Introduction to demyelinating disorders Flashcards
When does myelination being in babies?
1 1st trimester
2 - 2nd trimester
3 - 3rd trimester
3 - 3rd trimester
- rapid increase at birth and continues throughout life
Do oligodendrocytes form myelin in set places?
- no
- oligodendrocytes move to where they are needed
- then myelin is laid down
What is myelin?
1 - cytoplasm of neuronal cells
2 - extensions of schwann and oligodendrocytes lipid membranes
3 - protein laid down by neutrophils on neurons
3 - lipid and protein laid down during foetal development but stops when born
2 - extensions of schwann and oligodendrocytes lipid membranes
- mixture of lipid and proteins
What is myelin sheath?
- the myelin that has wrapped around the axons
Where can oligodendrocytes be found and how many axons can they myelineate?
- CNS
- multiple
Where can schwann cells be found and how many axons can they myelineate?
- PNS
- one axon per schwann cell
Are all axons in the CNS and PNS myelineated?
- no
In the CNS which axons are myelineated?
1 - CNS axons >1-2um
2 - CNS axons <1-2um
3 - CNS axons >0.2um
4 - CNS axons <0.2um
3 - axons >0.2um
- small axons are small enough and don’t need help transmitting signal
Which cells in the PNS are myelineated?
1 - PNS axons >0.2um
2 - PNS axons <0.2um
3 - PNS axons >1-2um
4 - PNS axons <1-2um
3 - PNS axons >1-2um
- small axons are small enough and do not need help transmitting signal
Some axons have more wraps of myelin than others. What determines how many layers of myelin the axons have?
1 - location of axon
2 - length of the axon
3 - type of axon (multi, uni-polar etc.)
4 - diameter of axon
4 - diameter of the axon
What role do gliotransmitters have in myelination?
- communication between neuronal and glial cells
- myelination is dependent on neuronal activity
What are the 3 functions of myelin?
1 - reduce loss of charge, increase speed of action potential, increase transmission efficacy
2 - increase loss of charge, increase speed of action potential, increase transmission efficacy
3 - reduce loss of charge, decrease speed of action potential, increase transmission efficacy
4 - increase loss of charge, increase speed of action potential, decrease transmission efficacy
1 - reduce loss of charge, increase speed of action potential, increase transmission efficacy
The nodes of ranvier are spaces between where axons are myelinated. What is highly concentrated at the nodes of ranvier?
1 - voltage gated Ca2+ channels
2 - voltage gated K+ channels
3 - voltage gates Mg+ channels
4 - voltage gated Na+ channels
4 - voltage gated Na+ channels
When a neuronal cell body receives an action potential from a dendrite it causes depolarisation inside the cell. How does this then move from the cell body of the neuron to the axon hillock (where axon and cell body meet) and move down the axon?
- Na+ voltage gated channels open
- depolarisation spreads and Na+ gated channels further down the axon begin to open
- acts like a domino effect
Are voltage gated channels generally found on the sections of axon that are myelinated?
- no
How does myelin reduce the loss of charge in the axons and therefore facilitate the movement of the action potential down the axon?
1 - no voltage gated channels in myelin areas and decreased axon permeability
2 - only Na+ and Ca2+ voltage gates channels in myelinated areas
3 - permeability to just K+ leaving the axon
4 - increased permeability and increased voltage gated channels in myelin areas
1 - no voltage gated channels in myelin areas and decreased axon permeability
- no voltage gated channels in myelin areas means no ions can leave or enter the already depolarised neuron
- permeability is decreased in myelin areas, meaning ions cannot leave, so depolarised neuron remains depolarised
- positive charge (action potential) must move down the axon
What is capacitance in relation to an action potential?
- relates to the ability of an electrical system to store charge or the charge required to initiate an action potential/electrical impulse
- high capacitance = high positive charge required for an action potential
- low capacitance = less positive charge required for an action potential
Capacitance relates to the ability of an electrical system to store charge or the charge required to initiate an action potential/electrical impulse.
- high capacitance = high positive charge required for an action potential
- low capacitance = less positive charge required for an action potential
How does myelin affect the capacitance of an axon?
1 - capacitance is high meaning meaning low charge required for action potential
2 - capacitance is high meaning meaning high charge required for action potential
3 - capacitance is low meaning meaning low charge required for action potential
4 - capacitance is low meaning meaning high charge required for action potential
3 - capacitance is low meaning meaning low charge required for action potential
- myelinated regions have lower capacitance (less negative charge)
- less negative charge in myelin areas means less positive charge required for action potential
- therefore less positive charge is required to initiate an action potential
When we look at the flow of an action potential along an axon, do small or larger diameter axons have faster flow of action potential?
- axons are part of a neurons cytoplasm, which means they contain cytoplasmic proteins, vesicles, etc.
- larger diameter have more room for cytoplasmic vesicles to spread out
- large diameter axons will have faster conductance as there is less resistance for ions to flow
What is the relationship between the diameter of the axon and the resistance to the flow of ions that move down the axon following an action potential?
- ⬆️ diameter = ⬇️ resistance = ⬆️ flow
- ⬇️ diameter = ⬆️ resistance = ⬇️ flow
What are the 2 terms used to describe the propagation of an action potential down a myelinated and non-myelinated axon?
- saltatory conduction = myelinated fast conduction
- continuous conduction = unmyelinated slow conduction
If we break down the word leukodystrophies, what does this term mean?
- leuko = white
- dyst = abnormal (muscle dystrophy)
- trophies = growth
Leukodystrophies is a rare neurological disorder. What happens?
- leuko = white
- dyst = abnormal
- trop = growth
- demyelinating disease
- degeneration/loss of the white matter of the nervous system (myelin)
- causes slow or no nerve message or action potential
Leukodystrophies is a rare neurological disorder.
- leuko = white
- dyst = abnormal
- trop = growth
This is a dysmyelinating disease causing degeneration/loss of the white matter of the nervous system, which is myelin meaning action potentials are unable to travel along axons, or if they do it is very slow. Is this a congenital or acquired disease?
- congenital
Leukodystrophies is a rare neurological disorder that causes loss of myelin sheaths, termed demyelination. Does this always cause loss of myelin?
- it can do
- but it can be where myelin is not formed when a baby is born
Leukodystrophies is a rare neurological disorder that causes loss of myelin sheaths, termed demyelination. What does this do to nerves?
- can cause complete loss of nerve activity
- can cause slowing of nerve activity
In patients with demyelination, do symptoms always present the same in all patients?
- no
- depends on the nerve affected
- if visual nerve then eye sight is affected