An investigation into the occurrence of nonlinear attractor in cellular dynamics
High resolution observation of a cellular system of which the components are on the scale of micro-meters or smaller is typically thwarted by several aspects: the difficulty to obtain the signal from the subject itself, the high irregularity of the biological environment, and the measurement n...
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| Format: | Theses and Dissertations |
| Language: | English |
| Published: |
2018
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| Online Access: | http://hdl.handle.net/10356/75939 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | High resolution observation of a cellular system of which the components are
on the scale of micro-meters or smaller is typically thwarted by several
aspects: the difficulty to obtain the signal from the subject itself, the high
irregularity of the biological environment, and the measurement noise.
Quantitative research over this subject, because of this, could not be easy.
However, when we view the system from the perspective of attractors and its
properties, it is possible to achieve better understanding of the dynamics of
cellular processes even with the observations of limited resolution. In this
thesis, we present our research on biochemical network and neuronal network
from the perspective of the occurrence of nonlinear attractors in them.
In the chapter on biochemical network, we discuss the different statistical
property between two attractors that induces rhythmic behavior while
interacting with intrinsic noise: limit cycle and weakly attracting stable
spiral. The first type of attractor gives rise to rhythmic behavior from its
deterministic dynamics alone, noise only perturbs the already existing
oscillation, giving it variation; the second type of attractor gives rise to
rhythmic behavior only through its interaction with noise, hence both the
oscillation amplitude and its variation are closely related to the strength of
the noise. Because of this difference, the statistics of the rhythmic behavior
induced by these two attractors behave differently when system size changes.
Based on our theoretical result, a new method is proposed to determine which
of these two mechanisms act behind an observed rhythmic behavior in
biochemical system. In particular, we have applied our method in a subsequent
chapter to in vitro hes1 data. We have uncovered that the observed hes1
rhythmic behavior is driven by Hopf bifurcation induced limit cycle in its
deterministic dynamics.
Finally in the chapter on neuronal network, we explored into the possible
presence of a chaotic attractor. Our results established that if a chaotic
attractor do exist, it cannot possess an embedding dimension of 10 and less.
Our analysis instead found that the neuronal network potentially exhibits a
critical attractor that arises from the phenomenon of self-organized
criticality. Ongoing research is actively being pursued to affirm this latter
result definitely. |
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