Week 3 - Central Nervous System

Question 1

4 functions of the central nervous system

Answer 1

1) Control of the internal environment - coordinated with the endocrine system (Hypothalamus-Pituitary Axis), perceiving and responding to events in the internal/external environment.

2) Voluntary control of movement

3) Spinal cord reflexes (rapid unconscious movements such as touching hot pan)

4) Assimilation of experiences necessary for memory and learning

Question 2

Draw and outline the anatomical division of the NS.

Answer 2

Central NS: brain and the spinal cord (protected by skull and vertebrae)

Peripheral nervous system (PNS): neurons outside the CNS. This can be divided into sensory division and motor division.

Sensory division: detects stimuli and afferent fibers transmit impulses from receptors to CNS. Can be broken down into somatic, visceral and special sensory.

Motor division: efferent fibers transmit impulses from CNS to effector organs. Broken down into somatic and autonomic.

Autonomic: parasympathetic and sympathetic NS

Question 3

Describe the role of dorsal root and ventral roots and how they differ?

Answer 3

To connect the nerve fibers from the PNS to the CNS

Dorsal roots are afferent - meaning they carry sensory information to the CNS (spinal cord) from the PNS

Ventral roots are efferent - meaning they carry motor information from the CNS (spinal cord) to the PNS

They both make up 31 pairs of spinal nerves in the PNS.

Question 4

Define somatic sensory and visceral sensory.

Answer 4

Somatic - sensory input consciously perceived from receptors like the eyes, skin…

Visceral - sensory input that is not consciously perceived from receptors of blood vessels and internal organs such as the heart (e.g. increased HR).

Question 5

Define autonomic and somatic NS.

Answer 5

Autonomic - motor output that is involuntarily controlled; effectors are cardiac muscle, smooth muscle and glands.
Somatic - motor output that is voluntarily controlled; effectors is skeletal muscle.

Question 6

Dendrites

Answer 6

extend from the cell body and receive information from the synaptic terminals of adjacent cells

Question 7

What is the role of myelin?

Answer 7

it enhances the conduction of an AP along a nerve fiber + insulates the axon and reduces the loss of the electrical impulse.

Question 8

Axon

Answer 8

carry electrical messages (APs) away from the cell body

Question 9

What is the role of Schwann cells in the structure of a neuron?

Answer 9

The cell membrane of Schwann cells is responsible for the myelination of axons.

Question 10

What two factors are responsible for a greater speed of neural transmission (conduction velocity)?

Answer 10

• The diameter of the axon
• The amount of myelin sheath

Question 11

Resting membrane potential

Answer 11

the electrical charge difference in the cell (intracellular) and outside the cell (extracellular)

there is a negative charge inside the cell in respect to the charge outside the cell at rest

Question 12

What is the magnitude of the resting membrane potential determined by?

Answer 12

1. Permeability of plasma membrane to ions - when channels are open ions go from an area of high conc to low conc, membrane far more permeable to K+.
2. Difference in ion concentrations across the cell membrane (Na+ greater outside cell, K+ greater inside cell)

Question 13

Why do we have a negative membrane potential in the cell/neuron at rest?

Answer 13

1. Diffusion of potassium out the cell.
2. Higher permeability of the plasma membrane for potassium compared to sodium

At rest, most of the sodium channels are closed whereas the potassium channels are open. Therefore, potassium ions move from high conc (in the cell) to low conc (extracellular fluid) and this net loss of positive charge leads to a negative charge which is the resting membrane potential.

Question 14

How do we maintain this negative resting membrane potential?

Answer 14

Sodium-potassium ATPase pump

Question 15

What does the sodium-potassium pump do?

Answer 15

Uses energy from ATP to maintain this intracellular and extracellular environment by pumping 3 Na+ OUT of the cell and 2 K+ IN the cell.

Question 16

When does an action potential occur/fire? What does this result in?

Answer 16

It occurs/fires when an excitatory stimulus of sufficient strength (causes membrane potential increase to -50mV) depolarizes the cell by opening sodium channels.

Therefore, sodium diffuses into the cell which makes the cell more positive (depolarizing it).
K+ channels also open but K+ permeability is relatively smaller and lasts longer.

Question 17

What is the threshold potential for an AP to fire?

Answer 17

-50mV is the voltage at which Na+ channels open to initiate AP

Question 18

Repolarization

Answer 18

return to resting membrane potential - potassium leaves the cell rapidly and sodium channels close.

Question 19

All-or-none law

Answer 19

Once a nerve impulse (AP) is initiated, it will travel the whole length of the axon. When the AP reaches the end, a neurotransmitter is released into the synpase.

Question 20

a) Membrane potential depolarizes from -.. mV to +.. mV
b) Membrane potential repolarizes from +.. mV to -.. mV
c) The RMP of a healthy neuron is usually in the range of -..mV to -..mV.

Answer 20

a) -70mV to +30mV
b) +30mV to -70mV
c) -70mV to -80mV

Question 21

Synapse

Answer 21

gap between the presynaptic neuron and the dendrites of the postsynaptic neuron

Question 22

Neurotransmitters

Answer 22

Chemical messengers released from presynaptic membrane (in vesicles) into the synaptic cleft.

They bind to receptors on the postsynaptic membrane which causes the depolarization of the postsynaptic membrane if sufficient amounts of the neurotransmitter is released (threshold point met)

Question 23

Two types of neurotransmitters

Answer 23

1) Excitatory neurons that produce excitatory postsynaptic potentials (EPSP) (e.g. Glutamate)
2) Inhibitory neurons that send inhibitory postsynaptic potentials (IPSP) (e.g. GABA)

Question 24

What are the two ways that EPSPs can promote neural depolarization?

Answer 24

1) Temporal summation: rapid, repetitive excitation from a single excitatory presynaptic neuron

2) Spatial summation: summing EPSPs from several different presynaptic neurons

Question 25

What are neurotransmitters that cause the depolarization of membranes called?

Answer 25

excitatory neurotransmitters

Question 26

What do Inhibitory postsynaptic potentials cause?

Answer 26

They cause hyperpolarization which is a more negative resting membrane potential therefore resisting depolarization.

Question 27

If we want a neuron to move towards its threshold and pass along the AP, what is the relationship between EPSP and IPSP?

Answer 27

EPSPs > IPSPs

Question 28

3 types of joint proprioceptors

Answer 28

1) Free nerve endings (receptive to touch and pressure - most abundant)
2) Golgi type receptors (found in ligaments of joints)
3) Pacinian corpuscles

Question 29

2 types of muscle proprioceptors (mechanoreceptors)

Answer 29

1) Muscle spindles
2) Golgi tendon organs

Question 30

Proprioception

Answer 30

the sense of the body’s position in space based on specialized receptors that reside in the muscles, tendons, and joint.

Question 31

Proprioceptors

Answer 31

sensors that provide information about joint angle, muscle length, and muscle tension, which is integrated to give information about the position and movement of our body/limbs (known as kinesthesia).

Question 32

Muscle spindles
- Define it.
- What is the main function?
- What reflex is it involved in?

Answer 32

• Respond to changes in muscle length.
• Main function is to assist in the regulation of movement and maintain posture.
• Involved in stretch/myotatic reflex where a stretch on the muscle causes a reflex contraction (reflex sensitivity controlled by y-motor neurons).

Question 33

What do muscle spindles consist of?

Answer 33

Intrafusal fibers - run parallel to normal muscle fibers - extrafusal fibers.

Gamma motor neurons - stimulate intrafusal fibers to contract with extrafusal fibers.

Question 34

What happens when muscle spindles detect stretch of the muscle?

Answer 34

• Sensory neurons conduct APs to the spinal cord to alert the CNS of a change in muscle length.
• Sensory neurons synapse with alpha motor neurons (in brain).
• Stimulation of alpha motor neurons which causes the muscle to contract and resist being stretched.
• This is known as the myotatic/stretch reflex.

Question 35

Golgi tendon organ (GTO)

Answer 35

Type of muscle proprioceptor that monitors force development/tension in the muscle and prevents muscle damage during excessive force generation.

Question 36

What does the stimulation of the Golgi tendon organ result in?

Answer 36

increases in muscle tension results in reflex relaxation of the muscle - inhibitory neurons send inhibitory postsynaptic potentials (IPSPs) to muscle alpha motor neurons to prevent it from firing thus reducing muscle force production.

Question 37

How does improved strength from resistance training influence Golgi tendon organ (GTO)?

Answer 37

potential ability to opposes the GTO inhibition due to increased tendon stiffness.

Question 38

What happens when Golgi tendon organs detect tension applied to a tendon?

Answer 38

• Sensory neurons conduct APs to the spinal cord.
• Sensory neurons synapse with inhibitory interneurons that synapse with alpha motor neurons.
• Inhibition of the alpha motor neurons cause muscle relaxation, relieving the tension applied to the tendon.

Question 39

Muscle chemoreceptors (OR muscle metaboreceptors)

Answer 39

Sensitive to changes in the chemical environment surrounding a muscle - H+ ions (implies a change in pH), C02, K+.

Inform CNS about metabolic rate of muscular activity which is important in the regulation of CV and pulmonary responses.

Question 40

Motor unit

Answer 40

motor neuron and all the muscle fibers it innervates

Question 41

Motor neurons
- Location
- Role

Answer 41

• Located within spinal cord
• Responsible for carrying neural messages from spinal cord to skeletal muscles.

Question 42

Innervation ratio

Answer 42

number of muscle fibers innervated by a single motor neuron

• Low ratio in the muscles involved in fine motor control
• Higher ratio in muscles that do not require fine motor control (large limbs)

Question 43

How do we recruit additional muscle fibers?

Answer 43

by activating more motor units - this increased force production

Question 44

The size principle

Answer 44

the orderly and sequential recruitment of larger motor units during exercise

smaller motor units recruited first during exercise; larger motor units recruited if we need more force.
(Type S –> Type FR –> Type FF)

Question 45

3 types of motor units

Answer 45

1) Type S (slow) / type 1(smallest)

2) Type FR (fast, fatigue resistance) / type 2a (intermediate)

3) Type FF (fast, fatigable) / type 2x (largest)

Question 46

3 functions of the Cerebrum or cerebral cortex

Answer 46

1) Organization of complex movement (motor cortex - voluntary movement)
2) Storage of learned experiences
3) Reception of sensory information

Other functions; memory, higher reasoning, abstract thought, audio and visual processing

Question 47

3 functions of the Cerebellum (Latin for little brain)

Answer 47

1) Control of movement (the rate, range and direction of movement)
2) Integration of sensory information.
3) Helps maintain balance and posture

Question 48

Brainstem roles

Answer 48

• Role in cardiorespiratory function
• Locomotion, muscle tone, posture
• Receiving information from special senses.

Question 49

Explain the 3 main structures of the brainstem.

Answer 49

1) Midbrain (mesencephalon): connects the pons and cerebral hemispheres and functions include controlling responses to sight, eye movement, pupil dilation, body movement and hearing (top)

2) Medulla oblongata: involved in control of autonomic function, relaying signals between the brain and spinal cord and coordination of body movements. (bottom)

3) Pons: involved in sleep and control of autonomic function. Relays information between cerebrum and cerebellum. (middle)

Question 50

Spinal cord
- Describe it.
- What is its role?
- What 3 neurons does it contain?

Answer 50

45cm long, encased and protected by vertebral column, and attaches to brain stem.

Two-way transmission of sensory information from skin, joints and muscle to the brain.

Contains 3 types of neurons: motor, sensory and interneurons.

Question 51

Motor control functions of the spinal cord

Answer 51

1. Spinal tuning:
2. Withdrawal reflex

Question 52

Spinal tuning

Answer 52

refers to intrinsic neural networks within the spinal cord that refine voluntary movement after receiving messages from higher brain centers.

Question 53

Withdrawal reflex (flexion withdrawal reflex)

Answer 53

whereby a reflex contraction of skeletal muscles can occur in response to sensory input and is not dependent on the activation of higher brain centers (moving hand from heat).
withdrawal of a limb from a painful stimulus to protect the body from harm.

Question 54

Describe the process of a withdrawal reflex.

Answer 54

• Painful stimulus
• Sensory neurons from pain receptors conduct APs to the spinal cord.
• Sensory neurons synapse with excitatory interneurons that are part of the withdrawal reflex.
• They then stimulate alpha motor neurons that innervate flexor muscles, causing withdrawal of the limb from the painful stimulus.
• Also associated with crossed extensor reflex to ensure balance/support of body weight.

Question 55

Crossed extensor reflex

Answer 55

this is where the opposing limb is extended in order to be able to support body weight during the removal of that injured limb.

Question 56

A “movement plan” is first developed by the ___ before being sent to the spinal centers for modification.

Answer 56

motor cortex

Question 57

Describe the 3 levels of the control of voluntary movement.

Answer 57

Precommand level: Cerebellum (fast movements) and basal nuclei (slow movements) involved in planning/coordinating of movement design.

Projection level: Motor cortex receives inputs from a variety of brain areas including basal nuclei, cerebellum, and the thalamus. It sends this information to spinal cord motor neurons (motor units) which results in execution of desired movement.

Segment level: Spinal tuning occurs which results in the refinement of motor control.

Throughout this process feedback from proprioceptors allow for further modification of motor control.

Question 58

What does the control of voluntary movement involve?

Answer 58

cooperation of many areas of the brain along with subcortical areas

Question 59

Role of Astrocyte in the presynaptic terminal.

Answer 59

They take up excess neurotransmitters (e.g. glutamine and GABA) that doesn’t interact with receptors on the postsynaptic membrane.

Question 60

What is the difference between convergence and divergence?

Answer 60

Convergence: when a neuron receives input from many other neurons
Divergence: neuron synapses with many other neurons