimental data from neurons cultured on microelectrode arrays. We did not find any differences between the electrophysiological output of theDigitoidsand the experimental data, therefore we conclude that our novel oxygen-dependent model can be used to develop more physiologically relevant tools for simulating the activity of cultured neurons.

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Silencing of Activity During Hypoxia Improves Functional Outcomes in Motor Neuron Networks in vitro

Cited by 10 publications

References 51 publications

Evolving alterations of structural organization and functional connectivity in feedforward neural networks after induced P301L tau mutation

Evolving alterations of structural organization and functional connectivity in feedforward neural networks after induced P301L tau mutation

Microdissection and culturing of adult lateral entorhinal cortex layer II neurons from APP/PS1 Alzheimer model mice

Digitoids: a novel computational platform for mimicking oxygen-dependent firing dynamics inin vitroneuronal networks

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