Neurons and synaptic transmission
Cards (6)
- What is a neuron? What is the structure of a neuron?
- A specialised cell designed to transmit information through electrical or chemical signals
- Dendrites: branch-like structures that carry electrical impulses towards the cell body
- Axon: carries electrical impulses away from the cell body
- Myelin sheath: fatty later that protects the axon and speeds up electrical transmission by forcing impulses to jump across small gaps called nodes of Ranvier
- Terminal buttons: end of an axon that communicates with the next neuron across a synapse
- What are the roles of the 3 types of neurons?
- Sensory neurons carry messages from the PNS to the CNS with long dendrites and short axons - located in clusters ganglias in the PNS
- Relay neurons connect sensory neurons to motor and relay neurons with short dendrites and long axons - located in the brain and visual system
- Motor neurons connect the CNS to muscles and glands with short dendrites and long axons - located in the CNS but long axons form part of the PNS
- What is synaptic transmission? (1)
- Neurons communicate with each other in groups called neural networks, and each one is separated by a small gap called the synapse
- Signals WITHIN neurons are electrically transmitted, signals BETWEEN neurons are chemically transmitted across the synapse
- When an electrical impulse reaches the end of the neuron (the presynaptic terminal) it triggers tiny sacs called synaptic vesicles to release neurotransmitters
- What is synaptic transmission? (2) What are neurotransmitters?
- Neurotransmitters are chemicals that diffuse across the synapse - once it crosses the gap it is taken up by a postsynaptic receptor site on the next neuron's dendrites
- The neurotransmitter is converted back into an electrical impulse and the process of transmission begins in the next neuron
- Each neurotransmitter has a specific molecular structure that fits perfectly into a postsynaptic receptor site, like a lock and key
- They also have specialised functions e.g. dopamine is released when experiencing pleasurable activities and leads to feelings of satisfaction
- What is excitation and inhibition?
- Excitation: excitatory neurotransmitters like adrenaline create a positive charge in the postsynaptic neuron, creating an excitatory postsynaptic neuron (EPSP), meaning it is more likely to fire and continue the message
- Inhibition: inhibitory neurotransmitters quieten down signals by having a negative charge, creating an inhibitory postsynaptic potential (IPSP) making it less likely that the cell will fire
- What is summation?
- Nerve cells can receive both EPSPs and IPSPs at the same time - summation is the net result of adding up excitatory and inhibitory input which determines whether the cell will fire or not
- For the cell to fire the net effect has to be excitatory more than inhibitory
- Spatial summation: when a large number of EPSPs are generated at different synapses at the same postsynaptic neuron at the same time
- Temporal summation: when a large number of EPSPs are generated at the same synapse by a series of high-frequency action potentials on the presynaptic neuron -> both increase the strength of EPSPs making the cell more likely to fire