Quantitative examination of stimulus-response relations in cortical networks in vitro

Weihberger, Oliver; Okujeni, Samora; Mikkonen, Jarno E.; Egert, Ulrich

doi:10.1152/jn.00481.2012

Cited by 40 publications

(52 citation statements)

References 55 publications

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“…Hence, they might interfere with our capacity to interpret the impacts of stimulation on response dynamics (Wallach and Marom, 2012; Weihberger et al, 2013). Network spikes may be suppressed by pharmacological blockage of NMDA channels in cultured cortical networks (Robinson et al, 1993; Jimbo et al, 2000; Bonzano et al, 2006).…”

Section: Methodsmentioning

confidence: 99%

Synaptic dynamics contribute to long-term single neuron response fluctuations

Reinartz¹,

Bíró²,

Gal³

et al. 2014

Front. Neural Circuits

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Firing rate variability at the single neuron level is characterized by long-memory processes and complex statistics over a wide range of time scales (from milliseconds up to several hours). Here, we focus on the contribution of non-stationary efficacy of the ensemble of synapses–activated in response to a given stimulus–on single neuron response variability. We present and validate a method tailored for controlled and specific long-term activation of a single cortical neuron in vitro via synaptic or antidromic stimulation, enabling a clear separation between two determinants of neuronal response variability: membrane excitability dynamics vs. synaptic dynamics. Applying this method we show that, within the range of physiological activation frequencies, the synaptic ensemble of a given neuron is a key contributor to the neuronal response variability, long-memory processes and complex statistics observed over extended time scales. Synaptic transmission dynamics impact on response variability in stimulation rates that are substantially lower compared to stimulation rates that drive excitability resources to fluctuate. Implications to network embedded neurons are discussed.

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Section: Methodsmentioning

confidence: 99%

Synaptic dynamics contribute to long-term single neuron response fluctuations

Reinartz¹,

Bíró²,

Gal³

et al. 2014

Front. Neural Circuits

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“…This preparation proved useful, over the past 10–15 years, as a toy model in the study of functional network processes, ranging from development and adaptation to learning and stimulus representation (Maeda et al, 1995; Kamioka et al, 1996; Jimbo et al, 1998, 1999; Tateno and Jimbo, 1999; Shahaf and Marom, 2001; Corner et al, 2002; Eytan et al, 2003; Shahaf et al, 2008). A recent series of studies demonstrated the efficacy of several closed loop applications in controlling aspects of activity in these in vitro large-scale cortical networks (e.g., Wagenaar and Potter, 2004; Wagenaar et al, 2005; Arsiero et al, 2007; Rolston et al, 2010; Wallach et al, 2011; Weihberger et al, 2013). Here we implement one of these approaches, the so-called “response-clamp” procedure: a PI (Proportional-Integral) negative feedback algorithm (Wallach et al, 2011; Wallach, 2013), in order to control response features in vitro .…”

Section: Introductionmentioning

confidence: 99%

Controlling neural network responsiveness: tradeoffs and constraints

Keren

Marom

2014

FNENG

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In recent years much effort is invested in means to control neural population responses at the whole brain level, within the context of developing advanced medical applications. The tradeoffs and constraints involved, however, remain elusive due to obvious complications entailed by studying whole brain dynamics. Here, we present effective control of response features (probability and latency) of cortical networks in vitro over many hours, and offer this approach as an experimental toy for studying controllability of neural networks in the wider context. Exercising this approach we show that enforcement of stable high activity rates by means of closed loop control may enhance alteration of underlying global input–output relations and activity dependent dispersion of neuronal pair-wise correlations across the network.

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“…1 or ∞). Based on previous results reported in the literature for regular stimulation [49, 50], we chose 0.2 Hz as a separation frequency in order to distinguish between two different conditions: time-dependence (MSR > 0.2 Hz) or independence (MSR < 0.2 Hz) of responses to subsequent stimuli. It is possible to note how the network preference for irregular stimulation sequences described above holds true only for fast sequences (i.e.…”

Section: Resultsmentioning

confidence: 99%

“…In 2013, a paper published by the group of Egert [50] suggested that strength and duration of neural network responses to electrical stimulations followed an exponential saturating profile as a function of the length of the preceding inactivity period. These results were compatible with short-term synaptic depression caused by bursts, due to depletion of readily releasable pool of neurotransmitter vesicles, also in conjunction with GABAergic inhibition (see Discussion of [50]).…”

Section: Discussionmentioning

confidence: 99%

Investigating the impact of electrical stimulation temporal distribution on cortical network responses

et al. 2017

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BackgroundThe brain is continuously targeted by a wealth of stimuli with complex spatio-temporal patterns and has presumably evolved in order to cope with those inputs in an optimal way. Previous studies investigating the response capabilities of either single neurons or intact sensory systems to external stimulation demonstrated that stimuli temporal distribution is an important, if often overlooked, parameter.ResultsIn this study we investigated how cortical networks plated over micro-electrode arrays respond to different stimulation sequences in which inter-pulse intervals followed a 1/f β distribution, for different values of β ranging from 0 to ∞. Cross-correlation analysis revealed that network activity preferentially synchronizes with external input sequences featuring β closer to 1 and, in any case, never for regular (i.e. fixed-frequency) stimulation sequences. We then tested the interplay between different average stimulation frequencies (based on the intrinsic firing/bursting frequency of the network) for two selected values of β, i.e. 1 (scale free) and ∞ (regular). In general, we observed no preference for stimulation frequencies matching the endogenous rhythms of the network. Moreover, we found that in case of regular stimulation the capability of the network to follow the stimulation sequence was negatively correlated to the absolute stimulation frequency, whereas using scale-free stimulation cross-correlation between input and output sequences was independent from average input frequency.ConclusionsOur results point out that the preference for a scale-free distribution of the stimuli is observed also at network level and should be taken into account in designing more efficient protocols for neuromodulation purposes.Electronic supplementary materialThe online version of this article (doi:10.1186/s12868-017-0366-z) contains supplementary material, which is available to authorized users.

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Quantitative examination of stimulus-response relations in cortical networks in vitro

Cited by 40 publications

References 55 publications

Synaptic dynamics contribute to long-term single neuron response fluctuations

Synaptic dynamics contribute to long-term single neuron response fluctuations

Controlling neural network responsiveness: tradeoffs and constraints

Investigating the impact of electrical stimulation temporal distribution on cortical network responses

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