Nervous system

Question 1

Sensory Division of Peripheral Nervous System

Answer 1

Sensory information (stimuli) gathered from inside and outside of body.
-Many kinds of sensory information, including pain, pressure, temperature, chemical levels.
Sensory input delivered to CNS via peripheral nerves.
Sensory nerve fibres are also called afferent fibres.
Sensory information travels from peripheral nervous system towards CNS.

Question 2

Motor Division of Peripheral Nervous System

Answer 2

Motor division of peripheral nervous system carries impulses away from central nervous system, usually to effector organs.
* Motor nerve fibres also called efferent fibres.
* There are two types of motor information. Motor information to the somatic nervous system or to autonomic nervous system

Question 3

Motor Division of Peripheral Nervous System
pt2

Answer 3

Somatic Nervous System
* Under voluntary control and effector tissue is skeletal (voluntary) muscle.
* CNS response to sensory information may be to activate the somatic nervous system, eliciting a voluntary response involving skeletal muscle movement e.g., if sensory system says you are too hot you may activate your muscle to take off a coat..– this is the motor response that involves the somatic nervous system. It is a voluntary activity that the person chooses to do

Question 4

Motor Division of Peripheral Nervous Systempt3

Answer 4

Autonomic Nervous System
* CNS response to sensory information may be to activate autonomic nervous system, leading to an involuntary action. Autonomic nervous system is responsible for involuntary motor responses. The effector may be smooth or cardiac muscle (both involuntary muscles) or a gland.
* If your body feels too hot, the involuntary response is to lose heat through the skin by causing vasodilation. Vasodilatation is an example of an involuntary autonomic nervous system response. The individual cannot control this response.
* The autonomic nervous system is further divided into the sympathetic (fight or flight) and the parasympathetic (rest and digest) divisions. A fine balance between both divisions is required for the maintenance of homeostasis.

Question 5

Nervous tissue

Answer 5

Nervous tissue has two types of cells: neurons and neuroglia.
* Neurons provide most of the functions of the nervous system, e.g., sensing, thinking, controlling muscle activity, and regulating glandular secretions.
* Neuroglia support, nourish, and protect the neurons and maintain homeostasis in the interstitial fluid that bathes them.

Question 6

Neurons

Answer 6

Like muscle cells, neurons (nerve cells) possess electrical excitability, they respond to a stimulus and convert it into an action potential.
* A stimulus is any change in environment that is strong enough to initiate an action potential. An action potential or impulse is an electrical signal that propagates (travels) along the surface of the membrane of a neuron or a muscle fiber.
* Transmission of the nerve signal is electrical within the nerve, but chemical as it passes from nerve to nerve
* Bundles of neurons are called nerves

Question 7

Structure of a nerve

Answer 7

Cell body contains the nucleus and usual cellular components (mitochondria, ER, Golgi)
They receive impulses from other nerves via their dendrites
The signal is passed along their axon
This is transmitted to other nerves or effector organs via terminal boutons

Question 8

Organisation of nerves

Answer 8

Groups of cell bodies make up the grey matter
* Groups of nerve bodies within the CNS are called nuclei (don’t confuse
with nucleus of an individual cell)
* Groups of nerve bodies in peripheral nervous system are called ganglia
* Groups of axons and dendrites make up the white matter (as there is a lot fat (myelin) around them. They are called tracts in the spinal cord and nerve fibres outside of the CNS

Question 9

Structure of axon-myelinated

Answer 9

Schwann cells are example of neuroglia
Between the thin wrapped- around layers of the Schwann cell is fatty substance; myelin
Myelin acts as an insulator
Large axons and those of PNS are usually myelinated

Question 10

Action potential

Answer 10

At rest, inside of nerve is negatively charged compared to outside.
At rest there is more K+ inside the cell than outside
When stimulus occurs, Na+ rushes into cell through pores (gates) and charge changes to positive on inside and negative on outside. In a slower response, K+ starts to leave the cell

Question 11

Speed of conduction of impulse

Answer 11

Depends on whether myelinated = faster * Larger neurone (axon ) = faster
* Fastest conduction is about 130 meters /second * Unmyelinated small nerves 0.5 meters/second

Question 12

Structure of a nerve ending

Answer 12

Tips of most axon terminals swell into synaptic end bulbs.
These bulb-shaped structures contain synaptic vesicles, tiny sacs that store chemicals called neurotransmitters.
Release of neurotransmitter is method of communicating with next nerve or effector cell.

Question 13

Synapses

Answer 13

Site where two neurons or a neuron and an effector cell communicate is termed a synapse.
* The neuron sending the signal is called the presynaptic neuron (pre = before), and neuron receiving the message is called the postsynaptic neuron (post = after).
* Although presynaptic and postsynaptic neurons are close together, their plasma membranes do not touch. They are separated by synaptic cleft, a tiny space filled with interstitial fluid.

Question 14

The synapse

Answer 14

At a chemical synapse, a presynaptic neuron converts an electrical signal (nerve impulse) into a chemical signal (neurotransmitter release).
The postsynaptic neuron then converts the chemical signal back into an electrical signal (nerve impulse).

Question 15

the synapse pt 2

Answer 15

Neurotransmitter bind receptor signals to join channels to affect depolarisation

Question 16

Turning off the signal

Answer 16

neurotransmitter will continue to affect postsynaptic receptors until it is turned off by being removed from its receptor.
Neurotransmitters are removed in three ways:
(1) Some neurotransmitter molecules diffuse away from synaptic cleft. (2) Some are destroyed by enzymes.
(3) Many neurotransmitters are actively transported back into neuron that released them (reuptake) or transported into neighbouring neuroglia (uptake).
-This is important for SSRI antidepressants (selective serotonin reuptake inhibitors)

Question 17

Spinal cord

Answer 17

Consists of a central canal and grey and white matter.
* Grey matter consists mostly of cell bodies and their dendrites
* Whiter areas consist of the axons of neurones, carrying signals up and down the cord.
* These tracts cross to the other side as they enter and exit the brain
* Explains why right side of brain controls left side of body and vice versa.

Question 18

Spinal cord

Answer 18

Looks like letter H
Grey columns= neuronal cell bodies
White columns= tracts of axons relaying messages from or to brain
Root ganglia= collection of neuronal cell bodies

Question 19

Spinal cord pt2

Answer 19

Anterior grey columns are neuronal cell bodies of motor neurones that leave cord from anterior root
Also contain cell bodies of interneurons that link sensory and motor neurones at spinal cord level
Posterior grey columns are cell bodies of sensory neurones that synapse with the sensory nerve coming in from periphery (who have their cell bodies in the posterior root ganglion)

Question 20

spinal cord pt3

Answer 20

Protected within vertebra Surrounded by fluid (cerebrospinal fluid (CSF), made within brain)
Central canal and the layer between spinal meninges contain CSF.

Question 21

spinal cord pt4

Answer 21

finishes at around L1 nerve roots continues as a cauda equina

Question 22

functions of spinal cord

Answer 22

A method of communication between brain and the peripheral nerves that leave the spinal cord.it has two major functions in maintaining homeostasis;Tracts of white matter of spinal cord carry sensory impulses to brain and motor impulses from brain to skeletal muscles and other effector muscles.
* Grey matter of the spinal cord is a site for integration of reflexes, which is a rapid, involuntary action in relation to a stimulus.

Question 23

Motor neurones

Answer 23

Two main forms
Upper motor neurones have cell bodies in brain
Axons travel down spinal cord and synapse with lower motor neurones (the final nerves to signal to the muscle) within the anterior spinal cord
If you cut a lower motor neurone the muscle will “go floppy”
If you cut an upper motor neurone the tone will remain or may even go firmer

Question 24

Involuntary muscle movement

Answer 24

Upper motor neurones in brain stem and spinal cord maintain posture and balance
* Spinal reflexes are the simplest examples
* Involving sensory neurone
* Interneurone in spinal cord
* Lower motor neurone
* Reflex’s are protective mechanisms

Question 25

stretch reflex

Answer 25

Interneurone not involved in this particular reflex

Question 26

moving up the nervous system to brain stem and brain

Answer 26

In brain stem (medulla) Motor and sensory nerves cross over and signal to opposite side of brain
Called “decussation”

Question 27

Main functional areas of cerebrum

Answer 27

Main regions:
Motor area
Sensory area
Speech: Motor speech – muscles for speaking Sensory speech- understanding spoken words
Visual area-sight

Question 28

what does hypothalamus do

Answer 28

Hypothalamus- Control posterior pituitary (ADH) Appetite
Body temperature

Question 29

Brain stem

Answer 29

Medulla
Decussation of sensory and motor fibres
Cardiovascular centre
Vasomotor (blood pressure sensing)
Respiratory centre-rate & depth breathing
Pons contains pneumotactic area for breathing

Question 30

Important tracts of brain

Answer 30

Note Basal ganglia deep within brain Important for initiating movement- Parkinson’s disease

Question 31

12 Cranial
nerves

Answer 31

Mainly from brain stem
Main ones to remember:
1. Olfactory (smell) 2. Optic (sight)
8. Auditory (hearing) 10 Vagus nerve (parasympathetic)

Question 32

The Autonomic Nervous System

Answer 32

Plays a major role in maintenance of homeostasis by regulating body’s automatic, involuntary functions.
* In common with rest of nervous system, it consists of neurones, neuroglia and other connective tissue.
* Divided into two: Sympathetic and the parasympathetic systems.
* Both systems supply (innervate) all internal organs;
* Function automatically and usually in an involuntary manner.
* Work together in co-ordinated fashion

Question 33

Parasympathetic system “rest and digest”

Answer 33

Becomes more important at times of rest, digestion.
Neurotransmitter is always acetyl Choline
Main one we will focus on is vagus nerve (10th cranial nerve)
Slows heart, Increases gastric acid & pancreatic juice
Digestion increased

Question 34

Sympathetic Division (Fight or Flight)

Answer 34

Sympathetic division includes nerve fibres that arise from the 12 thoracic and first two lumbar segments of the spine.
* Sympathetic nerve input increases when a stressful situation occurs. -strenuous exercise
-emotional stress at times of anger or anxiety.
Prepares body for exercise
Causes adrenal gland to release adrenaline and noradrenalin into bloodstream

Question 35

Sympathetic Division

Answer 35

Neurotransmitter is acetyl choline at cervical ganglion (in neck by spine)
* Final neurotransmitter usually noradrenalin.
* Causes increased heart rate and blood pressure
* Bronchodilation
* Reduces digestive process
* Stimulates liver to break down glycogen to release glucose

Question 36

Main neuro-transmitters of PNS

Answer 36

Motor nerves-acetyl choline
* Parasympathetic nerves-acetyl choline * Sympathetic nerves-noradrenaline
* Sympathetic nerve to adrenal gland –acetyl choline but release noradrenaline and adrenaline into blood

Question 37

When things go wrong

Answer 37

Slipped disc” is herniation of jelly content in intervertebral discs backwards to cause pressure on spinal cord or nerve root
Usually occurs lumbar region

Question 38

Strokes

Answer 38

Very common cause of death
* Blood supply to part of brain is stopped/reduced
* Can be due to a blood clot, an embolus or a bleed
* Risk factors for blood clot same as for heart attacks-diabetes, high blood pressure, cigarette smoking
* Embolus is usually atheroma debris in carotid artery in neck that dislodges and enters brain vessels
* Motor function affected causes upper motor neurone lesions. The muscle tone may be increased but its functionality is impaired

Question 39

Strokes pt2

Answer 39

Bleed into brain usually associated with hypertension
and/or aneurysm
Aneurysm in one of the main vessels leading to the brain causes subarachnoid haemorrhage, mixes with the CSF

Question 40

Upper and lower motor neurone problems

Answer 40

Lower motor neuron lesions (i.e., the final nerve supply to the muscle) result in muscular atrophy, flaccid muscle weakness, fasciculation and hyporeflexia.
* Upper motor neuron lesions (affecting motor control above the final nerve supply, as in a stroke) causes spastic hyperreflexia and muscle weakness.

Question 41

Motor neurone issues

Answer 41

Motor neurone disease
* Degeneration of upper and lower motor neurones.
* Muscles may start to twitch and become progressively weaker.
* Patients have increasingly difficulty in breathing
* Polio (Poliomyelitis)
* Viral infection invades anterior horn (muscle supplying) nerves-lower
motor neurones
* Causes floppy paralysis but sensation not affected

Question 42

Multiple sclerosis (MS)

Answer 42

Inflammatory process affecting nerves of CNS
* The myelin is replaced with white matter called plaques that do not
allow the underlying axons to relay messages properly.
* Symptoms depend on where the injury is occurring.
* May suffer vision problems
* Loss of co-ordination (cerebellum)
* Sensation (burning/pins and needles)
* Treatment is with immunosuppressants

Question 43

Dementia

Answer 43

Gradual impairment of memory (especially short term), intellect and reasoning.
* Brain gradually reduces in overall size
* Two main causes:
* Multiple small undetected strokes progressively cause loss of neurones
* Alzheimers; the most common dementia diagnosis among older adults. Typically associated with abnormal build-up of proteins in the brain — known as amyloid plaques and tau tangles — along with a loss of connection among nerve cells.

Question 44

Parkinson’s disease

Answer 44

Degeneration of basal ganglia
Causes lack of the neurotransmitter dopamine
Treatment with L-Dopa