Arseniy Gladkov
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Explore the profile of Arseniy Gladkov including associated specialties, affiliations and a list of published articles.
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9
Citations
94
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Recent Articles
1.
Pigareva Y, Gladkov A, Kolpakov V, Kazantsev V, Mukhina I, Pimashkin A
Micromachines (Basel)
. 2024 Jun;
15(6).
PMID: 38930702
Modern microtechnology methods are widely used to create neural networks on a chip with a connection architecture demonstrating properties of modularity and hierarchy similar to brain networks. Such in vitro...
2.
Pigareva Y, Gladkov A, Kolpakov V, Bukatin A, Li S, Kazantsev V, et al.
Micromachines (Basel)
. 2023 Jul;
14(4).
PMID: 37421068
The complex synaptic connectivity architecture of neuronal networks underlies cognition and brain function. However, studying the spiking activity propagation and processing in heterogeneous networks in vivo poses significant challenges. In...
3.
Pigareva Y, Gladkov A, Kolpakov V, Mukhina I, Bukatin A, Kazantsev V, et al.
Brain Sci
. 2021 Jun;
11(6).
PMID: 34071257
The structured organization of connectivity in neural networks is associated with highly efficient information propagation and processing in the brain, in contrast with disordered homogeneous network architectures. Using microfluidic methods,...
4.
Shimba K, Chang C, Asahina T, Moriya F, Kotani K, Jimbo Y, et al.
Front Neurosci
. 2019 Sep;
13:890.
PMID: 31555074
Neuroengineering methods can be effectively used in the design of new approaches to treat central nervous system and brain injury caused by neurotrauma, ischemia, or neurodegenerative disorders. During the last...
5.
Bisio M, Pimashkin A, Buccelli S, Tessadori J, Semprini M, Levi T, et al.
Adv Neurobiol
. 2019 May;
22:351-387.
PMID: 31073944
One of the main limitations preventing the realization of a successful dialogue between the brain and a putative enabling device is the intricacy of brain signals. In this perspective, closed-loop...
6.
Gladkov A, Grinchuk O, Pigareva Y, Mukhina I, Kazantsev V, Pimashkin A
PLoS One
. 2018 Feb;
13(2):e0192468.
PMID: 29415033
The phenomena of synchronization, rhythmogenesis and coherence observed in brain networks are believed to be a dynamic substrate for cognitive functions such as learning and memory. However, researchers are still...
7.
Gladkov A, Pigareva Y, Kutyina D, Kolpakov V, Bukatin A, Mukhina I, et al.
Sci Rep
. 2017 Nov;
7(1):15625.
PMID: 29142321
The architecture of neuron connectivity in brain networks is one of the basic mechanisms by which to organize and sustain a particular function of the brain circuitry. There are areas...
8.
Pimashkin A, Gladkov A, Agrba E, Mukhina I, Kazantsev V
Cogn Neurodyn
. 2016 Jul;
10(4):287-99.
PMID: 27468317
Sensory information can be encoded using the average firing rate and spike occurrence times in neuronal network responses to external stimuli. Decoding or retrieving stimulus characteristics from the response pattern...
9.
Pimashkin A, Gladkov A, Mukhina I, Kazantsev V
Front Neural Circuits
. 2013 Jun;
7:87.
PMID: 23745105
Learning in neuronal networks can be investigated using dissociated cultures on multielectrode arrays supplied with appropriate closed-loop stimulation. It was shown in previous studies that weakly respondent neurons on the...