On mechanisms of electromechanophysiological interactions between the components of signals in axons
Recent studies have revealed the complex structure of nerve signals in axons. There is experimental evidence that the propagation of an electrical signal (action potential) is accompanied by mechanical and thermal effects. In this paper, first, an overview is presented on experimental results and po...
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Estonian Academy Publishers
2020-03-01
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| Series: | Proceedings of the Estonian Academy of Sciences |
| Online Access: | http://www.kirj.ee/public/proceedings_pdf/2020/issue_2/proc-2020-2-81-96.pdf |
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doaj-bcc281af748f45eea1b8055f6611abaa2020-11-25T03:10:35ZengEstonian Academy PublishersProceedings of the Estonian Academy of Sciences1736-60461736-75302020-03-01692819610.3176/proc.2020.2.0310.3176/proc.2020.2.03On mechanisms of electromechanophysiological interactions between the components of signals in axonsJüri Engelbrecht0Kert Tamm1Tanel Peets2Department of Cybernetics, School of Science, Tallinn University of Technology, Akadeemia tee 21, 12618 Tallinn, Estonia Department of Cybernetics, School of Science, Tallinn University of Technology, Akadeemia tee 21, 12618 Tallinn, Estonia; kert@ioc.eeDepartment of Cybernetics, School of Science, Tallinn University of Technology, Akadeemia tee 21, 12618 Tallinn, EstoniaRecent studies have revealed the complex structure of nerve signals in axons. There is experimental evidence that the propagation of an electrical signal (action potential) is accompanied by mechanical and thermal effects. In this paper, first, an overview is presented on experimental results and possible mechanisms of electromechanophysiological couplings which govern the signal formation in axons. This forms a basis for building up a mathematical model describing an ensemble of waves. Three basic physical mechanisms responsible for coupling are (i) electric-lipid bi-layer interaction resulting in the mechanical wave in biomembrane; (ii) electric-fluid interaction resulting in the mechanical wave in the axoplasm; (iii) electric-fluid interaction resulting in the temperature change in axoplasm. The influence of possible changes in variables which could have a role for interactions are analysed and the concept of internal variables introduced for describing the endothermic processes. The previously proposed mathematical model is modified reflecting the possible physical explanation of these interactions.http://www.kirj.ee/public/proceedings_pdf/2020/issue_2/proc-2020-2-81-96.pdf |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
Jüri Engelbrecht Kert Tamm Tanel Peets |
| spellingShingle |
Jüri Engelbrecht Kert Tamm Tanel Peets On mechanisms of electromechanophysiological interactions between the components of signals in axons Proceedings of the Estonian Academy of Sciences |
| author_facet |
Jüri Engelbrecht Kert Tamm Tanel Peets |
| author_sort |
Jüri Engelbrecht |
| title |
On mechanisms of electromechanophysiological interactions between the components of signals in axons |
| title_short |
On mechanisms of electromechanophysiological interactions between the components of signals in axons |
| title_full |
On mechanisms of electromechanophysiological interactions between the components of signals in axons |
| title_fullStr |
On mechanisms of electromechanophysiological interactions between the components of signals in axons |
| title_full_unstemmed |
On mechanisms of electromechanophysiological interactions between the components of signals in axons |
| title_sort |
on mechanisms of electromechanophysiological interactions between the components of signals in axons |
| publisher |
Estonian Academy Publishers |
| series |
Proceedings of the Estonian Academy of Sciences |
| issn |
1736-6046 1736-7530 |
| publishDate |
2020-03-01 |
| description |
Recent studies have revealed the complex structure of nerve signals in axons. There is experimental evidence that the propagation of an electrical signal (action potential) is accompanied by mechanical and thermal effects. In this paper, first, an overview is presented on experimental results and possible mechanisms of electromechanophysiological couplings which govern the signal formation in axons. This forms a basis for building up a mathematical model describing an ensemble of waves. Three basic physical mechanisms responsible for coupling are (i) electric-lipid bi-layer interaction resulting in the mechanical wave in biomembrane; (ii) electric-fluid interaction resulting in the mechanical wave in the axoplasm; (iii) electric-fluid interaction resulting in the temperature change in axoplasm. The influence of possible changes in variables which could have a role for interactions are analysed and the concept of internal variables introduced for describing the endothermic processes. The previously proposed mathematical model is modified reflecting the possible physical explanation of these interactions. |
| url |
http://www.kirj.ee/public/proceedings_pdf/2020/issue_2/proc-2020-2-81-96.pdf |
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AT juriengelbrecht onmechanismsofelectromechanophysiologicalinteractionsbetweenthecomponentsofsignalsinaxons AT kerttamm onmechanismsofelectromechanophysiologicalinteractionsbetweenthecomponentsofsignalsinaxons AT tanelpeets onmechanismsofelectromechanophysiologicalinteractionsbetweenthecomponentsofsignalsinaxons |
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