Cholinergic modulation of cortical oscillatory dynamics

Liljenström, Hans; Hasselmo, M. E.

doi:10.1152/jn.1995.74.1.288

Cited by 108 publications

(56 citation statements)

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“…Neuromodulators generally have multiple effects in cortical circuits. For instance, they can change the DC firing rate of the neuron 37,38 ; this particular effect can be modelled as an additional depolarizing or hyperpolarizing current. Hence, in the model described above, neuromodulators can in principle alter the DC firing rate so that it approximately matches the oscillation frequency of the network that the neuron is embedded in.…”

Section: Stimulus Locking and Phase Lockingmentioning

confidence: 99%

Regulation of spike timing in visual cortical circuits

2008

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A train of action potentials (a spike train) can carry information in both the average firing rate and the pattern of spikes in the train. But can such a spike-pattern code be supported by cortical circuits? Neurons in vitro produce a spike pattern in response to the injection of a fluctuating current. However, cortical neurons in vivo are modulated by local oscillatory neuronal activity and by top-down inputs. In a cortical circuit, precise spike patterns thus reflect the interaction between internally generated activity and sensory information encoded by input spike trains. We review the evidence for precise and reliable spike timing in the cortex and discuss its computational role.Reliability and precision are two different quantities. When you make an appointment with your friend, she can either keep the appointment or not show up at all. If she does show up, she might or might not be on time. The former uncertainty is related to reliability, whereas the latter is related to precision. When the same stimulus waveform is repeatedly injected at the soma of a neuron in vitro (FIG. 1a), a similar spike train is obtained on each trial 1,2 (FIG. 1b). When approximately the same number of spikes occur on each trial the neuron is said to be reliable, whereas when the spikes occur almost at the same time across trials it is said to be precise (FIG. 1c). For a single neuron, the potential information content of precise and reliable spike times is many times larger than that which is contained in the firing rate, which is averaged across a typical interval of a hundred milliseconds [3][4][5][6] . The information contained in spike timing is available immediately, rather than after an averaging period. Furthermore, the timing of patterns of spikes can potentially transmit even more information than the timing of the individual constituent spikes 3,7 . The potential relevance of spike patterns becomes apparent when we consider neurons at the population level: when a group of similar neurons (a 'pool') produces precise and reliable spike trains, the neurons they project to receive volleys of synchronous spikes 8,9 . This opens up the possibility of communicating between different cortical areas through synchronous spike volleys.In contrast to the in vitro situation described above, in the intact cortex most excitatory synaptic inputs arrive at the dendrites rather than at the soma (FIG. 1d), and synaptic transmission is typically unreliable [10][11][12][13] . Furthermore, most of these dendritic inputs are not directly related to ongoing sensory stimulation; rather, they reflect spatiotemporally structured internal activity. Therefore, when the same stimulus is presented repeatedly, the resulting spike trains are usually neither precise nor reliable when they are aligned to the stimulus onset 6 . Instead, HHMI Author ManuscriptHHMI Author Manuscript HHMI Author Manuscript neural activity in vivo might be dominated by internally generated complex reverberations or rhythmic oscillations, and precise and reliable sp...

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Section: Stimulus Locking and Phase Lockingmentioning

confidence: 99%

Regulation of spike timing in visual cortical circuits

2008

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“…A number of papers addressed the generation of theta rhythms in the hippocampus using biophysical models (Traub et al, 1992;Liljenstrom and Hasselmo, 1995;Wallenstein and Hasselmo, 1997a,b;Finkel, 1998, 1999). Traub et al (1992) found carbachol-induced theta-frequency oscillations in a model of the CA3 region of hippocampus.…”

Section: Network Oscillation Mechanismsmentioning

confidence: 99%

Computational model of carbachol‐induced delta, theta, and gamma oscillations in the hippocampus

et al. 2001

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“…Parameter values used for these simulations are, as far as possible, based on physiological and anatomical data, but some parameters, such as connection weights (synaptic strengths), levels of neuromodulation, etc were not possible to obtain from the experimental data, and had to be tuned. We have previously shown that our cortical neural network model can reproduce essential characteristics of olfactory cortex and hippocampus neurodynamics (Liljenström, 1991(Liljenström, , 1995(Liljenström, , 1997Liljenström and Hasselmo, 1995;Liljenström and Wu, 1995;Å rhem and Liljenström, 2001). It describes intrinsic oscillatory properties of these structures, and reproduces response patterns associated with a continuous random input signal and with a shock pulse given to the cortex.…”

Section: Resultsmentioning

confidence: 97%

“…A mathematical description of the model is summarized below. (A more detailed description with parameter values, etc can be found in Liljenström, 1991;Liljenström and Hasselmo, 1995. ) The time evolution for a network of N neural units is given by a set of coupled nonlinear first-order differential delay equations for all the N internal states, u.…”

Section: Methodsmentioning

confidence: 99%

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Neural Stability and Flexibility: A Computational Approach

Liljenström¹

2003

Neuropsychopharmacol

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This paper addresses the issue of stability and flexibility of neural systems, and how a balance can be achieved. Assuming a close correspondence with cognitive and mental processes, we use a cortical neural network model to investigate how regulation of the neurodynamics can result in an efficient information processing, in terms of learning and associative memory. In particular, we use this model to investigate relations between structure, dynamics, and function of a neural system, and how the stability-flexibility dilemma may be solved by proper regulation. We focus on the complex neurodynamics and its modulation, and how this is related to the neural circuitry, where synaptic modification and network pruning are considered. Finally, we discuss the relevance of these results to clinical and experimental neuroscience and speculate on a link between neural instability and mental disorders.

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Cholinergic modulation of cortical oscillatory dynamics

Cited by 108 publications

References 0 publications

Regulation of spike timing in visual cortical circuits

Regulation of spike timing in visual cortical circuits

Computational model of carbachol‐induced delta, theta, and gamma oscillations in the hippocampus

Neural Stability and Flexibility: A Computational Approach

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