Physics of Biological Oscillators [E-Book] : New Insights into Non-Equilibrium and Non-Autonomous Systems / edited by Aneta Stefanovska, Peter V. E. McClintock.
This book, based on a selection of invited presentations from a topical workshop, focusses on time-variable oscillations and their interactions. The problem is challenging, because the origin of the time variability is usually unknown. In mathematical terms, the oscillations are non-autonomous, refl...
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Full text |
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Personal Name(s): | McClintock, Peter V. E., editor |
Stefanovska, Aneta, editor | |
Edition: |
1st edition 2021. |
Imprint: |
Cham :
Springer,
2021
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Physical Description: |
XXIV, 431 pages 111 illustrations, 96 illustrations in color (online resource) |
Note: |
englisch |
ISBN: |
9783030598051 |
DOI: |
10.1007/978-3-030-59805-1 |
Series Title: |
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Understanding Complex Systems
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Subject (LOC): |
- Chapter 1. Introduction
- Part 1. Theory
- Chapter 2. Phase and amplitude description of complex oscillatory patterns in reaction diffusion systems
- Chapter 3. Reduced phase models of oscillatory neural networks
- Chapter 4. Nonautonomous attractors
- Chapter 5. Normal hyperbolicity for non-autonomous oscillators and oscillator networks
- Chapter 6. Synchronisation and non-autonomicity
- Chapter 7. Non-asymptotic-time dynamics
- Chapter 8. Synchronization of coupled oscillators - phase transitions and entropy production
- Part 2. Model-Driven and Data-Driven approaches
- Chapter 9. On localised modes in bio-inspired hierarchically organised oscillatory chains
- Chapter 10. Useful transformations from non-autonomous to autonomous systems
- Chapter 11. Coupling functions in neuroscience
- Chapter 12. Phase reconstruction with iterated Hilbert transforms
- Part 3. Biological Oscillators
- Chapter 13. Oscillations in yeast glycolysis Lars Folke Olsen and Anita Lunding
- Chapter 14. Oscillations, rhythms and synchronized time bases: the key signatures of life
- Chapter 15. Glycolytic oscillations in cancer cells
- Chapter 16. Mechanism and consequence of vasomotion
- Chapter 17. Biological oscillations of vascular origin and their meaning: in vivo studies of arteriolar vasomotion
- Chapter 18. Phase coherence of finger skin blood flow oscillations induced by controlled breathing in humans
- Chapter 19. Complexity-based analysis of microvascular blood flow in human skin
- Chapter 20. Modulations of heart rate, ECG, and cardio-respiratory coupling observed in polysomnography
- Chapter 21. Brain morphological and functional networks: implications for neurodegeneration
- Part 4. Applications
- Chapter 22. Predicting epileptic seizures - an update
- Chapter 23. General anæsthesia and oscillations in human physiology: the BRACCIA project
- Chapter 24. Processed EEG as a measure of brain activity during anaesthesia
- Chapter 25. Medical products inspired by biological oscillators: intermittent pneumatic compression and the microcirculation
- Chapter 26. Phase coherence between cardiovascular oscillations in malaria: the basis for a possible diagnostic test
- Part 5. Outlook
- Chapter 27. Outlook.