Brain Cells & Nerve Impulses ( + Textbook Chapter 1 ) Flashcards
Contextualise:
How did Santiago Ramón y Cajal (1852 - 1934) influence the field of neuroscience?
What was his main ‘revelation’?
He utilised staining techniques with silver salts (developed by Camillo Golgi) on infant brain cells to show that each neuron is separate from one another - our neuronal activity is the sum of many interacting parts
(rather than a ‘single unit’ of combined brain cells)
His original aspirations of being an artist helped shape his remarkable illustration abilities in the medicinal field too!
List:
Identify some of the key animal cell aparatus neurons have in common with all other somatic cells:
(disregarding exceptions like red blood cells)
- Cell Membrane (Phospholipid Bilayer)
- Nucleus
- Mitochondria
- Ribosomes
- Endoplasmic Reticulum
Identify:
What are the common structural features of most neurons?
What are some exceptions though?
- Soma (Cell Body)
- Axons ( + Axon Hillock)
- Dendrites
- Presynaptic Terminals
Note: There are some variations in which cells lack axons or clear dendrites
Define:
Dendritic Spines
Purpose?
Small projections along dendrites that help increase the surface area available for receiving synaptic signalling
Describe:
A neuron’s soma (cell body) and one of its primary functions:
The soma contains important structures like the nucleus, mitochondria, and ribosomes - it is the location in the cell at which most of the metobolic work is conducted
Metabolic work may include important functions such as synthesising proteins to be carried in vesicles along microtubules in the axon by transport proteins so that they may be used as neurotransmitters (signals) at the presynaptic terminals
True or False:
The soma (cell body) is also a location of a neuron with synapses along its surface?
True
Contrast:
How are invertebrate neuronal cells different to vertebrates’?
Invertebrates lack any myelinated axons
This means action potentials propogate on average much less quickly compared to those within myelinated vertebrate axons (note: not all vertebrate axons are myelinated though)
Fill-in-the-Blank:
Myelin sheaths are an ‘insulating’ cover along the axons of neurons that have gaps along them known as ____, which allow for ____ conduction. Whereas unmyelinated axons just carry out ____ conduction.
- Nodes of Ranvier
- Saltatory
- Continuous
Explain:
How do myelin sheaths act to increase the speed of action potential conduction along the axon?
Identify the two main mechanisms/factors:
- Increasing Membrane Resistance (i.e. Decreasing Ion Permeability)
- Reducing Membrane Capacitance
- Since ions cannot cross the membrane where the sheath is, they diffuse along to the nodes of Ranvier (where volatge-gated ion channels are at their highest concentration) and continue action potential propagation through rapid depolarisation
- Capicitance relates to how much charge may be stored and therefore how much is required to cause an action potential (lowering this allows easier induction of electrical impulses)
Define & List:
State what a presynaptic terminal is, and give two alternative names for it:
Presynaptic terminals are the terminal/end regions of the branches projecting out from a neuron’s axon at which synapses with other cells are formed and signalling occurs.
Alternative names are ‘end bulb’ and ‘bouton’
Fill-in-the-Blank:
- “An ____ neuron brings information into a structure” (typically referring to PNS > CNS)
- “An ____ neuron carries information away from a structure” (typically referring to CNS > PNS)
- “An ____ neuron [has] dendrites and [an] axon [that] are entirely contained within a single structure”
Source: ‘Biological Psychology’ James W. Kalat 13th Edition
- Afferent
- Efferent
- Inter-/Intrinsic
For example, the cited textbook states an intrinsic neuron in the thalamus would thus have its axon and all its dendrites contained within this brain region
Note: Afferent and efferent are relative descriptors dependent on perspective and which direction an electrical impulse is going in the context etc.
Explain:
Would an interneuron have a comparatively shorter/longer/same-sized axon compared to other neurons?
Why?
It would, on average, be shorter as their structures are constrained to one brain region
Contrast: Some motor neurons can have axons that are metres long!
Identify:
From Left to Right, name each of the basic neuron types and give an example found in the body of each one:
- Unipolar (e.g. afferent/sensory nerves in spinal/cranial regions)
- Bipolar (e.g. some retina nerves)
3.Pseudounipolar (e.g. afferent/sensory nerves in ‘more complex’ nervous systems like humans)
4.Multipolar (e.g. majority in the CNS and some in the ANS)
Note: Unipolar nerves are found in simpler nervous systems/not in humans
True or False:
Glia outnumber neurons in the nervous system
False - recent scientific findings have contradicted this originally accepted notion
Glial cells have greater numbers in the cerebral cortex whilst neurons are the predominant cell of the two in places like the cerebellum
What are actin filaments and how do they contribute to cell function?
They are components of the cytoskeleton that plays vital roles in movement and stability of cells.
Actin is actually one of the smallest structural components of the cytoskeleton, and is a globular protein that binds tightly to other actin proteins in order to make up actin filaments.
Describe:
Microtubules and the role play in cellular functions.
They are hollow tube-like structures that are part of the cytoskeleton network and facilitate the movement of substances/organelles by acting as ‘tracks’ for motor proteins.
(These motor proteins are known as kinesins and dyneins).
They have other functions beyond this too such as assembling the mitotic spindle for cell division, and axon extension in neurons (i.e. providing structural support for both these and dendrites).
What are the TWO key communication mechanisms used by neurons?
Extra: Describe each of the mechanisms briefly.
Chemical Signalling
&
Electrical Signalling
Both involve synapses between two cells.
Chemical signalling requires the release of neurotransmitters, their diffusion across the synaptic cleft, and binding with membrane receptors of the post-synaptic cell. This triggers localised depolarisation/hyperpolarisations.
Electrical signalling involves a more ‘direct’ transfer via gap junctions between cells, which allow passive diffusion of ions/ionic current. This essentially passes an action potential from one cell to the next.
Describe:
The THREE states a voltage-gated sodium channel can be in.
- Resting/Closed: the activation gate is closed and no ions flow through.
- Activated: the activation gate is open and ions flow freely.
- Inactivated: the inactivation gate ‘swings shut’ and ions are blocked from entering the cell.
Note: during the inactivated state, the activation gate is still open, but it’s the inactivation gate that stops further influx of sodium into the cell.
Define:
The absolute refractory period of a neuron.
The point during an ‘action potential cycle’ at which the membrane can produce no new action potentials, regardless of the magnitude of stimulation.
Define:
The relative refractory period of a neuron.
The point during an ‘action potential cycle’ in which a high magnitude stimulation is required for any new action potentials to be initiated.
Note this coincides mostly with the hyperpolarisation phase of the action potential.
How is the RMP restored after an action potential has been triggered?
(Resting Membrane Potential)
Sodium-potassium pumps restore the RMP ion concentrations by using ATP to actively ‘pump’ sodium out and potassium back into the cell.
For each cycle of the sodium-potassium pump, 3 Na+ are pushed out and 2 K+ are brought in.
