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Neurones and Neural Pathways. Chapter 27. The nervous system consists of a complex network of nerve cells called NEURONES. The diagram shows the three types of neurone. SENSORY, ASSOCIATION and MOTOR. Structure of a Neurone.
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Neurones and Neural Pathways Chapter 27
The nervous system consists of a complex network of nerve cells called NEURONES. The diagram shows the three types of neurone. SENSORY, ASSOCIATION and MOTOR
Structure of a Neurone Neurones all share the same basic structure. They consist of a cell body, axon and dendrite
DENDRITES Information from receptors is transmitted along several dendrites which gather into one fibre to carry the information towards the cell body
CELL BODY The Cell body of a neurone contains the nucleus and most of the cytoplasm. It is the control centre of the cell’s metabolism and contains ribosomes. These are required to make proteins including enzymes for synthesis of neurotransmitters.
AXONS An axon is a single nerve fibre which carries nerve impulses away from a cell body and, in the case of sensory and association neurones, on to the next neurone in the sequence.
AXONS The axons of motor neurones are extremely long. They can be more than a metre long if reaching body parts like the toes.
Each axon from a motor neurone carries a message from the cell body to an effector
AXON CELL BODY The direction in which a nerve impulse travels is always: dendritescell bodyaxon DENDRITE
Myelin Sheath The presence of the myelin sheath greatly increases the speed at which impulses can be transmitted along the axon of a neurone This is a jacket of fatty material around a nerve fibre. A nerve fibre lacking myelin is described as unmyelinated.
Post-Natal Development of Myelination • Myelination, the development of myelin around axon fibres of individual neurones, takes time and is not complete at birth but continues during post–natal development.
Chemical Transmission at a Synapse • A synapse is a tiny region of functional contact between an axon ending of one neurone and the membrane of the dendrite (or sometimes the cell body) of the next neurone • The nerve cell before the synapse is called the presynaptic neurone; the one after is called the postsynaptic neurone • It is at the synapse that information is passed on by means of a chemical called a neurotransmitter
A synapse Presynaptic neurone Postsynaptic neurone
A region of contact between a motor neurone and an effector is called a neuro-effector junction
Neurotransmitters • There are many neurotransmitters passed on at the synapse. Two examples of the many neurotransmitters are: • ACETYLCHOLINE • NORADRENALINE
The two neurones at a synapse are separated by a narrow space called the synaptic cleft A synaptic knob is full of vesicles of one type of neurotransmitter When a nerve impulse passes through the presynaptic neurone and reaches the synaptic knob, several vesicles fuse with the knob surface membrane and release neurotransmitter from the vesicles into the synaptic cleft The neurotransmitter molecules briefly combine with receptor molecules at sites on the postsynaptic dendrite and a nerve impulse is able to be passed on Since vesicles containing neurotransmitter occur on one side only of a synapse, this ensures that nerve impulses are transmitted in one direction only
Fate of neurotransmitter after transmission of impulse • As soon as an impulse has been transmitted the neurotransmitter is rapidly removed. • Acetylcholine is broken down into non-active products by an enzyme present on the postsynaptic membrane, as in the following equation: acetylcholinesterase • Acetylcholine Non-active products The non-active products are then reabsorbed by the presynaptic neurone and resynthesised into active neurotransmitter stored in vesicles ready for reuse. Mitochondria present in the presynaptic knob provide the energy. Noradrenaline is rebsorbed by the presynaptic membrane and stored in vesicles ready for reuse.
Frequency of impulses • The nerve impulses transmitted are equal in size, however the number of impulses transmitted per second can vary depending on the intensity of the original stimulus
Loud Music Causes More Impulses to be Sent It is important to remove neurotransmitter quickly between impulses. If it doesn’t happen then only a limited number of impulses can be passed. We would therefore be unable to distinguish between loud and soft sounds or similarly between mild and severe pain
Excitatory and inhibitory signals In the CNS, one postsynaptic neurone normally forms synapses with many presynaptic axons from several different neurones At some of these synapses, the receptor sites in the postsynaptic membrane respond to the arrival of neurotransmitter( e.g. acetylcholine) by having an excitatory effect which increases the chances of reaching threshold and transmitting a nerve impulse
Excitatory and Inhibitory Signals At other synapses the receptor sites respond to the neurotransmitter (e.g. acetylcholine) by having an inhibitory effect which reduces the chance of reaching threshold and transmitting a nerve impulse When the sum of the excitatory effects from the postsynaptic membrane is greater than the inhibitory effects and threshold is reached, a nerve impulse is transmitted. When the inhibitory effects are in excess, no signal is fired
Heart rate decreases as receptor sites receive acetylcholine and cause inhibition Peristalsis rate increases as acetylcholine combines with receptor sites that cause excitation
Complex Neural Pathways • Neurones are found to be connected to one another in many different ways in the CNS. Two examples of neural pathways are: • DIVERGING NEURAL PATHWAY • CONVERGING NEURAL PATHWAY
Diverging Neural Pathway To diverge means to branch out from a common point. In a diverging neural pathway, the route along which an impulse is travelling divides. This allows information to be transmitted to several destinations e.g.Temperature Control Examples of a diverging neural pathways would be the hypothalamus having a neural pathway that diverges into branches which lead to sweat glands, skin arterioles and skeletal muscles.
Diverging Neural Pathway Fine Motor Control Another example of a diverging neural pathway would be the cerebrum transmitting impulses to different muscles in the hand. This allows the fine motor control of the fingers and thumbs and allows them to work in unison
Converging Neural Pathway To converge means to come together and meet at a common point. In a converging neural pathway, impulses from several sources are channelled towards one point
Rods and Cones Rods and cones are visual receptors present in the retina of the eye. They contain pigments which break down in the presence of light. In each case, this breakdown forms a chemical which triggers off nerve impulses along a pathway of neurones The pigment in cones is not very sensitive to light and needs bright light to break it down and trigger nerve impulses The pigment in rods is so sensitive to light that dim light triggers off its breakdown and sends impulses. It is inactive in bright light
Convergence of Signals from Rods • As the intensity of light entering the eye decreases, cones cease to respond and rods take over. Unlike cones several rods form synapses with the next neurone in the pathway Several rods form synapses with the next neurone in the pathway The nerve impulse transmitted by one rod in dim light is weak. It would mean not enough neurotransmitter would be released to carry on the impulse. Several rods are needed to allow enough neurotransmitter to be released. A nerve impulse is then passed through the optic nerve to the brain
Investigating the brain’s capacity to suppress the blinking reflex Blinking the eye is an example of a reflex action. A reflex action is a rapid, automatic response designed to protect the body from danger In this experiment, ten attempts are made to make the volunteer blink using their right eye. A ten second interval is allowed between each attempt to allow the volunteer the opportunity to summon maximum willpower. Some can suppress the blinking but others cannot resist blinking no matter how hard they try
Investigating the ability of the brain to suppress sensory impulses If a person is given a task to do that requires a lot of concentration and is subjected to auditory and visual distractions, some people are good at suppressing the sensory impulses from the distractions and perform well each time. Other people find it hard to block out the sensory impulses
Plasticity of Response • Sometimes the brain can be persuaded to temporarily suppress a reflex action or block out certain sensory impulses. This demonstrates Plasticity of Response of the nervous system.
Plasticity of Response • Plasticity is thought to occur as you have two conflicting messages- one saying to blink and the other not to blink meeting in a convergent pathway. • If the overall effect at the synapse is excitatory then the nerve impulse is fired and blinking occurs. • If the overall effect is inhibitory then no impulse is fired and blinking fails to occur. • This explains why some people can resist blinking whilst others can’t help themselves