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Printable Handouts
Navigable Slide Index
- Introduction
- Brain Glia
- A couple of things to remember about astroglia (1)
- A couple of things to remember about astroglia (2)
- A couple of things to remember about astroglia (3)
- Since the past two decades it turned out that astrocytes also
- Monitoring astroglial Ca2+ signalling ex vivo
- Monitoring astroglial Ca2+ signalling in vivo (awake) (1)
- Monitoring astroglial Ca2+ signalling in vivo (awake) (2)
- Some major pathways of Ca2+ signalling in astroglia
- Summary
- Lecture plan: three chapters
- Spatial filtering due to diffraction limit of light
- Spatiotemporal filtering due to Ca2+/Ca2+ indicator diffusion-reaction
- Different [Ca2+] dynamics could generate similar fluorescence readout
- Interim conclusion (1)
- Ca2+ signalling dynamics depends on the resting (nanomolar) [Ca2+] level
- Monitoring nanomolar Ca2+ using a time-domain measure – FLIM
- Monitoring basal nanomolar Ca2+ using 3D FLIM
- Astrocytic Ca2+ landscapes in situ and in vivo (1)
- Astrocytic Ca2+ landscapes in situ and in vivo (2)
- Astrocytic Ca2+ landscapes in situ and in vivo (3)
- Interim conclusion (2)
- Resting [Ca2+] versus spontaneous Ca2+ signals
- Resting [Ca2+] versus exogenously evoked Ca2+ signals
- Resting [Ca2+] versus physiologically evoked Ca2+ signals
- In this dependence a constituent or adaptive feature?
- Interim conclusion (3)
- Building a realistic astrocyte model using ASTRO+NEURON (1)
- Building a realistic astrocyte model using ASTRO+NEURON (2)
- Building a realistic astrocyte model using ASTRO+NEURON (3)
- Building a realistic astrocyte model using ASTRO+NEURON (4)
- Running a realistic astrocyte model using ASTRO+NEURON (examples)
- Conclusions
- Funding and collaborators
Topics Covered
- Astrocytes
- Astroglia
- Glia
- Calcium signalling
- Three Dimensional Electron Microscopy
- Alexa Fluor 594
- Oregon Green 488 BAPTA-1
- Monitoring resting calcium
- Fluorescence recordings
- Fluorescence lifetime imaging microscopy
- Astrocyte model
Links
Series:
Categories:
Therapeutic Areas:
External Links
Talk Citation
Rusakov, D. (2022, June 29). Astroglial calcium signalling: what it could tell us [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 26, 2024, from https://doi.org/10.69645/ILBZ5033.Export Citation (RIS)
Publication History
Financial Disclosures
- Prof. Dmitri Rusakov has not informed HSTalks of any commercial/financial relationship that it is appropriate to disclose.
A selection of talks on Neurology
Transcript
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0:00
Today we'll talk about
astroglial calcium signalling
and what it could
actually tell us.
0:10
A brief reminder.
Among brain glia,
astroglia are the most
abundant type of cells,
which have long been associated
with their classical roles:
Rapid uptake of the excitatory
neurotransmitter glutamate
via high affinity transporters,
buffering external potassium
that rises upon neural activity,
enabling the
brain-blood-barrier.
0:38
Couple of things to
remember about astroglia.
Nanoscopic astroglia
protrusions can
closely approach
excitatory synapses,
which has been shown
by 3D EM for instance.
If you look at the
astroglia fragment
and adjacent dendritic spines
with postsynaptic density,
this is what it looks like,
a fragment of astroglia plus
dendritic spines
minus astroglia,
just to give you an idea
of what happens in 3D.
1:10
Other reminders are that
individual astrocytes
occupy separate spatial domains,
overlapping very little
by 5, 10 percent perhaps.
Each neuron is approached
by many astroglia,
and each astrocyte covers
processes of many neurons.
1:30
Also, astrocytes are widely
connected through gap junctions.
If you patch an
individual astroglia with
a bright morphological
tracer, like Alexa Fluor,
you can see plenty of gap
junction-connected cells
because Alexa goes
through gap junctions.
These gap junctions are
built by connexin proteins.