Microfiber platform for oligodendrocyte myelination
Injuries or disorders in the central nervous system disrupt crucial sensory and motor functions. This critical system has limited regenerative capability, often contributes directly to permanent disabilities in afflicted adults. Limited regenerative capability is likely a result of the disruption...
Saved in:
| Main Author: | |
|---|---|
| Other Authors: | |
| Format: | Thesis-Doctor of Philosophy |
| Language: | English |
| Published: |
Nanyang Technological University
2020
|
| Subjects: | |
| Online Access: | https://hdl.handle.net/10356/136941 |
| Tags: |
Add Tag
No Tags, Be the first to tag this record!
|
| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Injuries or disorders in the central nervous system disrupt crucial sensory and motor
functions. This critical system has limited regenerative capability, often contributes directly
to permanent disabilities in afflicted adults. Limited regenerative capability is likely a result of
the disruption of the intrinsic nervous system environment following injuries and diseases.
The lack of treatment options stems from our lack of understanding of nervous tissue
regeneration and alteration in nerve cellular microenvironment. As such, recent studies
focused on unveiling the cellular biology of nervous system, zooming in on events following
distress to uncover specific mechanisms that impede tissue regrowth and functional recovery.
In this thesis, we developed platforms to help enhance our understanding of the nervous
system with clever engineering. Specifically, we developed an artificial fiber-based platform
for oligodendrocyte myelination. Our systems deliver simple solutions to study the complex
process of multilamellar wrapping by oligodendrocyte, which is crucial in maintaining the
functions of the central nervous system. We model intrinsic axons and the nervous system
microenvironment with suitable materials and structures, to study the mechanobiology of
oligodendrocyte myelination.
We first optimized the oligodendrocyte myelin-artificial axons culture in vitro to
evaluate the feasibility of attaining physiologically relevant myelination with electrospun
fibers. With appropriate biophysical and chemical cues, oligodendrocytes produced robust
multilamellar myelin sheaths surrounding artificial axons engineered with synthetic polymers.
Morphologically, we observed concentric wrapping around our electrospun fibers, mimicking
closely the physiological central nervous system myelination. We developed a drug/gene
screening platform designed as a quick, simple and cheap alternative to animal testing. Using
molecules known to promote oligodendrocyte myelination, we showed that our
physiologically relevant system produced readouts similar to animal experiments, thereby
highlighting it as an efficient platform to screen potential therapeutics targeting
remyelination.
To further enhance the utility of our artificial axons drug/gene screening platform, we
evaluated the efficacy of incorporating engineered mesoporous silica nanoparticles in our
system for neuronal cells. We achieved highly efficient uptake of RNA by all major neuronal
and glia cells through optimization of particles to RNA ratio. With the particles-RNA complex,
we performed gene silencing experiments to highlight the efficacy of incorporated
nanoparticles. In comparison to commercial transfection reagents, our engineered particles
displayed similar silencing efficacy on our screening platform.
We further developed our artificial axons platform to study the mechanobiology of
oligodendrocyte myelination. Using three-point bending theory, we established a tunable
structural stiffness platform, which decouples stiffness from other biophysical cues, to
investigate the effect of pathological stiffening of microenvironment on oligodendrocyte
myelination. We demonstrated that increasing structural stiffness promotes oligodendrocyte
precursor differentiation, which was validated with conventional two-dimensional tunable
stiffness hydrogels. Moreover, for the first time, we demonstrated with our artificial axonbased
tunable stiffness, that an increase in structural stiffness impedes oligodendrocyte
myelination. We investigated the role of YAP signaling in the mechanotransduction of
oligodendrocyte and observed translocation of YAP into oligodendrocyte nucleus in high
stiffness microenvironment. When examined the crucial actin turnover process required for
myelination, we observed significantly higher F-actin ratio in high stiffness microenvironment,
suggesting an obstructed actin disassembly process.
We extended our tunable structural stiffness platform to study the effect of intrinsic
axonal stiffness on oligodendrocyte myelination. By controlling the crystallinity of artificial
axons, we demonstrated tunable intrinsic stiffness in individual fibers. Similar to tunable
structural stiffness platform, our intrinsic stiffness platform decouples the changes in intrinsic
stiffness from other biophysical parameters that could influence myelination. Using this novel
platform, we demonstrated that high intrinsic stiffness of individual artificial axons hinders
oligodendrocyte myelination.
Taken together, this thesis advanced the utility of an electrospun polymer-based
artificial axons platform for oligodendrocyte myelination. Crucially, platforms introduced in
this thesis help accelerate the drug discovery process for myelin degenerative diseases and
improve our understanding of myelination. |
|---|