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We hope you have enjoyed this limited-length demo
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- View The Talks
-
1. Homeostasis
- Dr. Charles Sevigny
-
2. Membrane potential
- Dr. Charles Sevigny
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3. Action potentials
- Dr. Charles Sevigny
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4. Synaptic transmission and graded potentials
- Dr. Charles Sevigny
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5. Simple circuits
- Dr. Angelina Fong
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6. Sensory systems
- Dr. Angelina Fong
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7. Renal function: excretory system
- Dr. Jessica Briffa
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8. Renal function: filtration and clearance
- Dr. Jessica Briffa
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9. Renal function: sodium balance
- Dr. Jessica Briffa
-
10. Renal function: water balance
- Dr. Jessica Briffa
-
11. The reproductive system: gametogenesis and the ovarian cycle
- Dr. Victoria Garside
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12. The reproductive system: fertilisation, pregnancy, parturition and birth
- Dr. Victoria Garside
Printable Handouts
Navigable Slide Index
- Introduction
- Every action requires a circuit
- Initiation and action
- Simple circuits
- Simple circuits: excitatory neurones
- Simple circuits: inhibitory neurones
- Simple circuits: activity of neurone B
- Simple circuits: resultant activity of neurone B
- Simple circuits: activity of neurone C
- Simple circuits: resultant activity of neurone C
- Advanced simple circuits
- Advanced simple circuits: result
- Advanced simple circuits: three neurones
- Advanced simple circuits: three neurones resultant activity
- Simple circuits with inhibitory neurones
- Simple circuits with inhibitory neurones: result
- Simple reflex circuit
- Simple reflex circuit in detail
- Simple reflex circuit: interneuron
- Simple reflex circuit: interneuron result
- Simple reflex circuit: excitatory neurones
- Simple reflex circuit: excitatory neurones result
- Simple reflex circuit: excitatory and inhibitory neurones
- Simple reflex circuit: excitatory and inhibitory neurones result
- Convergent circuits
- Divergent circuits
- Convergent/divergent circuits
- Convergent/divergent circuits: neurone X activity
- Convergent/divergent circuits: neurone X activity result
- Conclusion
Topics Covered
- Neuronal activity
- Neuronal networks
- Excitatory neurons
- Inhibitory neurons
- Advanced simple circuits
- Feedback loops
- Reflex
- Convergent and divergent circuits
Links
Series:
Categories:
Therapeutic Areas:
Talk Citation
Fong, A. (2024, January 31). Simple circuits [Video file]. In The Biomedical & Life Sciences Collection, Henry Stewart Talks. Retrieved December 26, 2024, from https://doi.org/10.69645/JSNZ5590.Export Citation (RIS)
Publication History
Financial Disclosures
- There are no commercial/financial matters to disclose.
A selection of talks on Neuroscience
Transcript
Please wait while the transcript is being prepared...
0:00
Hi, I'm Dr. Angelina Fong,
senior lecturer from
the Department of
Anatomy and Physiology
at the University of
Melbourne in Australia.
In this recording,
we're going to cover
simple circuits as part of
the fundamentals of
human physiology.
You might be wondering
what the circuits have
to do with physiology.
Let's find out.
0:24
Imagine that every
action that you do,
whether consciously
or subconsciously,
requires a circuit that
takes the initiation or
the sort and translates
it into the final output.
Whether you're
going for a run or
speaking or simply
just swallowing,
all of these actions
that your body
performs requires a circuit.
0:50
We need to have an initiator or
trigger that will lead to
an action or an effect.
For this to happen, we must
have an output part of
the circuit that takes
the information from the
trigger to the action.
Once we produce the
action or the effect,
there are often feedback
mechanisms that will cause
a reflex response to
the initiator or the trigger
to change what that
trigger might be.
There are names of these
different parts of the circuit,
called efferent for
the output part
and afferent for the input part.
These are terms that we'll
come back to in the future,
but I just want to show you
what these circuits
might look like.
Now, this is a very
simple loop circuit.
But what is involved
in these circuits?