Week 5 - Neurology

Question 1

What are the two types of cells in the nervous system?

Answer 1

Neurons - cell body called soma, neurites are projections from the cell body - neurites divided into dendrites and axons.
Dendrites receive input from other neurons
Axons - action potential propagates through these
Law of dynamic polarisation - preferred direction of current flow

Glial cells - astrocytes - fill spaces between neurons and regulate the chemical content of the extracellular space
- oligodendrocytes/Schwann cells - provide myelination or axons - oligodendrocytes in CNS and Schwann in peripheral NS

Question 2

Afferent vs efferent axons

Answer 2

Afferent - carry sensory info from the peripheries of the body and enter the spinal cord dorsally

Efferent - carries motor info from the CNS through ventral root ganglions to muscles

Question 3

Which ions are at high concentration inside/outside of the cell?

Answer 3

Inside - potassium

Outside - sodium and chloride

Question 4

How is the resting membrane potential maintained?

Answer 4

Sodium potassium pump

leaky potassium channels - only potassium moves out, along their concentration gradient - net negative charge in cell - equilibrium potential for K is roughly -80mV

Question 5

What is the resting membrane potential?

Answer 5

Around -65mV

Equilibrium potential for - Na is positive
Equilibrium potential for - K is negative

Question 6

What is the threshold potential?

Answer 6

-40mV

Question 7

Describe voltage gated Na channels during action potential

Answer 7

Closed at rest
Threshold potential induces a conformational change in the protein
Pore allows Na in, depolarising rapidly
Stay open for around 1ms before deactivating

Question 8

Describe voltage gated K channels during action potential

Answer 8

Require depolarisation to open
Slow to open ~1ms after depolarisation
Delayed rectifier
Channels close when membrane potential returns to rest

Question 9

What is the refractory period

Answer 9

Time in which an excitable cell is unable to generate a subsequent action potential
Absolute - then all Na channels are open, no more to generate a subsequent one
Relative - after hyperpolarisation, less likely to produce one

Question 10

Describe action potentials

Answer 10

Stimulus depolarises rising towards the threshold, if it passes, Na channels open leading to rapid depolarisation to around 30mV, when a physical block closes Na channels.
K channels take longer to open, but when they do, they repolarise the cell. This is the falling phase. then hyperpolarisation

Firing rate, not amplitude shows intensity of stimulus

Question 11

How does a stimulus propagate?

Answer 11

Unmyelinated - passive propagation as adjacent sodium channels are activated by the depolarisation

Myelinated - nodes of Ranvier between myelin sheaths. These have high concentrations of sodium channels. APs initiated in an axon hillock. Propagation from node to node - saltatory conduction - much faster

Question 12

What are mechanoreceptors

Answer 12

Unmyelinated fibres in the skin sensitive to stretch, bend, pressure

Question 13

What are mechanosensitive ion channels

Answer 13

Gates opened by stretching of a membrane

Question 14

What are the 4 types of sensory input neurons?

Answer 14

A alpha - 13-20 microns, 80-120m/s, myelinated, receptor- proprioceptors in skeletal muscle

A beta - 6-12 microns, 35-75 m/s, myelinated, mechanoreceptors

A delta - 1-5 microns, 5-30 m/s, myelinated, pain and temperature

C - 0.2-1.5 microns, 0.5 -2 m/s, unmyelinated, relative temperature, some pain, itching

Question 15

What does the action potential firing frequency encode?

Answer 15

Stimulus strength and duration

Question 16

What is encoded by the timing of the first and last AP?

Answer 16

Stimulus onset/offset

Question 17

What makes a molecule a neurotransmitter?

Answer 17

Have precursor molecules and/or synthesis enzymes located in the presynaptic terminal

The chemical is present in the presynaptic terminal

It is available in sufficient quantity in the presynaptic neuron to affect the postsynaptic neuron

There are postsynaptic receptors for it to bind

Biochemical mechanisms for its inactivation are present

Question 18

Classes of neurotransmitter

Answer 18

Amino acid - glutamate, GABA

Monoamines - dopamine, adrenaline, serotonin

Peptides - over 50

Others such as acetylcholine

Question 19

Where are neurotransmitters generated?

Answer 19

In the presynaptic terminal

Enzymes required for synthesis are made in the cell body

Question 20

What is exocytosis?

Answer 20

The release of neurotransmitter into the synaptic cleft

Question 21

Sequence of events leading to neurotransmitter release: (called exocytosis)

Answer 21

1. Action potential invades the presynaptic terminal
2. Membrane depolarisation occurs
3. Voltage-gated calcium channels open
4. Increase in calcium promotes vesicle fusion
5. Vesicles release neurotransmitters into the synaptic cleft

Question 22

Exocytosis/endocytosis cycle

Answer 22

1. Docking – vesicle binds to membrane before AP invades terminal
2. Ca2+ sensing – Ca entry triggers fusion of the vesicle
3. Endocytosis – new vesicle membrane “pinched off”
4. Loading – new vesicle filled with neurotransmitter
5. Cycle completes

Question 23

types of postsynaptic receptors

Answer 23

Ionotropic receptors are fast ligand-gated ion channels that open when the NT binds
Metabotropic receptors are slow because they activate a second messenger system (for example via GPCRs)

Question 24

what are the two types of synapse?

Answer 24

At an excitatory synapse, if sufficient NT binds to Na+ ionotropic receptors the membrane will depolarise to produce an excitatory post-synaptic potential (EPSP). IPSPs occur at inhibitory synapses because Cl- channels are opened instead, further polarising the membrane (making it more negative so it is harder to generate an action potential)

Question 25

what is the quantal hypothesis?

Answer 25

that each vesicle produces a quantal response in the postsynaptic receptors - so the release of 2 vesicles produces a response twice the size of that of 1 vesicle

Question 26

what are the two types of summation?

Answer 26

Spatial summation is when a neurone combines multiple EPSPs from different synapse connections

Temporal summation is when a neurone combines multiple consecutive EPSPs from the same synapse

Spatial summation and temporal summation both stop when the threshold is reached and an action potential is generated.

Question 27

how can drugs affect neurotransmission?

Answer 27

GABA- gated Cl channel can be affected by substances. Ethanol affects the level of inhibition, affects CNS and motor function. Barbiturates cause mild sedation to full anaesthesia

Question 28

What are the two types of autonomic NS?

Answer 28

Sympathetic

Parasympathetic

Question 29

Describe the sympathetic NS

Answer 29

Preganglionic neurones release ACh
Post ganglionic neurones release noradrenaline
Receptors therefore known as adrenoreceptors
Fight or flight - heart rate increase, relaxation of airways and inhibition of digestion

Question 30

Describe the parasympathetic NS

Answer 30

Day to day required
ACh
Airway constriction, digestive stimulation and slowing of heart rate

Question 31

what is the somatic motor system?

Answer 31

We choose to make a movement, this is generated by the motor cortex, propagates down the spinal cord, into upper motor neurons, then lower motor neurons and these then send out signals to the muscles. Lower motor neurons directly command muscle contraction. Each motor neurons innervates a single muscle. They are distributed within the ventral horn in a predictable way. Neurons innervating axial muscles are medial to those innervating distal muscles. Neurons innervating flexors are dorsal to those innervating extensor muscles.

Question 32

what is a motor unit?

Answer 32

The alpha motor neuron and all the muscle fibres it innervates

Question 33

what is the life cycle of acetylcholine?

Answer 33

ACh released. Binds to postsynaptic nicotinic receptors and causes sodium channel openings so the action potential can spread down the sarcolemma. ACh is then broken down via the enzyme acetylcholinesterase into choline and acetic acid. Choline transporters on the presynaptic terminal then take choline up back into the presynaptic terminal - used as a precursor for the generation of Ach. The choline will bind with acetyl CoA under the influence of the enzyme choline acetyltransferase. The acetic acid diffuses away.

Question 34

how is muscle contraction initiated?

Answer 34

by ACh release and binding to postsynaptic ACh receptors. 1 presynaptic AP is sufficient to trigger 1 postsynaptic AP in a muscle fibre.

Question 35

What is the sarcolemma?

Answer 35

Excitable cell membrane covering muscle fibres

Question 36

What is the sarcoplasmic reticulum?

Answer 36

Extensive intracellular sac that stores calcium

Question 37

What are myofibrils?

Answer 37

What contract in response to action potentials
Made up of actin and myosin strands
Repeating contractile units called sarcomeres

Question 38

What are the stages of muscle contraction?

Answer 38

Action potential generated in sarcolemma.

Release of calcium from sarcoplasmic reticulum

Binds to troponin which is normally bound to actin filaments

Actin is freed, exposing myosin binding sites

Myosin binds to actin and pivots, sliding actin along

Myosin detatches at the expense of ATP

Question 39

When does relaxation occur?

Answer 39

When calcium or ATP levels reduce

Question 40

Describe all steps of muscle contraction

Answer 40

AP in alpha motor neuron
Exocytosis of ACh
Postsynaptic depolarisation
Ca release from sarcoplasmic reticulum
Sliding actin/myosin filaments
Muscle contraction

Question 41

What is a myotatic reflex?

Answer 41

Reciprocal innervation of flexor and extensor muscles

Sensory innervation comes from a contracting muscle to excite inhibitory neurons on the antagonist muscle.
If flexor contracts, paired extensor relaxes to allow movement

Question 42

What is the patellar reflex?

Answer 42

When hammer taps, firing frequency of sensory neurons increases, causes the motor neuron extensor firing frequency to increase, as well as interneuron firing frequency to suppress the motor neuron flexor activity

Question 43

What is the crossed extensor reflex?

Answer 43

On painful stimulus, sensory afferent axons activated and excitatory interneurons bring about efferent motor neuron excitation and therefore contraction.

Leg jerking away has excited flexors and inhibited extensors, opposite leg has inhibition flexors and excited extensors to allow weight to shift so as not to lose balance

Question 44

What is the vestibulo-ocular reflex?

Answer 44

Inhibition of extraocular muscles one one side and excitation on the other on detection of head rotation

Allows fixed position of eye even if the head is moving

Question 45

Describe hyponatremia

Answer 45

<135mmol/L
Common
Caused by diuretics, renal disease, congestive heart failure, cirrhosis

Muscle cramps, weakness, fatigue, reduced consciousness

BRAIN OEDEMA

Question 46

Describe hypernatremia

Answer 46

> 145mmol/L
Uncommon
Renal failure, fever, vomiting, diarrhoea

Tremor, seizures, hyperreflexia, thirst, lethargy, convulsions

BRAIN SHRINKAGE

Question 47

Describe hypokalemia

Answer 47

<3.5 mmol/L
Most common
Diuretics, renal failure, cirrhosis, malnutrition, malabsorption

Muscle weakness, fatigue, constipation, cardiac arrhythmias, muscle paralysis, respiratory paralysis

POTENTIALLY FATAL ARRHYTHMIAS

Question 48

Describe hyperkalemia

Answer 48

> 5.5 mmol/L
Uncommon
Drug interaction during treatment of kidney infections

Impairment of neuromuscular, cardiac and GI organ systems, ventricular fibrillation

INCREASED RISK OF CARDIAC ARREST

Question 49

What are channelopathies?

Answer 49

Diseases which affect ion channels and thus depolarisation/repolarisation of cells

Long QT syndrome - mutation in K channels leads to cardiac arrhythmias - rare inherited

Question 50

Describe demyelinating diseases

Answer 50

Multiple sclerosis - loss of myelin and damage to axons over many years by repeated episodes - possible stem cell repair

Charcot-Marie-Tooth - most common inherited disease - affects peripheral nerve conduction - affects legs then arms and hands

Guillan-Barre syndrome - inflammatory attack in myelin and peripheral nerves - very quick onset after something like stomach upset then goes away quickly - tingling, muscle weakness, possible paralysis and respiratory failure

Question 51

Describe peripheral neuropathies

Answer 51

Diabetic - chronic dysregulation of blood glucose - damage to sensory and motor axons in distal limbs - ulcerations, infections and gangrene

Autonomic - loss of sympathetic and parasympathetic nerves - poor circulation and healing - risk of gangrene

Neuritis - inflammation of cranial nerves from Lyme’s disease, meningitis, viral encephalitis

Optic neuritis - acute attack leading to loss of vision over several hours

Vestibular neuritis - acute, possibly via herpes simplex, loss of vestibular function on one or both sides leading to loss of balance

Bell’s palsy - weakness or paralysis of facial muscles, usually temporary and causes by viral inflammation (herpes simplex) of facial nerve

Trigeminal neuralgia - stabbing pain in face, usually on one side, triggered by loud sounds or touch/chewing

Question 52

Describe myasthenia gravis

Answer 52

Disorder of synaptic transmission
Autoimmune - loss of function of ACh receptors on skeletal muscle
Muscle weakness which worsens with activity and improves with rest
Difficulty talking, chewing, swallowing, simple locomotion
Ptosis and double vision

Question 53

Describe hyporeflexia

Answer 53

Depressed or absent reflexes
Lower motor neuron lesions
Loss of motor neurons
Denervation of muscles (injury or disease)
Thyroid deficiency

Question 54

Describe hyperreflexia

Answer 54

Exaggerated reflexes, spasticity and rigidity
Upper motor neuron lesions
Spinal trauma and trans-section
Brain haemorrhage
Drug misuse